Sarama Resources Ltd. — Capital/Financing Update 2023

Feb 26, 2023

27 FEBRUARY, 2023

SARAMA RESOURCES INTERSECTS 23m @ 4.26g/t GOLD AT SANUTURA PROJECT

Drilling Confirms Near-Surface, High-Grade Zones Within Tankoro Deposit

PERTH, AUSTRALIA / VANCOUVER, CANADA. Sarama Resources Ltd. ("Sarama" or the "Company") (ASX:SRR, TSX-V:SWA) is pleased to announce that exploration drilling at its 100%-owned(4), multi-million-ounce Sanutura Project (the "Project") has confirmed the presence of high-grade mineralisation within the central area of the Tankoro Deposit, with new downhole intersections from recent drilling including 23m @ 4.26g/t Au, 18m @ 3.63g/t Au and 11m @ 4.33g/t Au being returned.

Notably, the new results confirm the presence of a high-grade mineralised zone extending for 700m along strike and high-grade oblique mineralisation within the central area of the Tankoro Deposit. This area accountsfor approximately 80% of the Mineral Resource for the deposit and is currently the economic focal point of the Project.

The reported drilling totals approximately 5,400m and reflects the balance of unreported assays of a multi-purpose drill program completed in H2 2022 which was primarily focussed on testing for new, near-surface mineralisation within the Tankoro Deposit. The successful program has delivered numerous high-grade discoveries which are anticipated to grow the oxide component of the Project's 0.6Moz Au (Indicated) plus 2.3Moz Au (Inferred)(1) mining shape constrained Mineral Resource.

Highlights

• Extensive zones of high-grade mineralisation continue to be intersected within the Tankoro Deposit
• Highlighted downhole intersections from new assays include:
  • o 23m @ 4.26g/t Au from 30m in TAR044;
  • o 18m @ 3.63g/t Au from 24m in TAR043;
  • o 11m @ 4.33g/t Au from 30m in TAA320;
  • o 26m @ 2.09g/t Au from 2m in TAA318;
  • o 15m @ 2.37g/t Au from 7m in TAA321;
  • o 18m @ 2.02g/t Au from 21m in TAA362; and
  • o 22m @ 1.74g/t Au from 25m in TAA413.
• Significant zone of high-grade mineralisation delineated over a strike length of 700m
• Oblique lodes continue to demonstrate enriched grade, highlighting value potential
• Drill results support strike extensions for several mineralised lodes
• Intersections are in near-surface oxide material with potential to provide early feed in any mine development
• Intersections enhance confidence level of the near-surface oxide and transition component of the Mineral Resource, currently standing at a substantial 0.2Moz Au (Indicated) plus 0.8Moz Au (Inferred)(2)
• 2023 exploration to focus on the Bondi Deposit, located in the north of the Sanutura Project

Sarama's President, CEO & MD, Andrew Dinning commented:

"We are excited that we continue to make new, near-surface discoveries and extend areas outside of the modelled mineralization. The central area of the Tankoro Deposit hosts almost 80% of its contained metal and remains the economic focus of the Project and the drill results received from the 20,000m of drilling completed in the current campaign support management's view that abundant exploration potential remains. We have made multiple new highgrade discoveries proximal to but outside of the Mineral Resource and also developed a new exploration target model reminiscent of Endeavour Mining's flat, high-grade Kari Pump Deposit which lies 80km away. The recent discoveries are expected to add to the current Mineral Resource which we plan to update after the completion and follow up of the current +50,000m program, a majority of which is shallow, cost-effective aircore drilling."

Figure 1 - Tankoro Deposit Location Plan – Continual Success in CY2022 Drilling Program

Drilling Delineates High-Grade Zones in Oxide Material within the Central Area of Tankoro Deposit

Results are reported (refer Appendix A) for approximately 1,200m (20 holes) of aircore ("AC") and reverse-circulation ("RC") drilling undertaken in Q2/Q3 2022 within the central area of the Tankoro Deposit at the MC and MM Prospects which targeted high-grade zones of mineralisation close to surface. These prospects are the economic focal points of the deposit and the targeted areas would notionally provide early feed for a potential oxide open pit mine development.

Drilling at the MC Prospect (refer Figure 2) targeted a geometrically complex area of mineralisation that makes a significant contribution to the Mineral Resource. The mineralisation is interpreted to be a package of north-north-east striking quartz-feldspar-porphyry dykes which is interleaved with several later-stage north-east trending mineralised lodes, hypothesised to be associated with structural deformation/displacement events. The resulting mineralisation presents as a dense package of discrete lodes, which are typically high grade and of significant width. The recent drilling sought to better-define certain areas of the interpretation in order to reduce estimation risk in this high contained metal area of the Mineral Resource. Highlighted downhole intersections from this recent series of drilling include:

• 23m @ 4.26g/t Au from 30m in TAR044;
• 18m @ 3.63g/t Au from 24m in TAR043;
• 18m @ 2.02g/t Au from 21m in TAA362;
• 13m @ 1.25g/t Au from 49m in TAR043;
• 6m @ 1.74g/t Au from 18m in TAA374;
• 7m @ 2.20g/t Au from 47m in TAR067; and
• 5m @ 2.10g/t Au from 31m in TAR028.

These results add to previously reported shallow, high-grade drilling in the area featuring downhole intersections of:

• 36m @ 6.48g/t Au from 14m in DDH059;
• 26m @ 6.90g/t Au from 22m in FRC845;
• 32m @ 4.82g/t Au from 14m in AC988;
• 45m @ 3.88g/t Au from 6m in AC1891;
• 35m @ 3.29g/t Au from 6m in TAA130; and
• 34m @ 2.62g/t Au from 32m in FRC873.

Figure 2 – High-Grade Zone at MC Prospect Associated with Oblique Lode Geometry (Intersections >3g/t Au)

As with the higher-grade areas of the MM Prospect, the recent drilling confirmed the interpretation of mineralisation and the Company anticipates it will assist in the upgrading certain local areas of the Mineral Resource to Indicated and potentially Measured, classification.

Drilling at the MM Prospect (refer Figure 3) successfully intersected high-grade mineralisation along a strike distance of approximately 700m and included new downhole intersections of:

• 11m @ 4.33g/t Au from 30m in TAA320;
• 26m @ 2.09g/t Au from 2m in TAA318;
• 15m @ 2.37g/t Au from 7m in TAA321;
• 22m @ 1.74g/t Au from 25m in TAA413;
• 5m @ 3.47g/t Au from 39m in TAA414; and
• 12m @ 1.50g/t Au from 12m in TAA412.

Figure 3 – Central Tankoro Deposit Area with 700m Long High-Grade Zone Delineated at MM Prospect

These results are consistent with previously reported drilling in the area which included downhole intersections of:

• 14m @ 4.99g/t Au from 34m in FRC631;
• 21m @ 2.50g/t Au from 93m in FRC630;
• 22m @ 1.89g/t Au from 39m in FRC668;
• 17m @ 1.98g/t Au from 16m in FRC665; and
• 26m @ 1.84g/t Au from 28m in FRC662.

The Tankoro Deposit features numerous zones of elevated gold grades and it is encouraging that the zone targeted by the drilling demonstrates grade continuity over this significant distance. The broad widths of mineralisation intersected and the presence of multiple parallel mineralised lodes enhance the economics of potential open pit mining and the Company is pleased with the results which reduce the technical risk of the local Mineral Resource estimate.

Testing for Strike Extensions to Minor Lodes – MM, MC, Obi & Kenobi Prospects

Approximately 1,900m (34 holes) of AC and RC drilling targeted modest strike extensions to various minor lodes throughout the MM, MC (refer Figure 4), Obi and Kenobi Prospects. The targets were typically singular lodes for which interpretations had terminated on drill fences of economic significance.

Figure 4 – 300m Information Gap with Potential for Additions to Mineral Resource at MC Prospect

The results of the step-out/close-out holes generally provided terminations for the mineralised lodes and have improved knowledge of the lode architecture, particularly in one area at the MC Prospect. This area is outside the Mineral Resource and features an information gap extending for approximately 300m along strike in between two segments of the Mineral Resource (apart from a single fence of reconnaissance rotary-air-blast drilling which is considered to be of low accuracy).

The drilling suggests that a northern extension to the southern segment of the Mineral Resource is likely and further drilling in the information gap is warranted. Full results for this series of drilling are listed in Appendix A and highlighted downhole intersections include:

• 5m @ 1.72g/t Au from 34m in TAA377;
• 4m @ 1.82g/t Au from 19m in TAA199;
• 5m @ 1.13g/t Au from 20m in TAR027;
• 4m @ 1.23g/t Au from 19m in TAA205;
• 3m @ 1.04g/t Au from 26m in TAA205; and
• 6m @ 0.95g/t Au from 49m in TAA205.

Testing for Cross-Linking Mineralisation Potential – MM Prospect

Approximately 800m (16 holes) of reconnaissance AC drilling was conducted at the MM Prospect to investigate potential for cross-linking mineralisation in the near-resource field. Sarama's historical exploration activities have demonstrated that this orientation of mineralisation is an important feature of the Tankoro Deposit and often is associated with local increases in grade and lode volume. Previous drilling in the target area returned near-surface downhole intersections of 8m @ 0.97g/t Au, 10m @ 0.41g/t Au and 2m @ 2.74g/t Au which are considered promising for an early-stage target. Of interest was a previously reported downhole intersection of 4.7m @ 1.36g/t Au at a vertical depth of approximately 200m which can be extrapolated to near-surface drill intersections. New near-surface downhole intersections of 7m @ 1.00g/t Au and 2m @ 2.45g/t Au, in TAR030 and TAR037 respectively, will assist the Company in understanding the lode geometry and determining the potential for attractive exploration targets. Full results for this series of drilling are listed in Appendix A.

Improved Definition of Grade Distribution in Mineral Resource – Obi & Kenobi Prospects

Approximately 800m (15 holes) of AC and RC drilling was conducted at the Obi and Kenobi Prospect to improve the definition of grade distribution and investigate the potential for elevated gold grades in certain segments of the Mineral Resource. In general, the drilling confirmed the interpretation of the lodes comprising the Mineral Resource, with the majority of holes returning broad downhole intersections in the order of 15-20m length. The intersected grades were generally low to moderate and consistent with the grades estimated for the Mineral Resource in the area. Some instances of elevated grades are present, illustrated by new downhole intersections of 12m @ 1.26g/t Au (TAA160), 15m @ 1.06g/t Au (TAA419) and 16m @ 0.87g/t Au (TAA309), all of which were returned within oxide material approximately 25m from surface. Of note were a number of holes ending in mineralisation, which provides some scope for expansion of the Mineral Resource interpretations.

It is pleasing that the additional drilling information has confirmed the interpretation and estimate of gold grades, providing additional confidence in the Mineral Resource estimate. Further work in the target areas will likely be limited to infill drilling for classification upgrades to the Mineral Resource as the Project advances. Some potential exists for structural/deformation features to be present in-between existing drill fences which may be associated with grade enrichment in localised zones. Full results for this series of drilling are listed in Appendix A.

Early-Stage Targets with Working Interpretations – MC & Obi Prospects

Approximately 800m (17 holes) of AC drilling targeted selected areas of the MC and Obi Prospects where broad spaced drilling had supported preliminary working interpretations of mineralisation to be compiled. These areas are outside of the Mineral Resource and generally have low data density and multiple permissive interpretations. The recent drilling generally returned downhole intersections of modest grade and width, which is broadly consistent with exiting results in these areas. Full results for this series of drilling are listed in Appendix A. The recent results will be incorporated into the mineralisation interpretations which will further the Company's understanding of lode geometry and geologic model in the near-surface area.

Exploration Set to Continue in 2023 at Bondi Deposit

The Company is pleased by the numerous discoveries made throughout the 2022 drill program which it anticipates will add to the oxide and transition component of the already large, multi-million Mineral Resource of 0.6Moz Au (Indicated) plus 2.3Moz Au (Inferred)(1). The program illustrates good potential remains for growth within the fertile Tankoro Mineralised Corridor and planning is underway for follow-up exploration.

In the near term, the Company will turn its exploration focus to the Bondi Deposit, located in the north of the Sanutura Project. The deposit is an important part of the project, with potential to provide early open pit oxide feed in any mine development. There are numerous high priority exploration targets proximal to the Mineral Resource, a majority of which lie within 80m of surface.

For further information, please contact:

Company Activities Media Enquiries

Andrew Dinning or Paul Schmiede Sarama Resources Ltd e: info@saramaresources.com t: +61 8 9363 7600

Angela East Media & Capital Partners e: Angela.east@mcpartners.com.au t: +61 428 432 025

ABOUT SARAMA RESOURCES LTD

Sarama Resources Ltd (ASX: SRR, TSX-V: SWA) is a West African focused gold explorer/developer with substantial landholdings in south-west Burkina Faso. Sarama is focused on maximising the value of its strategic assets and advancing its key projects towards development.

Sarama's 100%-owned(4) Sanutura Project is principally located within the prolific Houndé Greenstone Belt in southwest Burkina Faso and is the exploration and development focus of the Company. The Project hosts the Tankoro and Bondi Deposits which have a combined Mineral Resource of 0.6Moz gold (Indicated) plus 2.3Moz gold (Inferred)(1).

Together, the deposits present a potential mine development opportunity featuring an initial, long-life CIL project which may be established and paid for by the significant oxide Mineral Resource base.

Sarama has built further optionality into its portfolio including an approximate 470km² exploration position in the highly prospective Banfora Belt in south-western Burkina Faso. The Koumandara Project hosts several regional-scale structural features and trends of gold-in-soil anomalism extending for over 25km along strike.

Sarama also holds an approximate 18% participating interest in the Karankasso Project Joint Venture ("JV") which is situated adjacent to the Company's Sanutura Project in Burkina Faso and is a JV between Sarama and Endeavour Mining Corp ("Endeavour") in which Endeavour is the operator of the JV. In February 2020, an updated Mineral Resource estimate of 709koz gold(3) was declared for the Karankasso Project JV.

The Company's Board and management team have a proven track record in Africa and a strong history in the discovery and development of large-scale gold deposits. Sarama is well positioned to build on its current success with a sound strategy to surface and maximise the value of its property portfolio.

Sanutura Project - An Already Large Mineral Resource with Potential to Grow

The Company's primary focus is its 100%-owned(4) Sanutura Project, which hosts a large Mineral Resource of 0.6Moz Au (Indicated) plus 2.3Moz Au (Inferred)(1) and covers an area of 1,420km2 . The Project occupies a commanding position along 70km of strike in the prolific Houndé Belt (refer Figure 6), Burkina Faso's pre-eminent gold belt.

