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jj Our AI - Driven Bioinformatics Platform is Expected to Accelerate the Development of a Novel NASH Therapeutic and Create Pathways to Optimize Efficacy Filed pursuant to Rule 433 of the Securities Act of 1933 Issuer Free Writing Prospectus dated November 12, 2020 Relating to the Preliminary Prospectus dated November 12, 2020 Registration Statement File No. 333 - 249724 HEPA

   

 

Forward - Looking Statements This presentation may contain forward - looking statements within the meaning of Section 27 A of the Securities Act of 1933 and Section 21 E of the Securities Exchange Act of 1934 . Such forward - looking statements are characterized by future or conditional verbs such as “may,” “will,” “expect,” “intend,” “anticipate,” “believe,” “estimate” and “continue” or similar words . You should read statements that contain these words carefully because they discuss future expectations and plans, which contain projections of future results of operations or financial condition or state other forward - looking information . Such statements are only predictions and our actual results may differ materially from those anticipated in these forward - looking statements . We believe that it is important to communicate future expectations to investors . However, there may be events in the future that we are not able to accurately predict or control . Factors that may cause such differences include, but are not limited to, those discussed under Risk Factors in our periodic reports and our Registration Statement filed with the Securities and Exchange Commission, including the uncertainties associated with product development, the risk that products that appeared promising in early clinical trials do not demonstrate safety and efficacy in larger - scale clinical trials, the risk that AI - POWR ™ fails to help us discover and develop product candidates, the risk that we will not obtain approval to market our products, risks associated with delays, increased costs and funding shortages caused by the COVID - 19 pandemic ; the risks associated with dependence upon key personnel and the need for additional financing . We do not assume any obligation to update forward - looking statements as circumstances change . Free Writing Prospectus Hepion Pharmaceuticals, Inc . has filed a registration statement (including a preliminary prospectus) (the “Registration Statement”) with the Securities and Exchange Commission (the “SEC”) on Form S - 1 (SEC File No . 333 - 249724 ) for the offering to which this prospectus relates . This presentation highlights basic information about us and the proposed offering . Because it is a summary, it does not contain all of the information that you should consider before investing . The registration statement has not yet become effective . Before you invest, you should read the prospectus in the registration statement (including the risk factors described therein) and other documents we have filed with the SEC for more complete information about us and the offering . You may access these documents for free by visiting EDGAR on the SEC Web site at http : //www . sec . gov . Alternatively, we or any underwriter participating in the offering will arrange to send you the prospectus if you contact ThinkEquity , a division of Fordham Financial Management, Inc . , Prospectus Department, 17 State Street, 22 nd Floor, New York, New York 10004 , telephone : ( 877 ) 436 - 3673 or email : prospectus@think - equity . com . This presentation does not constitute an offer or invitation for the sale or purchase of securities or to engage in any other transaction with Hepion Pharmaceuticals or its affiliates . The information in this presentation is not targeted at the residents of any particular country or jurisdiction and is not intended for distribution to, or use by, any person in any jurisdiction or country where such distribution or use would be contrary to local law or regulation . p. 2

   

 

AI - driven bioinformatics has the potential to transform healthcare The net - net for biotechs like us is to create the ability to mitigate risk, shorten timelines, and reduce the costs of our trials while creating additional value for our platform. President, CEO Hepion Pharmaceuticals, Inc. ROBERT FOSTER, PharmD, PhD The cost to d evelop o ne New Drug is $2.6 Billion: the approval r ate for Drugs Entering clinical d evelopment is less t han 12% Tufts Center for the Study of Drug Development, 2019 FDA Rejects NASH Therapeutic, June 2020 Fails Phase 3 Trial, May 2020 p. 3

   

 

HIGHLIGHTS ▪ Clinical phase 2a NASH program currently underway ▪ Anticipated that Artificial Intelligence and Smart Algorithms Platform ( AI - POWR ™) will help to identify and optimize responder outcomes ▪ Strong safety/tolerability profile in preclinical and phase 1 clinical studies (n=73 healthy volunteers) ▪ Strong preclinical proof of concept in fibrosis and viral infections ▪ Orally active, once daily capsules ▪ Regulating protein folding cyclophilins (enzymes) to treat diseases including: - Fibrosis, viral infections, cancers, etc. ▪ 30 years experience in this very specific field of chemistry and drug development - Core team that founded Aurinia Pharmaceuticals (NASDAQ:AUPH), and discovered and developed voclosporin through Phase 2 ▪ Robust IP (protection in major markets including US, Europe, Australia, Canada, China, Japan, Korea) with exclusivity until 2039 with potential further regulatory exclusivity up to 2044 $17.6 M as of 6/30/20 CASH 9.0 M shares outstanding as of 6/30/20 13.0 M F/D Shares as of 6/30/20 * * Excludes 1,062,000 shares of common stock issuable upon exercise of outstanding options under our equity incentive plan as of September 30, 2020. Elemer Piros, Ph.D. – Roth Capital Kumar Raja, Ph.D. – Brookline Capital Nathaniel Calloway, Ph.D. – Edison Group SHARES COVERAGE p. 4 TWO VALUE DRIVERS A Therapy for NASH with indications for several other conditions AI - Driven, Bioinformatic Platform

   

 

PIPELINE p. 5 THERAPY PROGRAM PRE - CLINICAL Phase 1 * Phase 2 Phase 3 NDA SUBMISSION NASH CRV431 205 COVID - 19 CRV431 206 HBV Open to Partnerships IND 142904 pIND 151344 IND 1376787 * Separate Phase 1 programs were not conducted for each separate indication. The Phase 1 program was comprised of Single and Mu lti ple Ascending Doses, and a Drug - Drug Interaction study.

   

 

We Have Developed an AI - Driven Bioinformatics Platform Which is Expected to Accelerate Cost - Effective Clinical Trials Study Design to Increase Response Rates ABOUT US p. 6

   

 

p. 7 Bioinformatics ACCELERATES the Development of Our OWN THERAPIES and can be used as a PLATFORM Hepion’s AI - POWR™ platform provides integrative, multi - variate, systems - biology bioinformatic and big - data analysis of proprietary pre - clinical and clinical data with publicly - available multi - omic data bases and key clinical outcomes. Analytics provide for drug target selection, clinical study design enhancement and a priori - responder analysis. We believe that the AI outputs will provide us with the following benefits: AI P O W R Supervised and unsupervised AI - enabled machine learning Precision medicine based on genetics, environment, and lifestyle Omics, including genomics, proteomics, metabolomics and lipidomics World, accessing world genomic databases Response and clinical outcomes ▪ Novel Drug Target