The Project lies 60km south of Endeavour Mining's Houndé Mine (5Moz Au); 120km south of Fortuna Silver's high-grade Yaramoko Mine (1Moz Au), and 140km south of Endeavour Mining's Mana Mine (5Moz Au), highlighting the significant gold endowment of the Houndé Belt (refer Appendix B). Endeavour Mining's Bantou Project (1.5Moz Au Inferred Mineral Resource(5)) islocated only 6km from the bulk of the Sanutura Project's main deposit, which illustrates the gold camp scale of endowment of the immediate area.

The Project has significant growth potential and the primary objective of the current +50,000m drill program is to increase the existing 0.2Moz Au (Indicated) plus 0.8Moz Au (Inferred)(2) pit shell constrained oxide and transition component of the Project's Mineral Resource to further underwrite and enhance the economics of mine development.

The recent drill program has generally focused on shallow additional and extensional targets throughout the wellmineralised western corridor of the Tankoro Deposit, where mineralisation has been drill-defined for a semi-continuous strike length of 16km and potential exists to expand the Mineral Resource at shallow depths in oxide material.

Figure 5 - Sanutura Project Location Plan

FOOTNOTES

• 1. Mineral Resource estimate for Sanutura Project - 9.4Mt @ 1.9g/t Au for 0.6Moz Au (Indicated) plus 52.7Mt @ 1.4g/t Au for 2.3Moz (Inferred), reported at cut-off grades ranging 0.2-1.6g/t Au, reflecting the mining methods and processing flowsheets assumed to assess the likelihood of the Mineral Resources to have reasonable prospects for eventual economic extraction. The effective date of the Company's Mineral Resource estimate is 16 November 2021. For further information regarding the Mineral Resource estimate refer to the technical report titled "NI 43-101 Independent Technical Report Sanutura Project, South-West Burkina Faso", dated 7 February 2022 and prepared by Paul Schmiede, Rindra Le Grange and Fred Kock, and the Company's ASX Prospectus dated 11 March 2022. Paul Schmiede is an employee of Sarama. Ms Le Grange and Mr Kock are employees of Cube Consulting Pty Ltd and Orway Mineral Consultants Pty Ltd respectivley and are considered to be independent of Sarama. The technical report is available under Sarama's profile on SEDAR at www.sedar.com and the ASX Prospectus is available under Sarama's profile on ASX at www.asx.com.au.
• 2. Oxide & transition component of the Mineral Resource for Sanutura Project - 3.2Mt @ 1.6g/t Au for 0.2Moz Au (Indicated) plus 23.4Mt @ 1.1g/t Au for 0.8Moz Au (Inferred), reported above cut-off grades of 0.2g/t Au and 0.3g/t Au for oxide and transition material respectively.
• 3. Mineral Resource estimate for Karankasso Project – 12.74Mt @ 1.73g/t Au for 709koz Au (effective date of December 31, 2019), disclosed on 24 February 2020 by Semafo Inc ("Semafo", since acquired by Endeavour Mining Corp. "Endeavour"). For further information regarding that Mineral Resource estimate, refer to the news release "Semafo: Bantou Project Inferred Resources Increase to 2.2Moz" dated 24 February 2020 and Semafo: Bantou Project NI43-101 Technical Report – Mineral Resource Estimate" dated 3 April 2020 and the Company's ASX Prospectus dated 11 March 2022. The news release and technical report are available under Semafo's and Endeavour's profile on SEDAR at www.sedar.com and the ASX Prospectus is available under Sarama's profile on ASX at www.asx.com.au. The Mineral Resource estimate was fully prepared by, or under the supervision of Semafo. Sarama has not independently verified Semafo's mineral Resource Estimate and takes no responsibility for its accuracy. Semafo, and now Endeavour, is the operator of the Karankasso Project JV and Sarama is relying on their Qualified Persons' assurance of the validity of the Mineral Resource estimate. Additional technical work has been undertaken on the Karankasso Project since the effective date but Sarama is not in a position to quantify the impact of this additional work on the Mineral Resource estimate referred to above.
• 4. The Government of Burkina Faso has processed the requisite documents to facilitate the grant of the new, full-term Tankoro 2 and Djarkadougou 2 Exploration Permits (the "Permits") and subsequently issued the invitation to pay the permit issuance fees (the "Fees") and the Fees were paid within the requisite 10-day timeline. Following the payment of the Fee, the issuance of the Permit's arrêté and related paperwork becomes an administrative process during which time the Company may undertake work on the Tankoro 2 and Djarkadougou 2 Properties. The Company has received the arrêté for the Djarkadougou 2 Exploration Permit and anticipates the issuance of the same for the Tankoro 2 Exploration Permit in due course. The properties, hosting the Tankoro and Bondi Deposits respectively, were formerly known as Tankoro and Djarkadougou, but have been renamed as part of the process of re-issuing the respective Permits.
• 5. Endeavour Mining's Bantou Project Mineral Resource – 38.4Mt @ 1.2g/t Au for 1.5Moz Au (Inferred). This is the aggregate of the Mineral Resource listing for the Bantou and Bantou Nord Deposits which are located within the Bantou Project. Data is sourced from Semafo: Bantou Project NI43-101 Technical Report – Mineral Resource Estimate" dated 3 April 2020. The technical report are available under Endeavour's profile on SEDAR at www.sedar.com.

CAUTION REGARDING FORWARD LOOKING INFORMATION

Information in this news release that is not a statement of historical fact constitutes forward-looking information. Such forward-looking information includes, but is not limited to, statements regarding the Company's future exploration and development plans, the potential for the Sanutura and Karankasso Projects to host economic mineralisation, the potential to expand the existing estimated Mineral Resources at the Sanutura Project (including the present oxide and transition component), the accuracy of the Mineral Resource estimate for the Sanutura Project in localized areas with the addition of new drilling and assay information, the potential to extend and add to existing mineralisation at the MM, MC, Obi and Kenobi Prospects, the potential for development of a mine at the Sanutura Project, the potential for the receipt of regulatory approvals and the timing and prospects for the issuance of the arrêté for the Tankoro 2 Exploration Permit by the Government of Burkina Faso. The Company's full suite of exploration permits are at varying stages in their life cycles and at any one time, the Company has exploration permits either in renewal or re-issue phase and although the Company follows due government process and anticipates new exploration permits will be granted in due course, it cannot guarantee this will be done in a timely manner or at all. Actual results, performance or achievements of the Company may vary from the results suggested by such forwardlooking statements due to known and unknown risks, uncertainties and other factors. Such factors include, among others, that the business of exploration for gold and other precious minerals involves a high degree of risk and is highly speculative in nature; Mineral Resources are not mineral reserves, they do not have demonstrated economic viability, and there is no certainty that they can be upgraded to mineral reserves through continued exploration; few properties that are explored are ultimately developed into producing mines; geological factors; the actual results of current and future exploration; changes in project parameters as plans continue to be evaluated, as well as those factors disclosed in the Company's publicly filed documents.

There can be no assurance that any mineralisation that is discovered will be proven to be economic, or that future required regulatory licensing or approvals will be obtained. However, the Company believes that the assumptions and expectations reflected in the forward-looking information are reasonable. Assumptions have been made regarding, among other things, the Company's ability to carry on its exploration activities, the sufficiency of funding, the timely receipt of required approvals, the price of gold and other precious metals, that the Company will not be affected by adverse political and security-related events, the ability of the Company to operate in a safe, efficient and effective manner and the ability of the Company to obtain further financing as and when required and on reasonable terms. Readers should not place undue reliance on forward-looking information.

Sarama does not undertake to update any forward-looking information, except as required by applicable laws.

QUALIFIED PERSONS' STATEMENT

Scientific or technical information in this disclosure that relates to the preparation of the Mineral Resource estimate for the Sanutura Project is based on information compiled or approved by Paul Schmiede. Paul Schmiede is an employee of Sarama Resources Ltd and is a Fellow in good standing of the Australasian Institute of Mining and Metallurgy. Paul Schmiede has sufficient experience which is relevant to the commodity, style of mineralisation under consideration and activity which he is undertaking to qualify as a Qualified Person under National Instrument 43-101. Paul Schmiede consents to the inclusion in this news release of the information, in the form and context in which it appears.

Scientific or technical information in this disclosure that relates to exploration activities at the Sanutura Project is based on information compiled or approved by Guy Scherrer. Guy Scherrer is an employee of Sarama Resources Ltd and is a member in good standing of the Ordre des Géologues du Québec and has sufficient experience which is relevant to the commodity, style of mineralisation under consideration and activity which he is undertaking to qualify as a Qualified Person under National Instrument 43-101. Guy Scherrer consents to the inclusion in this disclosure of the information, in the form and context in which it appears.

Scientific or technical information in this disclosure that relates to the quotation of the Karankasso Project's Mineral Resource estimate and exploration activities is based on information compiled by Paul Schmiede. Paul Schmiede is an employee of Sarama Resources Ltd and is a Fellow in good standing of the Australasian Institute of Mining and Metallurgy. Paul Schmiede has sufficient experience which is relevant to the commodity, style of mineralisation under consideration and activity which he is undertaking to qualify as a Qualified Person under National Instrument 43-101. Paul Schmiede consents to the inclusion in this disclosure of the information, in the form and context in which it appears. Paul Schmiede and Sarama have not independently verified Semafo's (now Endeavour's) Mineral Resource estimate and take no responsibility for its accuracy.

COMPETENT PERSONS' STATEMENT

The Mineral Resource estimates referred to in this disclosure were first disclosed in accordance with ASX Listing Rule 5.8 in the Company's ASX Prospectus dated 11 March 2022. The Company confirms that it is not aware of any new information or data that materially affects the information included in the ASX Prospectus and that all material assumptions and technical parameters underpinning the estimates in the ASX Prospectus continue to apply and have not materially changed.

The new Exploration Results reported in this disclosure are based on, and fairly represent, information and supporting documentation prepared by Guy Scherrer. Guy Scherrer is an employee of Sarama Resources and a member of the Ordre des Géologues du Québec. Guy Scherrer has provided his prior written consent as to the form and context in which the new Exploration Results and the supporting information are presented in this disclosure.

The previously reported Exploration Results referred to in this disclosure were first disclosed in accordance with ASX Listing Rule 5.7 in the Company's ASX disclosure listed in Appendix B. The Company confirms that it is not aware of any new information or data that materially affects the information included in those previous items of disclosure.

This announcement has been authorised by the Board of Sarama Resources.

Neither TSX Venture Exchange nor its Regulation Services Provider (as that term is defined in policies of the TSX Venture Exchange) accepts responsibility for the adequacy or accuracy of this release.

APPENDIX A – SUMMARY OF RECENTLY RETURNED DRILL RESULTS

Prospect	Hole ID	Downhole Intersection	Intersection Material Type	DepthFrom(m)	DepthTo(m)	Comments	HoleType	CollarEasting(m)	CollarNorthing(m)	CollarElevation(m)	Dip(°)	Azimuth(°TN)	HoleLength(m)
		Delineation of 700m High-Grade Zone at MM Prospect
MM	TAA317	8m @ 1.47g/t Au	100% Oxide	4	12		AC	40,607	98,562	346	-50	87	66
MM	TAA318	26m @ 2.09g/t Au	100% Oxide	2	28		AC	40,601	98,645	343	-50	112	67
MM	TAA319	6m @ 1.68g/t Au	100% Oxide	33	39	ended in mineralisation	AC	40,575	98,772	341	-50	89	39
MM	TAA320	11m @ 4.33g/t Au	100% Oxide	30	41		AC	40,571	98,822	340	-51	91	58
MM	TAA321	15m @ 2.37g/t Au	100% Oxide	7	22		AC	40,579	98,948	337	-50	120	39
		2m @ 0.61g/t Au	100% Oxide	27	29		AC
MM	TAA322	5m @ 2.81g/t Au	100% Oxide	35	40	ended in mineralisation	AC	40,553	98,949	337	-50	120	40
MM	TAA323	3m @ 1.06g/t Au	100% Oxide	16	19		AC	40,555	98,989	336	-50	89	59
		3m @ 0.86g/t Au	100% Oxide	36	39		AC
MM	TAA412	12m @ 1.50g/t Au	100% Oxide	12	24		AC	40,589	98,842	339	-50	112	43
MM	TAA413	22m @ 1.74g/t Au	100% Oxide	25	47		AC	40,578	98,741	341	-50	114	60
MM	TAA414	5m @ 3.47g/t Au	100% Oxide	39	44		AC	40,569	98,352	350	-52	114	66
		4m @ 2.17g/t Au	100% Oxide	47	51		AC
		4m @ 0.37g/t Au	100% Oxide	54	58		AC
		Mineral Resource Risk Reduction at MC Prospect
MC	TAA207	no significant intersections		0	9		AC	41,128	99,341	332	-50	110	9
MC	TAA362	3m @ 1.89g/t Au	100% Oxide	9	12		AC	41,059	99,714	331	-50	90	60
		18m @ 2.02g/t Au	100% Oxide	21	39		AC
		4m @ 0.44g/t Au	100% Oxide	50	54		AC
MC	TAA374	6m @ 1.74g/t Au	100% Oxide	18	24		AC	41,041	99,497	331	-50	327	64
MC	TAA376	5m @ 0.85g/t Au	100% Oxide	16	21		AC	41,069	99,774	332	-51	133	57
		3m @ 0.92g/t Au	100% Oxide	24	27		AC
MC	TAR028	2m @ 1.34g/t Au	100% Oxide	14	16		RC	41,129	99,341	332	-50	109	63
		5m @ 2.10g/t Au	100% Oxide	31	36		RC
MC	TAR043	4m @ 1.41g/t Au	100% Oxide	9	13	8m missing samples above	RC	41,118	99,586	331	-51	322	70
		18m @ 3.63g/t Au	100% Oxide	24	42	1m missing samples above	RC
		13m @ 1.25g/t Au	100% Oxide	49	62		RC
MC	TAR044	4m @ 0.65g/t Au	100% Oxide	10	14		RC	41,065	99,599	331	-49	182	70
		23m @ 4.26g/t Au	100% Oxide	30	53		RC

Prospect	Hole ID	Downhole Intersection	Intersection Material Type	DepthFrom(m)	DepthTo(m)	Comments	HoleType	CollarEasting(m)	CollarNorthing(m)	CollarElevation(m)	Dip(°)	Azimuth(°TN)	HoleLength(m)
		7m @ 1.57g/t Au	100% Oxide	63	70	ended in mineralisation	RC
MC	TAR066	7m @ 0.91g/t Au	100% Oxide	48	55		RC	41,017	99,889	333	-73	89	91
MC	TAR067	2m @ 0.59g/t Au	100% Oxide	42	44		RC	41,062	99,918	333	-81	89	87
		7m @ 2.20g/t Au	100% Oxide	47	54		RC
MC	TAR068	6m @ 0.75g/t Au	100% Oxide	6	12		RC	41,088	99,935	334	-56	89	94
		Test for Strike Extensions to Various Lodes at MC Prospect
MC	TAA197	no significant intersections		0	45		AC	41,318	99,131	340	-55	113	45
MC	TAA198	5m @ 0.42g/t Au	100% Oxide	1	6	ended in mineralisation	AC	41,350	99,133	340	-55	113	33
MC	TAA199	2m @ 1.94g/t Au	100% Oxide	10	12		AC	41,366	99,088	341	-55	91	35
		4m @ 1.82g/t Au	100% Oxide	19	23		AC
		2m @ 1.24g/t Au	100% Oxide	31	33		AC
MC	TAA201	no significant intersections		0	68		AC	41,270	98,944	341	-53	90	68
MC	TAA204	2m @ 0.80g/t Au	100% Oxide	8	10		AC	41,170	98,999	340	-55	90	65
		6m @ 0.64g/t Au	100% Oxide	30	36		AC
MC	TAA205	4m @ 1.23g/t Au	100% Oxide	19	23		AC	41,215	99,025	340	-55	90	65
		3m @ 1.04g/t Au	100% Oxide	26	29		AC
		6m @ 0.95g/t Au	100% Oxide	49	55		AC
MC	TAA206	3m @ 0.89g/t Au	100% Oxide	6	9		AC	41,257	99,049	340	-55	90	65
MC	TAA208	no significant intersections		0	67		AC	40,966	99,719	331	-51	125	67
MC	TAA219	2m @ 1.04g/t Au	100% Oxide	2	4		AC	41,063	100,179	334	-50	90	51
MC	TAA291	3m @ 0.60g/t Au	100% Oxide	18	21		AC	41,373	98,791	345	-51	91	36
MC	TAA292	2m @ 0.93g/t Au	100% Oxide	26	28		AC	41,352	98,892	343	-50	92	31
MC	TAA372	11m @ 0.70g/t Au	100% Oxide	10	21		AC	41,021	100,186	333	-49	103	75
		9m @ 0.52g/t Au	100% Oxide	39	48		AC
MC	TAA377	7m @ 2.12g/t Au	100% Oxide	14	21		AC	41,031	100,134	334	-50	109	60
		5m @ 1.72g/t Au	100% Oxide	34	39		AC
MC	TAA382	no significant intersections		0	41		AC	41,382	99,094	341	-50	90	41
MC	TAR026	3m @ 1.06g/t Au	100% Oxide	9	12		RC	41,343	98,985	341	-50	89	78
MC	TAR027	5m @ 1.13g/t Au	100% Oxide	20	25		RC	41,095	99,336	332	-52	111	79
		9m @ 0.99g/t Au	100% Oxide	67	76		RC
MC	TAR029	no significant intersections		0	65		RC	41,054	99,327	333	-50	113	65
MC	TAR064	no significant intersections		0	83		RC	40,937	99,724	331	-51	125	83

Prospect	Hole ID	Downhole Intersection	Intersection Material Type	DepthFrom(m)	DepthTo(m)	Comments	HoleType	CollarEasting(m)	CollarNorthing(m)	CollarElevation(m)	Dip(°)	Azimuth(°TN)	HoleLength(m)
		Test for Strike Extensions to Minor Lodes at Obi Prospect
OBI	TAA162	no significant intersections		0	63		AC	40,521	95,695	378	-50	117	63
OBI	TAA163	4m @ 0.66g/t Au	100% Oxide	6	10		AC	40,747	96,564	384	-50	122	28
OBI	TAA299	no significant intersections		0	40		AC	40,571	96,282	381	-50	115	40
OBI	TAR001	no significant intersections		0	69		RC	40,562	95,698	379	-48	120	69
OBI	TAR012	7m @ 0.61g/t Au	100% Oxide	39	46		RC	40,719	96,567	385	-51	120	65
		Test for Strike Extensions to Minor Lodes at Kenobi Prospect
KENOBI	TAA179	no significant intersections		0	66		AC	41,501	97,173	369	-51	91	66
KENOBI	TAA180	no significant intersections		0	72		AC	41,461	97,150	369	-51	91	72
KENOBI	TAA281	2m @ 0.47g/t Au	100% Oxide	46	48		AC	41,455	97,289	366	-50	113	65
KENOBI	TAA282	no significant intersections		0	33		AC	41,489	97,295	366	-50	113	33
KENOBI	TAA284	4m @ 0.49g/t Au	100% Oxide	45	49		AC	41,289	97,342	365	-50	93	71
KENOBI	TAA287	no significant intersections		0	71		AC	41,526	97,931	356	-51	91	71
KENOBI	TAR025	no significant intersections		0	71		RC	41,291	97,124	370	-76	270	71
		Test for Strike Extension to Minor Lode at MM Prospect
MM	TAA345	no significant intersections		0	68		AC	40,651	98,469	348	-50	90	68
MM	TAA346	no significant intersections		0	70		AC	40,617	98,449	349	-50	90	70
		Test for Cross-Linking Mineralisation at MM Prospect
MM	TAA184	no significant intersections		0	12		AC	40,623	99,180	332	-50	92	12
MM	TAA185	no significant intersections		0	12		AC	40,774	99,058	333	-50	90	12
MM	TAA324	no significant intersections		0	65		AC	40,688	99,122	333	-50	92	65
MM	TAA325	no significant intersections		0	20		AC	40,715	99,140	333	-50	92	20
MM	TAA326	no significant intersections		0	69		AC	40,745	99,156	334	-50	92	69
MM	TAA327	no significant intersections		0	10		AC	40,738	99,296	331	-50	89	10
MM	TAR030	7m @ 1.00g/t Au	100% Oxide	23	30		RC	40,643	99,242	332	-52	88	64
MM	TAR031	no significant intersections		0	67		RC	40,666	99,258	332	-51	87	67
MM	TAR032	2m @ 0.56g/t Au	100% Oxide	23	25		RC	40,688	99,273	331	-52	88	68
MM	TAR033	no significant intersections		0	69		RC	40,715	99,289	331	-51	90	69
MM	TAR034	no significant intersections		0	48		RC	40,621	99,180	332	-51	94	48
MM	TAR035	no significant intersections		0	40		RC	40,658	99,199	332	-51	93	40

Prospect	Hole ID	Downhole Intersection	Intersection Material Type	DepthFrom(m)	DepthTo(m)	Comments	HoleType	CollarEasting(m)	CollarNorthing(m)	CollarElevation(m)	Dip(°)	Azimuth(°TN)	HoleLength(m)
MM	TAR036	no significant intersections		0	63		RC	40,763	99,111	333	-51	90	63
MM	TAR037	2m @ 2.45g/t Au	100% Oxide	36	38		RC	40,746	99,042	334	-51	91	60
MM	TAR038	2m @ 0.49g/t Au	100% Oxide	51	53		RC	40,774	99,056	334	-51	88	58
MM	TAR045	no significant intersections		0	70		RC	40,733	99,092	333	-51	93	70
			Improve Definition of Grade Distribution in Certain Segments of Mineral Resource at Obi Prospect
OBI	TAA161	19m @ 0.75g/t Au	100% Oxide	5	24		AC	40,662	95,800	380	-51	114	36
OBI	TAA160	12m @ 1.26g/t Au	100% Oxide	6	18		AC	40,674	95,668	379	-51	114	46
OBI	TAA300	12m @ 0.68g/t Au	100% Oxide	22	34		AC	40,601	96,285	384	-50	115	50
OBI	TAA306	14m @ 0.77g/t Au	100% Oxide	37	51		AC	40,593	96,659	375	-51	115	54
OBI	TAA307	14m @ 0.86g/t Au	100% Oxide	13	27		AC	40,618	96,662	381	-51	115	35
OBI	TAA309	16m @ 0.87g/t Au	100% Oxide	16	32		AC	40,604	96,779	376	-51	114	47
OBI	TAR002	13m @ 0.78g/t Au	100% Oxide	68	81	ended in mineralisation	RC	40,628	95,662	379	-48	114	83
OBI	TAR053	2m @ 0.44g/t Au	100% Oxide	50	52		RC	40,618	95,801	380	-50	114	96
		16m @ 0.77g/t Au	69% Oxide / 25% Trans / 6% Fresh	80	96	ended in mineralisation	RC
			Improve Definition of Grade Distribution in Certain Segments of Mineral Resource Risk Reduction at Kenobi Prospect

KENOBI	TAA181	20m @ 0.67g/t Au	100% Oxide	28	48	ended in mineralisation	AC	41,392	97,114	370	-80	271	48
KENOBI	TAA182	12m @ 0.85g/t Au	100% Oxide	43	55	ended in mineralisation	AC	41,309	97,239	367	-55	90	57
KENOBI	TAA183	6m @ 0.95g/t Au	100% Oxide	12	18		AC	41,323	97,145	369	-73	270	61
KENOBI	TAA418	no significant intersections		0	57		AC	41,383	97,008	372	-76	291	57
KENOBI	TAA419	15m @ 1.06g/t Au	100% Oxide	10	25		AC	41,345	97,066	371	-76	289	53
KENOBI	TAA283	no significant intersections		0	21		AC	41,492	97,348	365	-53	90	21
KENOBI	TAA285	no significant intersections		0	40		AC	41,539	97,816	357	-52	90	40

		Upgrade from Unclassified to Inferred Mineral Resource at Obi Prospect
OBI	TAA164	no significant intersections		0	47		AC	40,745	96,882	378	-83	271	47
OBI	TAA165	2m @ 2.37g/t Au	100% Oxide	21	23		AC	40,788	96,908	377	-80	271	45
OBI	TAA301	no significant intersections		0	25		AC	40,571	96,494	375	-50	111	25
OBI	TAA302	2m @ 0.81g/t Au	100% Oxide	36	38		AC	40,538	96,505	374	-50	111	65
OBI	TAA303	no significant intersections		0	25		AC	40,561	96,557	375	-55	90	25
OBI	TAA304	no significant intersections		0	35		AC	40,555	96,655	373	-50	115	35
OBI	TAA305	7m @ 0.57g/t Au	100% Oxide	1	8	started in mineralisation	AC	40,529	96,652	371	-50	115	52

Prospect	Hole ID	Downhole Intersection	Intersection Material Type	DepthFrom(m)	DepthTo(m)	Comments	HoleType	CollarEasting(m)	CollarNorthing(m)	CollarElevation(m)	Dip(°)	Azimuth(°TN)	HoleLength(m)
OBI	TAA308	no significant intersections		0	70		AC	40,538	96,768	372	-50	114	70
OBI	TAA310	no significant intersections		0	43		AC	40,786	96,836	379	-50	121	43
OBI	TAA311	4m @ 0.61g/t Au	100% Oxide	3	7		AC	40,755	96,980	376	-52	115	54
		2m @ 0.68g/t Au	100% Oxide	37	39		AC
OBI	TAA312	4m @ 1.07g/t Au	100% Oxide	5	9		AC	40,778	96,981	376	-50	115	40
OBI	TAA313	no significant intersections		0	33		AC	40,798	96,981	376	-50	115	33
		Upgrade from Unclassified to Inferred Mineral Resource at MC Prospect
MC	TAA202	no significant intersections		0	35		AC	41,138	98,985	340	-55	90	35
MC	TAA203	2m @ 1.94g/t Au	100% Oxide	11	13		AC	41,104	98,965	340	-55	90	51
MC	TAA223	no significant intersections		0	64		AC	41,067	100,435	334	-50	92	64
MC	TAA293	no significant intersections		0	61		AC	41,052	98,987	339	-57	90	61
MC	TAA294	2m @ 1.13g/t Au	100% Oxide	9	11		AC	41,103	99,020	339	-56	90	38
		3m @ 1.40g/t Au	100% Oxide	21	24		AC

Notes: The reported composites for the drilling were determined using a cut-off grade of 0.30g/t Au to select significant and anomalous intersections, with a maximum of 2m internal dilution being incorporated into the composite where appropriate. No top-cuts were applied to assaysfor constituent samples. Isolated mineralised intersectionsless than 2m in downhole length have not been reported. Higher grade zones within the reported composite are included where the average grade of the internal zone is approximately 4x grade of the reported composite grade. Collar position reported under Sanutura Project Grid (2022). Hole azimuths reported relative to true north. Intersection material type listing based on visual logging of relative proportions of weathered, transition and fresh material intersected over the downhole length for the reported intersection.

APPENDIX B – REFERENCES TO PREVIOUS ASX DISCLOSURE

Date	Title
11 March 2022	Sarama Resources Prospectus
9 August 2022	Sarama Resources News Release
1 September 2022	Sarama Resources News Release
8 September 2022	Sarama Resources News Release
6 October 2022	Sarama Resources News Release
29 November 2022	Sarama Resources News Release
14 December 2022	Sarama Resources News Release
17 January 2023	Sarama Resources News Release

APPENDIX C – JORC CODE (2012 EDITION) – TABLE 1 INFORMATION

Section 1 Sampling Techniques and Data

(Criteria in this section apply to all succeeding sections.)

Criteria	JORC Code Explanation	Commentary
SamplingTechniques	Nature and quality of sampling (e.g. cutchannels, random chips, or specificspecialised industry standard measurementtools appropriate to the minerals underinvestigation, such as down hole gammasondes, or handheld XRF instruments, etc).These examples should not be taken aslimiting the broad meaning of sampling.	PrefaceThe Sanutura Project (the "Project") is comprised of severalexploration properties over which exploration has occurred to varying degrees. Themajority of exploration has been conducted over several phases by Sarama Resources ("Sarama") since 2011 andhas resulted in the discovery of theTankoro Deposit. Several Mineral Resource estimates have been completed for the deposit over time and exploration activitiescontinue. In 2016,Sarama acquired the Djarkadougou 2 Property, which hosts the Bondi Deposit, from Orezone Gold Corp ("Orezone") and integrated the property intothe greater Sanutura Project. A significant amount of phased exploration work was conducted by Orezonein the period 2003-2016, culminating in anestimate of Mineral Resources in 2009. At present, the bulk of the exploration work on the Djarkadougou 2 Property is attributable to Orezone'soperating era, however Sarama completed an updated Mineral Resourceestimate in 2021 and is continuing exploration activities.
		Grab samples have been collected on an ad-hoc basis in areas of geological interest and for material of geological or mineralogical interest.Soil geochemistry sampling (Sarama) -samples have been collected using both handheld digging (500mm depth) and mechanical auger collectionmethods (average depth ~5m) to sample the sub-surface material. Auger holes were logged on 1m intervals and were partially sampled over 1mintervals at specific downhole points according to the regolith profile.
		Soil geochemistry sampling (Orezone) -significant soil geochemical sampling was undertaken on the Djarkadougou 2 Property by Orezone using similarpractices to those used by Sarama, however specific procedures are not known.
		Rotary-air-blast ("RAB"), aircore ("AC") and reverse-circulation ("RC") drilling (Sarama)–chip samples are collected by cyclones on the drill rigs at 1mdownhole intervals.
		RC drilling (Orezone) –chip samples are collected by cyclones on the drill rigs at 1m downhole intervals.
		AC and RC drilling (other operators aside from Sarama and Orezone) –chip samples were collected on a drilled interval (generally 1m length) basisusing common industry equipment, but the specific details are unknown.
		Diamond drilling ("DC") (Sarama & Orezone) –samples collected half drill core produced from drill core retrieved in barrels and sawn in half alonglongitudinal axis. Core sampled according to geological contacts and was generally ~1m in downhole length.
		In all cases of drilling:
		•the use of nominal 1m sample intervals is deemed appropriate for the style of mineralisation being targeted;•drilling has generally been oriented close to perpendicular to the expected strike of mineralisation to sample the mineralisation appropriately; and•details on the preparation of sub-samples,QA/QC protocols and analytical techniques are included in following sections.
	Include reference to measures taken toensure sample representivity and the	The use of digital survey equipment to capture and project point sample locations facilitates spatial referencing and assessment of samplerepresentativity relative to in-site mineralisation:
		•all drillhole collars and soil geochemistry sample points have been surveyed using digitalinstruments of appropriate accuracy; and

	appropriate calibration of any	•RC and DC drilling has been downhole surveyed using specialised equipment.
	measurement tools or systems used.	The calibration details of survey instruments used by other operators is unknown, but Sarama and its drill contractors undertake regular instrumentcalibration.
		Drill sampling protocols used by Sarama incorporate consideration of downhole conditions and the use of equipment designed for drilling operations.Sarama typically collects samples in continuous intervals to ensure representativity across the mineralisation. Drilling by other operators appears tohave been carried out using similar protocols, however specific details are unknown.
		Further details on sampling and sub-sampling protocols are listed in the following sections.
	Aspects of the determination ofmineralization that are Material to the	The presence of gold mineralisation has been identified usingstructured exploration programs which feature soil geochemistry and grab sampling inthe early stages, before drilling in more advanced exploration.
	Public Report.In cases where 'industry standard' work hasbeen done this would be relatively simple	The presence of in-situ gold mineralisation that is reported from drilling has been determined using gold assays above background levels (nominally>0.2-0.3g/t Au) which are continuous over lengths >2m. Composite reporting is used to produce a single drill intercept for aparticular intersection ofmineralisation.
	(eg 'reverse circulation drilling was used toobtain 1 m samples from which 3 kg waspulverised to produce a 30 g charge for fireassay'). In other cases, more explanationmay be required, such as where there iscoarse gold that has inherent samplingproblems. Unusual commodities ormineralization types (eg submarinenodules) may warrant disclosure of detailedinformation.	Details on sampling, sub-sample preparation, analytical techniques and reporting of significant results are contained in the following sections. Thesemethods are industry-standard.
DrillingTechniques	Drill type (eg core, reverse circulation,open-holehammer, rotary air blast, auger,Bangka, sonic, etc) and details (eg corediameter, triple or standard tube, depth ofdiamond tails, face-sampling bit or othertype, whether core is oriented and if so, bywhat method, etc).	Drilling by Sarama consisted ofRAB, AC and RC drill types:•RAB drilling used a 90mm diameter cutting blade;•AC drilling used a 70-85mm diameter cutting blade(for 2022 drilling, a 70-90mm hole diameter, using either a cutting blade or face samplinghammer according to material type being encountered);•RC drilling utilised a face sampling hammer with 127-140mm bit size; and•DC drilling was completed with rigs equipped with a conventional core barrel to retrieve HQ (63.5 mm) core, reduced to the NQ(47.6 mm) diameterin the lower part of the hole. Core orientation was initially identified by spear imprint, before a change to digital method (Reflex ACT II & III).Drilling by Orezone (Djarkadougou 2 Property) consisted of AC, RC and DC drill types:•AC drilling details are unknown;•RC drilling used a 5-inch hammer bit. When water was encountered, the upper portion of the hole was reamed, and the hole was completed bycore drilling; and•DC drilling was completed with rigs equipped with a conventional core barrel to retrieve HQ (63.5 mm) core, reduced to the NQ (47.6 mm) diameterin the lower part of the hole. Core orientation was by spear imprint, but details of the method are not known.No details are available for drilling completed by other operators.
Drill SampleRecovery	Method of recording and assessing coreand chip sample recoveries and resultsassessed.	RAB, AC and RC sample weights are recorded in the database for each sample length drilled. Comparison of actual vs theoretical sample weights on akg/drilled metre basis (using assumed hole diameter and material SG) gives an indication of the completeness of sample recovery. For DC drilling,recovered core lengths are compared to drilled length to give a measurement of core sample recovery.

RAB drilling (Sarama) – no sample recovery data is available

AC drilling (Sarama) – sample recovery data (coarse sample weight/interval) is available for approximately 77% of the total drilling and sub-sample weights/interval (for lab submission) are recorded for approximately 83% of the drilling with missing primary sample weights. It appears that sufficient sub-samples were available for assaying in the majority of cases.

For the 2022 AC drilling reported in this disclosure, sample recovery data (coarse sample weight/interval) is available for approximately 99% of the total drilling and sub-sample weights/interval (for lab submission). It appears that sufficient sub-samples were available for assaying (1.1-3.0kg) in all cases. For the available coarse samples recovered from 70mm holes, sample weights varied from N/A kg/m drilled and averaged (length weighted) N/A kg/m drilled, and for 90mm holes, sample weights varied from 4.5-25.5kg/m drilled and averaged (length weighted) 14.0kg/m drilled. This compares to a theoretical sample weight of 9.6kg/m drilled and 15.3kg/m drilled for a nominal 70mm hole with an allowance of 15mm diameter wall overbreak in oxide (SG 1.7) and fresh rock (unweathered quartz vein with SG 2.7) respectively; and 14.7kg/m drilled and 23.4kg/m drilled for a nominal 90mm hole with an allowance of 15mm diameter wall overbreak in oxide (SG 1.7) and fresh rock (unweathered quartz vein with SG 2.7) respectively . This is considered to be of a high standard.

RC drilling (Sarama) - sample recovery data (coarse sample weight/interval) is available for approximately 94% of the total drilling and sub-sample weights/interval (for lab submission) are recorded for 71% of the drilling with missing primary sample weights. It appears that sufficient sub-samples were available for assaying (0.1-11.6kg) in all cases.

For the 2022 RC drilling reported in this disclosure, sample recovery data (coarse sample weight/interval) is available for approximately 96% of the total drilling and sub-sample weights/interval (for lab submission). It appears that sufficient sub-samples were available for assaying (0.2-3.0kg) in all cases. For the available coarse samples recovered from 127mm holes, sample weights varied from 0.5-45.0kg/m drilled and averaged (length weighted) 20.7kg/m drilled, and for 140mm holes, sample weights varied from 4.0-80.0kg/m drilled and averaged (length weighted) 26.4kg/m drilled. This compares to a theoretical sample weight of 26.9kg/m drilled and 42.8kg/m drilled for a nominal 127mm hole with an allowance of 15mm diameter wall overbreak in oxide (SG 1.7) and fresh rock (unweathered quartz vein with SG 2.7) respectively; and 32.1kg/m drilled and 50.9kg/m drilled for a nominal 140mm hole with an allowance of 15mm diameter wall overbreak in oxide (SG 1.7) and fresh rock (unweathered quartz vein with SG 2.7) respectively. This is considered to be of a high standard.

RC drilling (Orezone) – sample recovery data (coarse sample weight/interval) is available for approximately 93% of the total drilling and sub-sample weights/interval (for lab submission) are recorded for 0% of the drilling with missing primary sample weights. It appears that sufficient sub-samples were available for assaying (1-2kg) in all cases. For the available coarse samples recovered, sample weights varied from 1.0-86kg/m drilled and averaged (length weighted) 27kg/m drilled (compared to a theoretical sample weight of 25.3kg/m drilled for a nominal 125mm hole and a material SG of 2.0) which is considered to be of a high standard

RC drilling (other operators) – no sample recovery data is available.

DC drilling (Sarama) – core length recovery data is available for 100% of drilling and averages 97%. This is a high level of sample recovery.

DC drilling (Orezone) – no specific details are available on procedures and sample recovery is unknown.

Measures taken to maximize sample recovery and ensure representative nature of the samples.

AC & RC drilling (Sarama) – samples are collected by cyclones on the drill rigs at 1m intervals. The full drilled interval is collected before sub-sampling. In the case of reconnaissance AC drilling, a sub-sample of the drilled interval is produced at the drill site using a riffle splitter. In the case of higher-level AC and RC drilling, the full drilled interval sample is transported from the drill site to a preparation facility where is it dried before sub-sampling by riffle splitter. In all cases and since 2012, AC and RC drilling is terminated if water ingress into the hole is deemed significant to reduce the potential for sample smearing. For the RC and AC drilling cyclone and riffle splitters are routinely cleaned before each new interval is drilled. The use of 1m sample intervals is deemed appropriate for the style of mineralisation being targeted. Drilled sample recovery is computed and gives an indication quality of sample.

RAB drilling (Sarama) – sampling followed a similar procedure for reconnaissance type AC drilling. Due to the passage of drill cuttings up the side of the drilled hole, sample contamination is common in the drilling and the sampled interval is not necessarily representative of the drilled interval's mineralisation.

		RC drilling (Orezone) –sampling procedures similar to those used by Sarama were adopted.
		AC & RC drilling (other operators) -the procedures and techniques employed by other operators are unknown.
		DC drilling (Sarama & Orezone) -diamond core retrieved on a continuous basis and was reconstructed into continuous runs on an angle iron cradle fororientation. Depths are checked against the depth on the core blocks and rod counts were routinely carried out by the drillers. Core was stored inpurpose-built trays before, during and after sampling. In the case of drilling by Sarama, drilled sample recovery is computed and gives an indicationquality of sample.
	Whether a relationship exists betweensample recovery and grade and whether	Sample recovery for diamond holes is generally very high (97%) within the mineralised zones (>0.2g/t Au). Ground conditions for AC and RC drillingwere good and drilling generally returned consistent size samples.
	sample bias may have occurred due topreferential loss/gain of fine/coarsematerial.	No significant bias is expected, and any potential bias is not considered material at this stage of resource development.
Logging	Whether core and chip samples have beengeologically and geotechnically logged to alevel of detail to support appropriateMineral Resource estimation, miningstudies and metallurgical studies.	Sarama -All drilling is geologically logged and recorded in a central database and depending on sample quality may be suitable to thesupport higherleveltechnical work. AC and RC drilling data recorded includes rock types, structures, quartz veining type and percentages, sulphide occurrence andalteration type and intensity. Sample recovery and quality, water table depth and water inflows were also notedduring logging. Diamond drilling useda similar logging system, but also included structural measurements, basic geotechnical data and core recovery. Diamond core was logged accordingto geological domains identified by geologists. The data is sufficiently detailed to inform a Mineral Resource estimate.
		Orezone –logging practices to those used by Sarama were adopted and data is considered suitable for estimation of Mineral Resources.
		Other operators -Geological logging for by other operators is not fully available and it is unlikely that this drilling would be suitable for the purposesof higher-level technical work.
	Whether logging is qualitative orquantitative in nature. Core (or costean,channel etc) photography.	Sarama -Logging has been conducted both qualitatively and quantitatively –full description of lithologies, alteration and comments are recorded, aswell as percentage estimates on veining and sulphide amount. Visual estimates of percentages of key minerals associated withgold mineralization andveining were made. For all diamond core, digital photographs are taken of each core tray in a wet and dry state
		Orezone –Where available, logging has been conducted both qualitatively and quantitatively –full description of lithologies, alteration and commentsare recorded, as well as percentage estimates on veining and sulphide amount. Visual estimates of percentages of key minerals associated with goldmineralization and veining were made. For all diamond core, digital photographs are taken of each core tray in a wet and drystateOther operators –only basic logging was conducted.
	The total length and percentage oftherelevant intersections logged.	Total length of drilling and samplingto 31 December 2021:
		•RAB (Sarama) –14,100m drilled / 14,100m logged / 14,100m sampled & assayed•AC (Sarama) –141,500m drilled / 141,300m logged / 141,300m sampled & assayed
		•AC (Orezone) –2,200m drilled / 2,200m logged / 1,800m sampled & assayed
		•RC (Sarama) –92,200m drilled / 91,900m logged / 91,000m sampled & assayed
		•RC (Orezone) –63,300m drilled / 62,800m logged / 62,700m sampled & assayed
		•RC (other operators) –2,000m drilled /1,500m logged (basic) / 1,600m sampled & assayed•DC (Sarama) –38,900m drilled / 38,700m logged / 35,000m sampled & assayed
		•DC (Orezone) –17,100m drilled / 16,800m logged / 16,500m sampled & assayed
		For the 2022 drilling reported previously:
		•AC (Sarama) –10,865m drilled / 100% logged / 98% sampled & assayed

		•RC (Sarama) –3,071m drilled / 100% logged / 98% sampled & assayed
		For the 2022 drilling reported in this disclosure:
		•AC (Sarama) –3,687m drilled / 100%logged / 99%sampled & assayed
		•RC (Sarama) –1,771m drilled / 100% logged / 96% sampled & assayed
Sub-Sampling	If core, whether cut or sawn and whether	All core was half-cut lengthwise using a diamond saw parallel to the orientation line.
Techniques andSample	quarter, half or all core taken.	One half of the core was sampled, generally on 1m intervals, but shorter intervals were used to honour geological contacts asbest as possible.
Preparation	If non-core, whether riffled, tube sampled,rotary split, etc and whether sampled wet	Soil geochemistry sampling undertaken by Sarama, sub-samples are produced from the sieving of a dry sample collected at shallow depth from surface.The protocols for other operators arenot known.
	or dry.	RAB, AC and RC drilling (Sarama) -sub-samples areproduced from the drilled interval sample using a 'Controlab' stainless steel riffle splitter. In generaldrilling is terminated if/when water ingress into the hole is deemed to be excessive with the result that drilled samples aremainly dry or at the worst,moist.
		•For reconnaissance RAB and AC drilling, sub-samples are prepared at the drill site and placed into sealed and tagged bags –these sub-samples aremainly dry, but some will be moist.•For higher-level AC and RC drilling, drilled samples are bagged at the drill site and transported to preparation facilities where they are placed into
		drying trays/tubs for subsequent riffle-splitting –these sub-samples will be dry.
		RC drilling (Orezone) -drilled samples are bagged at the drill site and transported to preparation facilities where they are placed into drying trays/tubsfor subsequent riffle-splitting –these sub-samples will be dry.
		Other operators' drilling -the sub-sampling practices by other operators is not known.
	For all sample types, the nature, quality	The methodologies for initial preparation of sub-samples are discussed above.
	and appropriateness of the samplepreparation technique.	Sub-sample weights produced for submission to the analytical laboratories, are generally in the range of 1-2kg (Sarama) and 2-5kg (Orezone) but willdepend on the requirements of specific analytical techniques used. This is considered appropriate for the style of mineralisation and the nature of theexploration programs.
		At the analytical laboratories, further sub-sampling takes place as follows:
		•Soil geochemistry surveys –usually none, as the full sub-sample is generally used as charge for cyanidation-based gold determination; and•Drilling –(Sarama) sub-samples are finely crushed (approx. 2mm), pulverised (to typically 85-95% passing 75µm) using a specialised equipmentand an approximate 200g sub-sample of the pulp is taken of which a further sub-sample of 50g is produced by using a simple scoop method forfinal fire assaying.
		•Drilling –(Orezone) the entire sub-sample for RC (5kg) and DC (2kg) was dried, crushed to 6mm and ground in a vertical continuous Keegor discpulveriser to achieve 75-95% passing 75µm. The samples were further riffle split to 2kg (for BLEG analyses) or 500g (for fire assays). Inthe eventof leach tail determination by fire assay, the leached tail material is collected, washed and dried before being homogenised and sub-sampled,before a final 50g sub-sample of the leached pulp is taken by a scoop.
		These laboratory-based sub-sampling methods are considered appropriate for the style of mineralisation and the nature of the exploration programs.
		Details of QAQC protocols implemented by Sarama, other operators and analytical laboratories to monitor sampling and sub-sampling quality arediscussed below.

	Quality control procedures adopted for all	Details of primary sampling and methods with the aim of producing representative sample are included above.
	sub-sampling stages to maximiserepresentivity of samples.	Diamond core recovery percentage, RC/AC sample weights and sample quality were measured, recorded and monitored to ensure an adequate andrepresentative sub-sample was collected.
		For its sub-sampling and analytical activities, Sarama used a QAQC system that features the use of field duplicates, pulp duplicates, standard referencematerials and blanks to monitor sampling, sub-sampling and sample representivity, along with analytical precision and repeatability. In particular, thevarious sub-sampling activities are monitored and assessed using the following methodologies:
		•in the case of chip samples from drilling, production of sub-samples from drilled interval samples is undertaken by purpose-specific riffle splitters(on dry samples for higher-level AC and RC drilling)with field duplicates taken to assess sample splitting effectiveness;•for core sampling the same side is consistently sampled, half-core with the bottom of hole line being retained in the tray; and•production of pulp sub-samples for the analytical stage is undertaken at dedicated analytical laboratories which only sub-samples homogenisedpulverised material, with reference and blank material of known grades inserted into the pulp sample streams at regular intervals to monitor theprecision and accuracy of analytical equipment and the cleanliness of pulp preparation and handling.
		For analytical laboratories used by Sarama, the analytical precision and accuracy of the laboratories' equipment and cleanliness of pulp sub-samplepreparation and handling is monitored internally by the lab using certified reference materials (standards and blanks) and repeat assays. Dependingon the laboratory, certain accreditation protocols, both internal and external, will be in place. While not known, it is likely that such procedures werein place for the laboratories used by other operators.
		Details of duplicate and reference material insertion rates by Sarama, and where available, by other operators, are in subsequent sections.
		The results of the internal laboratory qualitycontrol are reported regularly to Sarama on a batch-by-batch basis, and the results were closely monitoredby Sarama personnel.
		Ad-hoc QAQC activities, including check assaying and re-sampling, were conducted by both Sarama and Orezone.
	Measures taken to ensure that thesampling is representative of the in-situmaterial collected, including for instanceresults for field duplicate/second-halfsampling.	Sarama & Orezone -The details of protocols for the collection of primary and sub-samples and their representivity of in-situ material is included inpreceding and succeeding sections.
		The sub-sample sizes are considered appropriate and representative of the gold mineralisation being sampled based on:
		•the style of mineralisation (disseminated veinlet-controlled gold deposit)•the width and continuity of the intersections
		•the grain size of the material being collected, and
		•the assay value ranges for gold at the parts per million accuracy level.
		Other operators -The specific QAQC protocols of other operators are not known, however sourced data indicates that such systems were in place.
	Whether sample sizes are appropriate tothe grain size of the material beingsampled.	The sample and sub-sample sizes (length and weight) are considered appropriate and representative of the style of mineralisation and the form anddistribution of gold within the mineralised area. Future work is planned to examine the volume variance effect on analyticalassay results.
Quality of	The nature, quality and appropriateness of	Specifics
Assay Data andLaboratoryTests	the assaying and laboratory proceduresused and whether the technique isconsidered partial or total.	•Soil geochemistry (Sarama & Orezone) -samples of approximately 2kg weight were assayed by the bulk leach extractable gold ("BLEG") methodwhich uses a NaCN solution to leach gold over a 24-hour period, with the liquor subsequently analysed by AAS instrumentation.•Soil geochemistry (other operators) –unknown but likely similar to the Sarama analytical technique.•RAB, AC, RC and DC drilling (Sarama) -a nominal 50g pulp charge was analysed for gold by lead collection fire assay with AAS instrumentation.
		•AC, RC and DC drilling (Orezone) –samples of approximately 2kg weight were assayed by the bulkleach extractable gold ("BLEG") method whichuses a NaCN solution to leach gold over a 24-hour period, with the liquor subsequently analysed by AAS instrumentation. The leached tails for

	head samples with leach grades >0.5g/t Au were commonly subjected to fire assaying to determine gold content of the tail.
	General
	The fire gold analysis is a total assay method, which is an industry standard for gold analysis, and an appropriate assay method for this type ofmineralisation and for the purpose of the program.
	The BLEG method is a partial assay technique, which is an industry standard for gold analysis, and an appropriate assay method for soil geochemistryand early-stage reconnaissance type drilling. The use of the analytical technique is only appropriate for higher-order analytical work if the tail of theleach stage is subsequently analysed (thereby converting the level of gold grade determination from partial to full).
	For the samples with assay details available, the analytical laboratories used (SGS and ALS) and currently operate under to internationally recognisedstandards. It is not known whether the laboratories operated to these standards for the historical analytical work, however the laboratories are partof large international organisations that routinely conduct assaying as a core business so it is likely that internal QAQC measures were in place to ensurequality of work.
For geophysical tools, spectrometers,handheld XRF instruments, etc, the	pXRF units were used by other operators for multi-element analysis of soil geochemistry samples, however the calibration details are not known bySarama. The data is not used for higher-order work.
parameters used in determining theanalysis including instrument make andmodel, reading times, calibrations factorsapplied and their derivation, etc.	No geophysical tools were used or data analysed for drilling.
Nature of quality control procedures	Details of the prevalence of QAQC primary sampling detailed below. In general:
adopted (egstandards, blanks, duplicates,external laboratory checks) and whetheracceptable levels of accuracy (i.e. lack ofbias) and precision have been established.	•the QAQC regime implemented by Sarama is considered acceptable (accuracy and precision) for the nature ofthe exploration programs and forthe intended use of the data; and•the QAQC regime implemented by Orezone for its work on the Djarkadougou 2 Property, while comprehensive in design and magnitude, is broadlyineffective in monitoring sampling and analytical practices and as a result the assay database is of low confidence. This results from the generationof gold assays from bulk cyanidation of samples (without leach tail fire assay) for which gold dissolution ranged 60-90%. This issue has produceda negative bias in gold values in the assay database and erodes the effectiveness of QAQC monitoring. The QAQC system implemented was foundto be ineffective in externally monitoring analytical lab performance and sample preparation activities, resulting from the use of in-house preparedreference materials which appear to be highly variable in gold grade. Field practices that Orezone employed for sample collection and sub-samplingwere probably of a reasonable standard, however this can't be assessed definitively because of the above issues.•No data on external checks on the results of the primary laboratories are available.
	The prevalence of QAQC elements in the production streams by various operators is listed below:
	Sarama QAQC
	•Soil geochemistry sampling –the QAQC regime featured insertion of uncertified reference materials into the production stream and the use offield duplicate. Design insertion rates for totalQAQC elements were 3% (2011-2013) and 6% (2014-present).•Auger drilling –the QAQC regime featured insertion of uncertified reference materials into the production stream and the use of field duplicatesampling. Design insertion rates for total QAQC elements were 3% (2011-2012) and 5% (2015-present).•RAB drilling –no QAQC elements used.•AC drilling –the QAQC regime featured insertion of certified reference materials (2012 activities used uncertified reference materials) into theproduction stream and the use of field duplicate sampling. Actual insertion rates for total QAQC elements were 4% (2012-2014, no field duplicatesused), 9% (2015-2016) and 11% (2016-2019).•RC drilling –the QAQC regime featured insertion of certified reference materials into theproduction stream and the use of field duplicate sampling.Actual insertion rates for total QAQC elements were 6% (2011-2014), 8% (2015-2016) and 5% (2016-2019).

		•DC drilling–the QAQC regime featured insertion of certified reference materials into the production stream sampling. Actual insertion rates fortotal QAQC elements were 6% (2012-2015), 6% (2016) and 8% (2016-2019).•For the drilling reposted in this disclosure: the QAQC regime featured insertion of certified reference materials (uncertified reference material forone blank element) into the production stream and the use of field duplicate sampling. Actual insertion rates for total QAQCelements were 11%for AC drillingand 11% for RC drilling. Coarse reject sampling was undertaken on an ad-hoc basis for certain AC sample intervals.Orezone QAQC•Soil geochemistry sampling–details unknown.•Auger drilling–details unknown.•AC drilling –the QAQC regime actual insertion rates for total QAQC elements was 28% (2003-2016).•RC drilling -the QAQC regime actual insertion rates for total QAQC elements was 29% (2003-2016).•DC drilling -the QAQC regime actual insertion rates for total QAQC elements was 16% (2003-2016).
		Other operators' soil geochemistry & drilling -the QAQC practices used by other operators is not known.
Verification of	The verification of significant intersections	Regional Exploration
Sampling andAssaying	by either independent or alternativecompany personnel.	Regional exploration has employed similar procedures s those for the Tankoro and Bondi Deposits (reviews outlined below). Results from regionalexploration are not considered 'significant' to the Project given the magnitude of Mineral Resources at he Tankoro and Bondi Deposits.
		Tankoro Deposit
		Cube Consulting assessed the veracity of the drilling data during site visits in 2011 and 2012. Verification work, pertaining to sampling and assayingincluded:
		•the collection of 160 independent samples by Cube comprising field and umpire duplicates for both the RC and diamond drilling; and•the summary logging of 16 diamond holes by Cube and comparison with corresponding Sarama logging and assay results.
		Cube concluded that the mineralised intercepts returned from the summary logging confirmed the original Sarama logging and assay tenor in theSarama database and that the comparison of the replicate verification assays to the original assays for the mineralised intercepts were consideredacceptable and confirmed the drill assays reported by Sarama. While significant exploration has taken place since Cube's verification work, the practicesemployed for sampling and assaying have remain largely unchanged and the outcomes of the review are considered relevant and have coverage oversampling and assaying considered 'significant' to the Project (excluding the Djarkadougou 2 Property).
		In 2018, as part of a site visit and re-estimate of the mineral inventory at the Tankoro Deposit, SRK Consulting undertook the following verificationwork:
		•extensive review of the geological and drill database;•review of the data collection methodologies during a site visit;•QAQC review of sampling and assay data; and•geological modelling of the Tankoro Deposit.
		SRK concluded that the assay data provided was of sufficiently high quality and had been subjected to a sufficiently high level of checking to support aMineral Resource estimate. Limited exploration has been conducted on the Project since this phase of work so the results of the SRK review areconsidered relevant and have coverage over sampling and assaying considered 'significant' to the Tankoro Deposit.
		During the period 2012-2021, Cube Consulting completed several phases of QAQC review for the drillhole database as part of updates to MineralResource and mineral inventory estimates. The reviews have focussed on sample collection and assaying, form part of a continuous improvementcycle, and are considered relevant and have coverage over sampling and assaying considered 'significant' to the Tankoro Deposit.

For the drilling reported in this disclosure, no independent verification of significant intersections has taken place. In general, all intersections of significance are reviewed by at least 2 company personnel.

Bondi Deposit

During Orezone's operatorship of the Djarkadougou 2 Property (hosting the Bondi Deposit), Met-Chem undertook a site visit in 2007 and an audit of the databases, the logging and sampling procedures, QAQC program and a visit to the three laboratories in Ouagadougou. Conclusions from the audit included the following relevant points:

• the performance of the blanks and standards was variable, and they could not be used to monitor accuracy of the laboratories;
• duplicate assay results verified of 44 RC field duplicates and 15 core pulps by Met-Chem suggested a moderate repeatability, particularly for the range of values above 15 ppb Au;
• no systematic bias was detected in the underlying assay data;
• a more aggressive leach extractable assay method (Leachwell) was recommended to counter the incomplete leaching of the gold when using BLEG which may have caused a negative bias in the head assays;
• the homogeneity of the in-house standard and blank materials needed improvement;
• the source of the poor blank performance needed to be determined and addressed;
• the origin of the variability between the original and duplicate sample analytical results needed to be determined and controlled if possible; and
• Met-Chem believed the field data, the geological interpretation and the parameters used for the resource estimate were collected, handled and interpreted by experienced people and fairly reflected the geological and gold grade continuity of the main deposits.

The bulk of the exploration work for the Bondi Deposit was conducted in the 2005-2007 period so the results of the review are considered relevant and have coverage over sampling and assaying considered 'significant' to the Bondi Deposit.

In 2021, as part of an updated Mineral Resource estimate for the Bondi Deposit, Sarama undertook a retrospective review of the drillhole database, with particular focus on analytical performance for drilling informing the Bondi Deposit. The review concluded that the gold assays for the deposit generated during Orezone's operatorship have low confidence. This results from the generation of gold assays from bulk cyanidation of samples (without leach tail fire assay) for which gold dissolution ranged 60-90%. This issue has produced a negative bias in gold values in the assay database and erodes the effectiveness of QAQC monitoring. The QAQC system implemented was found to be ineffective in externally monitoring analytical lab performance and sample preparation activities, resulting from the use of in-house prepared reference materials which appear to be highly variable in gold grade. The review determined that the field practices that Orezone employed for sample collection and sub-sampling were probably of a reasonable standard, however this couldn't be assessed definitively because of the above issues. The review is considered relevant and has coverage over sampling and assaying considered 'significant' to the Bondi Deposit.

The use of twinned holes.	Tankoro Deposit
	5 x RC holes and 1 diamond drill hole were twinned by diamond holes at the MM and MC Prospects in the period 2012-2013.
	10x AC holes were twinned by RC holes at the MC, Phantom, OBI and Kenobi Prospects where shallow AC drilling of oxide mineralisation wascompletedfrom 2013 to 2019.
	Although there are significant variations between the mineralised lengths of the AC, RC and DC drilling and also in the average gold grade for theinterval, all the holes confirm the tenor and veracity of the original drill intercepts
	The AC drilling does tend to show a fairly consistent undercall of approximately 24% when compared to the RC drilling and is likely to be a samplesupport issue where the larger volume of the RC sample allows an improvedopportunity for the capture of the gold particles and better represents thehigh local variability of the gold mineralisation.
	For the drilling reported in this disclosure, no twinned holes were drilled.
	Bondi Deposit –no twin drilling undertaken.

		Regional Exploration –no twin drilling undertaken.
	Documentation of primary data, data entryprocedures, data verification, data storage(physical and electronic) protocols.	General Procedures by SaramaData collection for surface prospecting and soil geochemistry surveys undertaken by Sarama generally involves manual logging of information on paperbased records. This information is then translated into electronic format via spreadsheet templates. Datacollection for drilling undertaken by Saramagenerally involves the entry of field logging information directly into electronic format via spreadsheet templates. In bothcases, the spreadsheetbased records are uploaded into master databases maintained by specialist external database administrators.AC, RC and DC drill samples collected by Sarama are retained for future reference. In the case of RC drilling, a small amount of cuttings/chips for eachlogged interval are retained in plastic box trays.The data collection and handling procedures of other operators is not known, however all available sampling information has been incorporated intothe master databases (surface prospecting, soil geochemistry and drilling) for the Project after being translatedfrom the various native forms. Retainedsamples of drilling by other operators are generally not available.Tankoro Deposit Exceptions
		Drilling completed by Acacia Mining in 2017-2018 was logged and compiled in a separate process. A final Microsoft Access database was used totranslate logging and sampling data from the Acacia Mining system to Sarama's database structure. Validation checks were performed to ensure dataintegrity. The drilling handled by this process is a relatively minor contributor to the total drilling that informs the Mineral Resource estimate for theTankoro Deposit.Bondi Deposit Exceptions
		The majority of the drilling at the Bondi Deposit was undertaken by Orezone. Upon acquisition of the property by Sarama, Sarama undertook anextensive database rebuild and translation exercise which imported all available data from various spreadsheets and database exports supplied byOrezone. This exercise was conducted on a first principles basis and included re-matching sampling data with analytical laboratory result reports, whichwere uploaded using script-based processes. Sarama undertook several phases of data validation on the final re-compiled database.
	Discuss any adjustment to assay data.	All assay data that is reported as being below analytical detection limit is recorded in the database as a small negative value equivalent to the detectionlimit (for example, <0.01g/t Au is recorded as -0.01g/t Au). For composite reporting, analysis of drill results and modelling, the sample intervals withnegative values recorded in the database were replaced with 'half the detection limit' values (for example -0.01g/t Au replaced with 0.005g/t Au).
		Missing samples and interval gaps denoted by no sample ("NS") or blank records in the databases. For the purposes of composite reporting of drillresults and analysis these intervals were assigned zero grade.
		In both cases, the unaltered base data record is preserved in the database structure.
Location ofData Points	Accuracy and quality of surveys used tolocate drill holes (collar and down-hole	For RC and DC drilling, hole locations were initially identified by a cement marker or plug at the collars, inscribed with the drillhole name. AC drilling isgenerally unmarked but the density of drilling is such that drilled collars can be located based on design co-ordinates prior to final surveying.
	surveys), trenches, mine workings andother locations used in Mineral Resourceestimation.	Drillhole collars are surveyed (X, Y, Z) using either handheld GPS, differential GPS or real-time kinematic GPS equipment. Collar locations for holes usedthe estimation of Mineral Resources were surveyed as follows:
		•Tankoro Deposit -using differential GPS or real-time kinematic GPS equipment which generally provides a level of accuracy of 1-10cm horizontallyand 3-15cm vertically; and•Bondi Deposit –using several methods including total station and DGPS referenced back to local control points. Survey tolerance is unknown.
		Potentially low confidence due to local survey control being informed by regional control points that potentially have erroneous co-ordinatesprovided by the government. With this issue present, some collars have been manually adjusted to fit a reasonable topographic model and whilenot ideal, the flat lying terrain allows for an acceptable level of relative accuracy. Future estimates will incorporate better survey control.

		RC drilling, downhole surveys used a gyroscopic or magnetic field-based instrument (Reflex Ez-Gyro or Ez-Gyro). Readings were taken at the collar (oras close as practicable) and end of hole positions, along with intermediate readings down the length at intervals ranging 5-40m. For diamond drilling,early programs used the Reflex instrument to take downhole readings at approximately 6m past the lowest drill tube.
		•In the case of the Tankoro Deposit, recent downhole surveys were conducted using a self-seeking Ez-Gyro was utilised. After completion of thehole there is an additional survey while coming out of the hole at each 10m.•In the case of the Bondi Deposit, readings were taken at 25-30m downhole increments using a Reflex magnetic field-based instrument.
		For diamond tails drilled from an existing RC hole, the new survey data for the diamond hole section was sometimes appended to the existing RCsurvey data and in other times, the hole re-surveyed over its entire length.
		AC drilling -the holes were not downhole surveyed due to their limited length and probably minor deviation.
		The 3D location of the individual samples is considered to be adequately established, consistent with accepted industry standards and suitable for theestimation of Mineral Resources to the stated confidence levels.
	Specification of the grid system used.	All drillhole data is measured and recorded in the UTM WGS84 datum in Zone 30P (Northern Hemisphere) coordinate system.
		For this disclosure, data is presented in a Sanutura Project Grid (2022) which is a planar reference system oriented along the strike of the TankoroDeposit and shifted to an arbitrary origin.
	Quality and adequacy of topographiccontrol.	Sanutura Project (excluding Djarkadougou 2 Property) -no specific topographical control points are used. Surveying conducted using GPS, differentialGPS or real-time kinematic GPS equipment which gives acceptable accuracy for the stage of the Project and which doesn't require fixed control points.The majority of drilling has been surveyed using high-accuracy DGPS or real-time kinematic equipment.
		Djarkadougou 2 Property –historical surveying conducted by Orezone used several points of topographic control but errors possibly existed ingovernment supplied reference co-ordinates which have translated through to the total station measurements.
		For estimate of Mineral Resources at Tankoro and Bondi Deposits, local topographic models were constructed from drillhole collars within the area ofthe deposits, which is adequate for the stage of the Project and intended use of the information.
Data Spacing	Data spacing for reporting of Exploration	Soil Geochemistry Surveys
and	Results.	The spacing of soil geochemistry surveys varies according to the purpose of the individual campaign and the operators' practices.
Distribution		•800m x 100m grids oriented N090° have been used for initial regional surveys over large areas.•400m x 100m grids oriented N090° have been used for follow-up or more focussed surveys.•100-200m x 50m grids have been used for infill surveys.
		In the case of sampling by Sarama, the depth of sample collection is generally 500mm below the surface but is modified by supervising geologistsaccording to the regolith conditions. The sampling depth for other operators is unknown.
		Auger Drilling
		The spacing of auger drilling for soil geochemistry surveys varies, but is commonly:
		•800m x 50m oriented N090° (for broad-spaced initial sampling); and•400m x 20-30m oriented N090° (for infill sampling).
		Two samples were taken in each hole, 1m apart, at an average depth of approximately 6m.
		RAB, AC & RC Drilling
		The spacing of drillholes varies according to the specific purpose of the drill programs.

		•Fence spacing ranges 10-600m for grid but is typically 50m & 100m. The Tankoro Deposit has typically been drilled on 50-150m fence spacingwhile the Bondi Deposit is drilled on 25-40m spacing for RC (typically 25m spacing) and 50m spacing for DC drilling. Single fence drilling wasemployed to test early-stage targets.•Hole spacing (within each fence) ranges 20-50m but is typically 20m.Downhole sample point spacing for drilling varies by drill type and purpose of the program from 1m to 4m (composited RAB and AC holes in early-stagereconnaissance drilling. Overall, sample point spacing is generally 1-2m and that in Mineral Resource is 1m.
		For the drilling reported in this disclosure, downhole sampling was conducted using 1m intervals.
	Whether the data spacing, and distributionis sufficient to establish the degree ofgeological and grade continuityappropriate for the Mineral Resource andOre Reserve estimation procedure(s) andclassifications applied.	Tankoro & Bondi Deposits –The data spacing and distribution is considered sufficient to establish the degree of geological and grade continuityappropriate for the Mineral Resource category applied. Certain areas of the modelled inventory remain unclassified due to insufficient confidence ingeological and/or grade continuity.
		Regional Project Area - The data spacing and distribution is sufficient for the early-stage exploration works completed to date, however increased datadensity is required for estimation of Mineral Resources in these areas.
	Whether sample compositing has beenapplied.	Depending on the nature of the drill programs, the drilled samples were either maintained as 1m intervals or were sub-sampled and composited intolonger interval sub-samples (commonly 2m or 4m) prior to assaying. Where significant assays were returned, the retained coarserejects of theconstituent intervals of the composite were individually sub-sampled, assayed and results stored in the database as primary assays.
		Soil geochemistry and grab sampling –no compositing has been used.
		RAB drilling (Sarama) –2m compositing has been predominantly used.
		AC drilling (Sarama) –some 2m compositing has been used for assaying of first pass or reconnaissance drilling. Where required, constituent 1mintervals were assayed.
		AC drilling (Orezone) –no compositing used.
		RC drilling (Sarama & Orezone) –very limited use of composite samples (2m).
		RC drilling (Other Operators) –no compositing used.
		For the drilling reported in this disclosure, no compositing was used.
Orientation ofData in	Whether the orientation of samplingachieves unbiased sampling of possiblestructures and the extent to which this isknown, considering the deposit type.	Surface prospecting (grab samples) and soil geochemistry surveys (hand and auger collected) are point samples and were collected somewhatindependent of geological trends. For the early-stage nature of these samples, this is considered acceptable.
Relation toGeological		Tankoro Deposit Drilling
Structure		In general, holes have been drilled on N90°oriented drill fences with holes dipping 40-50° to the east totarget the mineralisation which typically dipssteeply to the west. In certain areas of the deposit, drill fences have been oriented N135° and N180° to better intersect mineralisation oblique to themain lodes which trend N020°. Drill holes have dips of 40-90° to optimise intercepts of mineralisation with respect to thickness and distribution.
		Although the E-W orientated drill lines are oblique to theorientation of the main mineralised trend, structural logging from the diamond drilling hasconfirmed that the drilling orientation has not introduced any sampling bias.
		To the extent known, the drill orientations provide an unbiased sampling of the mineralised lodes as a whole.
		For the new drilling reported in this disclosure, hole orientation was generally and approximately TN90 and TN110-120°, with selected holes orientedat approximately TN270°. The holes generally dipped at ~50° to target the NE to NNE-striking mineralisationwhich dips to the west(generallysteeply).Some of the drilling is reconnaissance in natureand the orientation oftargets is not well understood so the degree of sample bias, if any, is not known.

		Bondi Deposit Drilling
		RC and core holes have largely been drilled against the dip of the mineralized zones. Most of the holes have been drilled toward the west (N270° andN286°) and theeast (N090° and N106°) at a dip of 45-50°. The sub-vertical mineralized zones at the Bondi Deposit are reasonably well determined bythe hole spacing (25 to 50m) and by control on the hole deviation achieved by the down-hole surveys.
		To theextent known, the drill orientations provide an unbiased sampling of the mineralised lodes as a whole.
		Regional Project Drilling
		Drilling has been oriented in several directions according to the purpose and targets of specific programs:
		•majority of drilling is oriented on fences at N310° to N325° which is approximately perpendicular to the trend of the litho-structural corridor, trendof gold-in-soil anomalism and the interpreted strike of mineralisation intersected by drilling (NE-NNE).•majority of drilling has hole inclinations of 50-55° which provides for reasonable sampling of lodes with flat to sub-vertical dips (assuming drillingdirection has opposed the dip of mineralisation).
		The orientation of mineralisation is poorly understood at this stage so the true effectiveness of sampling by drilling is not known.
	If the relationship between the drilling	Tankoro and Bondi Deposits
	orientation and the orientation of key	Drilling orientations are not considered to have introduced any sampling bias.
	mineralised structures is considered to haveintroduced a sampling bias, this should be	Regional Project Drilling
	assessed and reported if material.	The presence or degree of any sampling bias is not known at this stage.
		Drilling to date is generallyexploratory in nature and does not support a detailed understanding of the geological setting nor the mineralisation presentat the Project and as such, the relationship of downhole intersection length to true width of the mineralisation is unable tobe determined.
SampleSecurity	The measures taken to ensure samplesecurity.	Sarama -For the works completed by Sarama, samples are collected and placed into specially numbered bags prepared for the programs. This isperformed in the presence of Sarama's field geologists with inventory details recorded for each sample.
		•For soil geochemistry and surface prospecting, samples are generally placed into sealed and tagged bags directly at the site of collection.•For reconnaissance AC drilling, sub-samples are prepared at the drill site and placed into sealed and tagged bags.•For higher-level AC and RC drilling, samples are bagged securely at the drill site and transported to preparation facilities by Sarama field personnel.Once at the preparation facility, Sarama personnel remove the samples from the bags, place them into drying trays/tubs with tags inserted for thesample numbers and after subsequent riffle-splitting, the sub-sample is placed into sealed and tagged bags.•Once the samples are finally bagged, they are transported to analytical labs in Burkina Faso in large batches with full details (sample number, batchnumber, sub-sample weight) recorded by Sarama personnel.•Once at the analytical laboratories, the samples are sequentially unbagged, weighed and recorded with comparisons to submission details madeby Sarama personnel.
		All aspects of the sample collection and riffle splitting of the assay sub-sample (in the case of in the case of RAB, AC and RC drilling) were conducted bypersonnelunder the supervision of Sarama's geologists
		Orezone – RC and DC drilling:
		•RC samples and the drill core retrieved by the drillers was collected and handled at the drill site by Orezone personnel. Thesamples weretransported to the storage area in Djarkadougou, split and sent to the Orezone warehouse (enclosed building) in Ouagadougou. The storage areawas fenced, and security was provided on a permanent basis by a watchman.•The samples were checked and sent to the preparation facilities in Ouagadougou and then returned to Orezone's warehouse after samplepreparation was completed. The assay sub-samples were dispatched to the analytical laboratories.

		•The samples were continually under the direct control of Orezone, who monitored the preparation and shipment of the samples.
		Other Operators -Sarama is unaware of how previous operators ensured sample security for works completed prior to Sarama's acquisition of theproperties.
Audits or	The results of any audits or reviews of	Regional Exploration
Reviews	sampling techniques and data.	Sarama's sampling techniques in regional areas of the at the Project reflect those employed for its work at the Tankoro Deposit, for which audits havebeen undertaken as below.
		The work undertaken by Orezone on the Djarkadougou 2 Property, as the next most substantial work on the Project, broadly mirror that for the BondiDeposit for which audits and reviews have been undertaken as below.
		Tankoro Deposit
		Cube Consulting assessed the veracity of the drilling data during site visits in 2011 and 2012 which involved the following:
		•independent sampling and logging;•field inspection of the drilling in progress; and•confirmation of drillholes, geological outcrops, artisanal workings and mineralisation style.
		Based on these site visits and QAQC reviews conducted as part of Mineral Resource estimates conducted in 2013, 2016, 2020 and 2021, Cube concludedthat all logging, sampling and data QAQC procedures implemented by Sarama from 2011 to 2019 were undertaken to a high industry standard. Therecord keeping and data management was considered adequate for an advanced exploration project.
		SRK Consulting (2018) reviewed the data collection methodologies during a site visit and undertook an extensive review of theassay and geologicaldatabase. SRK concluded that the assay data provided was of sufficiently high quality and had been subjected to a sufficiently high level of checking tosupport a Mineral Resource estimate.
		For the drilling reported in this disclosure, no audits or reviews were undertaken apart from routine QAQC checking.
		Bondi Deposit
		During Orezone's operatorship of the Djarkadougou 2 Property (hosting the Bondi Deposit), Met-Chem undertook a site visit in 2007 and an audit ofthe databases, the logging and sampling procedures, QAQC program and a visit to the three laboratories in Ouagadougou. Conclusions from the auditincluded the following relevant points:
		•the performance of the blanks and standards was variable, and they could not be used to monitor accuracy of the laboratories;•duplicate assay results verified by Met-Chem suggested a moderate repeatability, particularly for the range of values above 15 ppb Au;•no systematic bias was detected in the underlying assay data;•a more aggressive leach extractable assay method (Leachwell) was recommended to counter the incomplete leaching of the gold when using BLEGwhich may have caused a negative bias in the head assays;•the homogeneity of the in-house standard and blank materials needed improvement;•the source of the poorblank performance needed to be determined and addressed;•the origin of the variability between the original and duplicate sample analytical results needed to be determined and controlled if possible; and•Met-Chem believed the field data, the geological interpretation and the parameters used for the resource estimate were collected, handled andinterpreted by experienced people and fairly reflected the geological and gold grade continuity of the main deposits.
		In 2021, as part of an updated Mineral Resourceestimate for the Bondi Deposit, Sarama undertook a retrospective review of the drillhole database,with particular focus on analytical performance for drilling informing the Bondi Deposit. The review concluded that the goldassays for the depositgenerated during Orezone's operatorship have low confidence. This results from the generation of gold assays from bulk cyanidation of samples(without leach tail fire assay) for which gold dissolution ranged 60-90%. This issue has produced a negative bias in gold values in the assay databaseand erodes the effectiveness of QAQC monitoring. The QAQC system implemented was found to be ineffective in externally monitoring analytical lab

performance and sample preparation activities, resulting from the use of in-house prepared reference materials which appear to be highly variable in gold grade. The review determined that the field practices that Orezone employed for sample collection and sub-sampling were probably of a reasonable standard, however this couldn't be assessed definitively because of the above issues.

Section 2 Reporting of Exploration Results

(Criteria listed in the preceding section also apply to this section.)

Criteria	JORC Code Explanation	Commentary
MineralTenement andLand TenureStatus	Type, reference name/number, locationand ownership including agreements ormaterial issues with third parties such as	The Sanutura Project (the "Project") is comprised of 11 exploration properties for which Exploration Permits have been issued by the Government ofBurkina Faso:
	joint ventures, partnerships, overridingArrêté 2020-275/MMC/SG/DGCM)royalties, native title interests, historical•Bini –sites, wilderness or national park and•Botoro -N/A, pending issuance of new arrêtéenvironmental settings.•Danymi 2 -•Djarkadougou 2 -Arrêté 2023-028/MEMC/SG/DGCM•Gbingue 2 -Arrêté 2021-229/MEMC/SG/DGCM•Nakar -•Ouangoro 2 -N/A, pending issuance of new arrêté•Tankoro 2 -N/A, pending issuance of new arrêté•Tyikoro -	•Bamako 2 -N/A, pending issuance of new arrêtéfor renewed Exploration Permit (previously Arrêté 2019-180/MMC/SG/DGCM, as amended byN/A, pending acceptance of application for re-issued Exploration Permit (previously Arrêté 2020-063/MMC/SG/DGCM)for renewed Exploration Permit (previously Arrêté 2018-209/MMC/SG/DGCM)N/A, pending issuance of new arrêté re-issued Exploration Permit (previously Arrêté 2019-132/MMC/SG/DGCM)N/A, pending issuance of new arrêté for renewed Exploration Permit (previously Arrêté 2019-126/MMC/SG/DGCM)for renewed Exploration Permit (previously Arrêté 2020-300/MMC/SG/DGCMfor re-issued Exploration Permit (previously Arrêté 2019-150/MMC/SG/DGCM)N/A, pending acceptance of application for re-issued Exploration Permit (previously Arrêté 2020-149/MMC/SG/DGCM)•Werinkera 2 -N/A, pending issuance of new arrêtéforre-issued Exploration Permit (previously Arrêté 2019-133/MMC/SG/DGCM)
		An Exploration Permit has a term of 3-years and, subject to the holder of the Exploration Permit satisfying certain reporting and expenditurerequirements, it can be renewed for a further 2 terms, each of 3-year duration. At the end of the second renewal, the regular tenure regime expires,but the holder of an Exploration Permit may apply for an Exceptional Extension for the Exploration Permit. If granted, this extension provides for asingle 3-year term which cannot be renewed or extended. At the end of the regular tenure regime or the Exceptional Extension tenure period, theholder of an Exploration Permit may apply for the issuance of a new Exploration Permit.
		Sarama indirectly holds a 100% interest in all of properties constituting the Project.
		The Bini, Danymi 2, Gbingue 2, Ouangoro 2, Tankoro 2, Tyikoro and Werinkera2 Properties (collectively, the "South Houndé Properties") were subjectto an earn in agreement, entered into by Sarama and Acacia Mining plc ("Acacia") in November 2014. The parties terminated this earn-in agreementon 14 May 2019 with subsequent amendments being executed by Sarama and Barrick TZ Limited ("Barrick TZ", the successor company of Acacia) on15 November 2019, 19 June 2020 and 18 November 2021.
		Under the final amended agreement, Sarama retains a 100% interest in the South Houndé Properties and Barrick TZ is entitled to the following propertyrelated payments:
		•commercial production-based payments consisting of:
		o US$1M on production of 10,000 oz gold;o US$1M on production of a further 5,000 oz gold; and
		•royalty payments, capped at gold production of 1Moz Au, according to sliding-scale royalty rates of:
		o 1.0% for gold price ≤US$1300/ozo 1.5% for gold prices >US$1300/oz and ≤US$1500/oz, ando 2.0% for gold prices >US$1500/oz.

	On 1 September 2022, Maverix Metals Inc("Maverix"), a gold-focussedroyalty and streaming company, announced that it had entered into anagreement with Barrick TZ to purchase the above royalties in respect of the South Houndé Properties. The transaction wassubject to certaincompletion conditions. Maverix was subsequently acquired by Triple Flag Precious Metals Corp on 19 January 2023 under a Plan of Arrangement.
	The Bondi Deposit lies within the Djarkadougou 2 Property, with exploration rights granted via the issuance of the Djarkadougou 2 Exploration Permit(the "Djarkadougou 2 Permit" and formerly the "Djarkadougou Permit") which was originally granted to Orezone Inc (Burkina Faso) ("OrezoneBurkina"). On 22 August 2017, Sarama completed an agreement (the "Djarkadougou Agreement") with Orezone Gold Corporation (Canada)("Orezone"), giving Sarama the right to acquire a 100% interest in the Djarkadougou 2 Property subject to payment of certain commercial conditionsbeing satisfied. All conditions precedent was either satisfied or waived by the parties and the Djarkadougou Permit was transferred to SWA SARL (awholly owned subsidiary of Sarama) on 18 August 2017. Pursuant to the agreement with Orezone, the property holder has the obligation to makeroyalty payments to Orezone of US$20/oz sold from the property, up to a maximum of 200,000 ounces.
	Several areas of significance for conservation and/or preservation exist in the region of the Project. The highest-ranking protected areas are the ForêtClassée des Deux Balés("Deux Balés Classified Forests"), which has been informally recognised as a National Park since 1967 and the Reserve Totalede Faune de Bontioli("Bontioli Full Fauna Reserve"). These areas are located approximately 150km north-east and 75km east of the Project's centroid.
	At a local scale, the Project is positioned amongst lower-level areas of conversation and preservation; namely Reserve Partielle de Faune(Partial FaunaReserves) and Forêts Classés(Classified Forests).
	Property) is located in the Reserve Partielle de Faune de NabéréThe majority of the Bondi Deposit (hosted by the Djarkadougou 2(the "Nabéré PartialReserve"). The area is designated as IUCN Category IV, which is defined as a protected area managed mainly for conservation through managementintervention. Such an areaof land and/or sea is subject to active intervention for management purposes toensure the maintenance of habitats and/orto meet the requirements of specific species. Whilst being a protected area, the local environment has been significantly degraded byartisanal miningactivity on the Bondi Deposit and an associated village. Sarama has had discussions with the Ministry of Energy Transition, Mines and Quarries and theMinistry of Environment in respect of its activities on the Djarkadougou 2 Property theinteraction with the Nabéré Partial Reserve and strategies tomanage the impact of Sarama's proposed exploration activities on the local environment. There is potential for certain special conditions regardingSarama's exploration activities in the Nabéré Partial Reserve to be specified in the new arrete, for which Sarama awaits, by the Ministry of EnergyTransition, Mines and Quarries.
	The Project is subject to legislated NSR royalty payments to the Government of Burkina Faso for gold production sourced from the Project (sliding scale:<us$1000 3%;="" oz="">US$1000/oz and <$1300/oz 4%; and >US$1500/oz 5%). There is also a contribution payable to local community development funds,calculated at 1% and applied on the same basis as the NSR royalty.</us$1000>
	No other commercial, environmental or social encumbrances are known to impact the Project.
The security of the tenure held at the timeof reporting along with any knownimpediments to obtaining a licence tooperate in the area	Status of Project Exploration Permits as follows:•Bamako 2 -granted, currently in 2ndterm of 3terms -current term expiring 13 October 2025 (pending issuance of new arrêtéfor renewal);•Bini -expired, 3rd term of 3-terms expired 6 May 2022 (waiting for permit re-issue application to be accepted);•Botoro -granted, currently in 3rd term of 3terms -current term expiring 14 January 2024 (pending issuance of new arrêtéfor renewal);•Danymi 2 -granted, currently in 1st term of 3terms -current term expiring 16 July 2024 (pending issuance of new arrêtéfor re-issue);•Djarkadougou 2 -granted, currently in 1st term of 3terms -current term expiring 5January2026;•Gbingue 2 -granted, currently in 1st term of 3terms -current term expiring 13 September 2024;•Nakar-granted, currently in 2nd term of 3terms -current term expiring 20 June 2025 (pending issuance of new arrêtéfor renewal);•Ouangoro 2 -granted, currently in 2ndterm of 3terms-current term expiring 17 February 2026 (pending issuance of new arrêté for renewal);•Tankoro 2 -granted, currently in 1st term of 3terms -current term expiring 15 December 2024 (pending issuance of new arrêtéfor re-issue);

• Tyikoro – expired, 3rd term of 3 terms expired 20 June 2022 (waiting for permit re-issue application to be accepted); and

• Werinkera 2 - previous permit term expired, renewal application assessed favourably but administrative corrections required before issue of arrêté (will be 1st term of 3 terms assuming successful grant).

		No other permits orauthorisations are required to be issued to undertake exploration works on the Project.
ExplorationDone by OtherParties	Acknowledgment and appraisal ofexploration by other parties.	Prior to Sarama's involvement, minimal exploration work was conducted on the Project as a whole. Regional mapping and geophysical surveys(Marcelin 1971, SYSMIN 2003) were conducted over much of the country as part of government-sponsored programs aimed at fostering the extractiveresource industry.
		Minor and early-stage prospecting and soil geochemistry programs were subsequently conducted on select properties within the Project by operatorsother than Sarama (Werinkera Property -Orbis Gold Limited, 2010-2011 and Ouangoro 2 Property –Goldrush Resources Limited, 2006-2007). Theresults of these exploration programs are not known, and these operators relinquished their interests in the properties.
		A small RC reconnaissance drilling program was conducted on the Botoro Property by Birim Goldfields in 2007, following targetgeneration works. Thedrilling identified several prospect areas that warrant follow-up as part of a structured exploration program for the whole Project.
		The most significant body of work undertaken by other operators was the multi-phased exploration programs on the Djarkadougou 2 Property(Orezone, 1998-2016). Over this period, Orezone completed several phases of prospecting, soil geochemistry, airborne and ground-based geophysicalsurveys, targeted mechanised auger sampling, trenching and various campaigns of AC, RC and DC drilling.
		A resource estimate was completed by Orezone on the Bondi Deposit (Djarkadougou2 Property) in 2005 and updated in 2009. These estimates wereundertaken in accordance with Canadian National Instrument NI 43-101 ("NI 43-101").
Geology	Deposit type, geological setting and style ofmineralization.	The Sanutura Projectis located in thenorth trending Houndé and Boromo greenstone belts which extend for over 400km. Lower Proterozoic Birimianvolcano-sedimentary and plutonic rock are intruded by large batholiths of Eburnean granitoids. The elongated volcano-sedimentary belts trend northtonorth-east and form arcuate belts to the north of Ouagadougou.
		The Houndé and Boromo belts host several important regional structures such as the Houndé-Ouahigouya tectonic zone (Houndé Belt) and the BatieWest shear zone (southern Boromo Belt). Major gold deposits have been found along the regional structures while important gold prospects have beenfound along second and third order structures that splay from these main breaks.
		Two main gold deposits have been discovered within the Project to date; namely, then Tankoro and Bondi Deposits. Outside of these areas, the stylesof gold mineralisation are not well understood given the limited exploration work undertaken to date. It is likely that as aminimum, gold mineralisationis present in the form of gold-quartz veins and stockwork systems which are being exploited by artisanal miners presently. There is potential forintrusive-related and shear-hosted gold mineralisation styles of mineralisation as is observed in other similar belts in SW Burkina Faso.
		Tankoro Deposit
		A north to north-east (NE) trending, regional-scale fault is interpreted to traverse through the central part of Tankoro with a series of district scale,north trending faults are also interpreted from the orientation of quartz veins and breccia zones.
		The gold mineralisation at Tankoro occurs along a semi-continuous 16km strike length within the north north-east striking (025°TN) sub-verticalTankoro Structural Corridor which is up to 1.4km wide. The system has been interpreted as a seriesof sub-parallel anastomosing shear zones, whichacted as zones of weakness for the emplacement of porphyry bodies and as pathways for mineralising fluids. The strike-slip fault zones have developedmultiple splays and releasing bends or jogs, generating preferential sites for mineralisation.
		The main porphyry zones have developed as linear and continuous bodies, varying from 100m and up to 1.3km in strike length. Well-developed goldmineralisation is preferentially located either in porphyry intrusions orcoarse-grained sandstones with high intensity sericite-carbonate floodingalteration and overprinted by albite alteration in the vicinity of quartz-albite-sulphide veinlets, but rarely within fine grained mudstones.
		The highest-grade zones contain quartz-pyrite-stibnite or quartz-pyrite-tetrahedrite and are localised where NE-striking cataclastic faults haveintersected the porphyry intrusions.
		The proportion of vein material is low at between 5-10% by volume and veinlets are commonly in the order of millimetres to 0.5m thick. Gold is typicallyfinely disseminated within the host rocks and has a good correlation with the presence of pyrite and arsenopyrite.

		Arsenopyrite displays a strong host-rock control with a preferential development in sedimentary wall rocks in the periphery of some mineralisedintrusions. The disseminated arsenopyrite defines a wider halo of alteration than the narrow nuggety high grade gold mineralisation.
		The weathering profile in Burkina Faso is generally deep and has developed to depths ranging from 50m to 90m over Tankoro.
		Bondi Deposit
		The Bondi Deposit is located in the central portion of the Djarkadougou 2 Property which overlies an assemblage of basalt flows, minor rhyolite andsedimentary rocks intruded by various felsic to mafic rocks. It is cut by the regionally significant Houndé-Ouahigouya Shear Zone, which is intimatelyassociated with most of the major gold deposits discovered in the western region of Burkina Faso.
		The bulk of the mineralisation is contained in several lenses associated with the main sub-vertical N-NNE shear zone system and with second-ordershear splays. The lenses are linearly contiguous but separated by gaps corresponding to weakly or unmineralised portions of the shears. Themineralization lies in a 6km shear zone cutting the contact between the Tarkwa sedimentary trough to the west and north with the eastern volcanicdomain to the south and east.
		Gold mineralization is associated with multi-stage emplacement of quartz-pyrite veinlets into sheared arenite-argillite, mafic dykes and quartz-feldsparporphyry. The mineralization is characterized by alteration that manifests itself by silica, sericite, carbonate and hematite, finely disseminated pyritewith subordinate arsenopyrite and chalcopyrite.
		The weathering profile has developed to a depth of approximately 30m at Bondi.
Drill HoleInformation	A summary of all information material tothe understanding of the ExplorationResults including a tabulation of thefollowing information for all Material drillholes: easting and northing of the drill hole,collar elevation or RL (Reduced Level –elevation above sea level in metres) of thedrill hole, collar dip and azimuth of the holedown, hole length and interception holelength.	The following physicals represent the aggregated drilling undertaken on the Project by Sarama and other operators, including areas of the MineralResource and regional explorationto 31 December 2021:•330 RAB drillholes (14,127m, average length 43m);•2,848 AC drillholes (143,619m, average length 50m);•1,843 RC drillholes (157,058m, average length 85m); and
		•56,000m diamond drilling (consisting of diamond tails drilled from RC pre-collars and 161 full length diamond drillholes).
		During 2022 and prior to this disclosure, 103AC holes (5,372m, average length 452m) 20RC holes (1,512m, average length 76m) were reported.
		An additional 35AC holes (1,984m, average length 51m) and 4RC holes (208m, average length 52m) are reported in this disclosure. Details of theseholes are included in Appendix A of this disclosure.
		The following drillhole physicals (included in the above) were used directly in the modelling of the mineral inventory for the Tankoro Deposit. TheMineral Resource estimate used only DC, RC and AC drilling data. The drilling was completed in several phases by Sarama and Acacia between 7th June2011 and 6th July 2019.
		•600 AC drillholes (34,216m)•568 RC drillholes (60,546m)•75 full length diamond drillholes (21,296m), and•103 diamond drillhole tails (15,411m) that were extensions to previously drilled RC holes.
		The following drillhole physicals (included in the above) were used directly in the modelling of the mineral inventory for the Bondi Deposit. The MineralResource estimate used only DC, RC and AC drilling data. The drilling was completed in several phases by Orezone and Sarama between January 2003–February 2016 and July 2017 –July 2018 respectively.
		•14 AC drillholes (531m);•689 RC drillholes (49,021m); and•86 full length diamond drillholes (17,503m).

	If the exclusion of this information isjustified on the basis that the information isnot Material and this exclusion does notdetract from the understanding of thereport, the Competent Person shouldclearly explain why this is the case.	For holes reported in this disclosure, atabulation of all Material drill holes has been providedin Appendix A to this disclosure.Outside of this disclosure as all relevant drilling has been incorporated into the Mineral Resource. Thisexclusion is not considered Material nor doesit detract from the understanding of the Mineral Resource estimate or Exploration Results that arebeing reported.
DataAggregationMethods	In reporting Exploration Results, weightingaveraging techniques, maximum and/orminimum grade truncations (eg cutting ofhigh grades) and cut-off grades are usuallyMaterial and should be stated.	For holes reported in this disclosure, significant intersections are reported using a length-weighted downhole composite of raw assay grades.Composite intervals are selected using a minimum of 2 adjacent samples at a minimum grade of 0.30g/t Au with inclusion of internal sub-grade intervalsof a maximum 2m downhole length.
	Where aggregate intercepts incorporateshort lengths of high-grade results andlonger lengths of low-grade results, theprocedure used for such aggregationshould be stated and some typicalexamples of such aggregations should beshown in detail.	Details are outlined above. Where areported composite interval contains an anomalously higher-grade interval, the sub-interval is reported. Theprocedure for selection of the sub-interval is based on manual review of the listing of assays and subjective determination that the sub-intervalshouldbe reported separately.
	The assumptions used for any reporting ofmetal equivalent values should be clearlystated.	No metal equivalent values are being reported.
RelationshipBetweenMineralization	These relationships are particularlyimportant in the reporting of ExplorationResults.	The mineralisation can occur in multiple orientations with splays and cross-cutting structures developed along the length of the mineralised corridors.In general, holes are targeted to intersect mineralised structures/bodies perpendicular to their expected strike and as close as practically possible tothe perpendicular direction of their expected dip.
Widths and	If the geometry of the mineralization withrespect to the drill hole angle is known, itsnature should be reported.	Regional Exploration
InterceptLengths		The mineralisation in some areasof the Project is likely to occur in multiple orientations with splays and cross-cutting structures developed along thelength of the mineralised trend. The drilling orientations are a compromise to target all possible mineralisation orientations.
	If it is not known and only the down holelengths are reported, there should be aclear statement to this effect (eg 'downhole length, true width not known').	Given the early-stage nature of the Project area and the poorly understood spatial aspects of the mineralisation intersected, the relationship ofdownhole intersections to true width of the mineralisation cannot be determined.
		Tankoro Deposit
		The drilling orientation is a compromise to target all possible mineralisation orientations and downhole intercepts of the steep sub-vertical structureswill have a downhole length longer than the true width. The E-W orientated drill lines are slightly oblique to the orientation of the dominant main NNEsub-vertical mineralised trend and will also have marginally longer down hole lengths than the true width. In general, holes fully intersect themineralised zones and inclusion within the estimation process will negate any downhole length bias.
		Bondi Deposit
		Angled holes were drilled perpendicular to the strike of the sub-vertical mineralisation zone. Downhole intercepts of the drilling that are at an obliqueangle to the mineralisation will have a downhole length longer thanthe true width which is unknown at this stage. In general, holes fully intersect themineralised zones and inclusion within the estimation process will negate any downhole length bias.

		For the new drilling reported in this disclosure, the drillholes have been oriented at varying dips and azimuths to intersect the projected targets asclose as possible to 90°. The orientation of some of the mineralisationintersected is not well understood so determination or estimation of true widthis not possiblein all cases.
Diagrams	Appropriate maps and sections (withscales) and tabulations of intercepts shouldbe included for any significant discoverybeing reported These should include, butnot be limited to a plan view of drill holecollar locations and appropriate sectionalviews.	Drillhole location plans, where relevant, are included within the disclosure.
BalancedReporting	Where comprehensive reporting of allExploration Results is not practicable,representative reporting of both low andhigh grades and/or widths should bepracticed to avoid misleading reporting ofExploration Results.	For the holes reported in this disclosure, a full tabulation of results (both significant and not significant) is included in Appendix A to this disclosure.
Other	Other exploration data, if meaningful and	Regional Exploration
SubstantiveExplorationData	material, should be reported including (butnot limited to): geological observations;geophysical survey results; geochemicalsurvey results; bulk samples –size andmethod of treatment; metallurgical testresults; bulk density, groundwater,geotechnical and rock characteristics;potential deleterious or contaminatingsubstances.	Soil geochemistry surveys have been undertaken where first pass samples were collected on a broadly spaced grids which either cover the full propertyarea or selected portions. These are followed up with similarly spaced expanded grids or by infill sampling where increased resolution was required.Defined soil anomalies are followed up using scout RAB and AC drilling.
		A country-scale, airborne radiometric and magnetic geophysical survey was undertaken in 2003 on behalf of the Government of Burkina Faso. In theregion of the Project, this survey facilitated the interpretation of Project and property-scale lithological units, structural features and topographicalfeatures which culminated in the production of regional geology maps.
		Tankoro Deposit
		•Geophysical Surveys -to better define the geological and structural setting of gold mineralization discovered in key areas of the Project, thefollowing geophysical surveys were completed:
		o high-resolution airborne magnetic-radiometric survey was acquired by New Resolution Geophysics, in March 2015, over the whole of the Projectarea (818.6 km²) with a flight line spacing of 100m in a 120-300 degrees flight line direction and a mean terrain clearance of 45m; ando high-resolution gradient array resistivity ("RES") and inducedpolarization ("IP") survey was undertaken in selected locations of the Project.
		The surveys proved to be effective in mapping shallow resistive and chargeable zones with geological and structural features clearly defined. Theinterpretation proposes a series of north to north-east trending, narrow elongated units. Faults and shears were inferred from breaks and bendsalong the resistive and/or chargeable units. The important observations from the RES/IP survey have been integrated with existing geologicalinformation to build a solid lithological and structural picture.
		•Metallurgical Testwork -considerable metallurgical testwork over successive phases have been undertaken on the mineralisation in the area ofthe Mineral Resource and on outlying prospect areas. The testwork programs were conducted by various specialist laboratories under thesupervision of Orway (comminution, direct cyanidation, flotation and oxidative flowsheets), Kappes (heap leach flowsheets), and Sarama (bottleroll type direct cyanidation for initial characterisation) to determine indicative recoveries and understand the metallurgical behaviour of the variousstyle and weathering states of mineralisation within the deposit. The testwork is regarded as preliminary and as such, parameters and flowsheetsare un-optimised.
		•Density Measurements were taken from diamond drill samples selected across a range of rock types and weathering profiles using a water

		immersion technique.
		Bondi Deposit
		•Geophysical Surveys -to better define the geological and structural setting of gold mineralization discovered in key areas of the Project, thefollowing geophysical surveys were completed:
		o IP gradient survey, 50km over 100 by 50 m grid; ando High-resolution resistivity survey, 38km over 50 by 10 m grid.
		•Density Measurements were taken from diamond drill samples selected across a range of rock types and weathering profiles using a waterimmersion technique. Specific gravity determination: 5 pits excavated to calculate bulk density.•Metallurgical Testwork -considerable metallurgical test work over successive phases has been undertaken on the mineralisation in the area ofthe Mineral Resource. The testwork programs were conducted by various specialist laboratories under the supervision of Orezone and includedcomminution, direct cyanidation, flotation work to determine indicative recoveries and understand the metallurgical behaviourof the variousstyles and weathering states of mineralisation within the deposit. The testwork is regarded as preliminary and assuch, parameters and flowsheetsare un-optimised.
Further Work	The nature and scale of planned furtherwork (egtests for lateral extensions ordepth extensions or large-scale step-outdrilling).	Regional Exploration
		In regional areas outside the Tankoro and Bondi Deposits, the Project remains at an early stage of exploration and planned activities are broadlydirected towards determining the prospectivity of the Project and seek to generate and test targets for gold mineralisation of economic interest. Theactivities include:
	Diagrams clearly highlighting the areas ofpossible extensions, including the maingeological interpretations and futuredrilling areas, provided this information isnot commercially sensitive.	•broad-scale surface prospecting and mapping is planned over the Project area;•geological mapping and traversing of the identified soil anomalies for all property areas to prioritise the geochemical targets and to enable theexploration effort to focus on the most prospective areas that have geological features consistent with the exploration model;•ground-based geophysical surveys are contemplated for select priority areas in the Project area.;•AC and/or RC drilling is contemplated for reconnaissance type testing of targets generated by gold-in-soil geochemistry surveys and structuralgeology assessment;
		Tankoro Deposit
		Significant work has been conducted at the Tankoro Deposit to date and the following works are broadly aimed at improving the confidence level ofthe Mineral Resource, expanding the Mineral Resource base, improving knowledge of metallurgical behaviour of the mineralisation
		•undertake drilling for extensional and additional targets to expand the Mineral Resource base;•undertake confirmatory (twin) drilling in certain areas to examine volume variance effects (AC vs RC);•undertake analytical tests to examine the volume variance effect of bulk cyanidation vs fire assay methods;•undertake metallurgical testwork to improve the geo-metallurgical understanding of the deposit; and•undertake mineralogical testwork to gain an understanding of variability in metallurgical performance and in particular, the reasons for free-millingmaterial in certain fresh areas of the deposit.
		Bondi Deposit
		Significant work has been conducted at the Bondi Deposit to date and the following works are broadly aimed at improving the confidence level of theMineral Resource, expanding the Mineral Resource base, improving knowledge of metallurgical behaviour of the mineralisation:
		•reclassification of a problematic assays in the historical drillhole database;•re-assaying of historical drilling where appropriate and possible;•re-logging historical drilling where appropriate and possible;

• undertaking confirmatory drilling in areas of high geological risk;
• undertaking re-drilling of the Mineral Resource where assay quality is poor and existing data does not support higher-order estimates;
• conducting extensional exploration drilling where appropriate;
• improving the estimate of artisanal mining depletion by higher-order surveying; and
• expanded metallurgical testwork to better understand potential variability of the deposit.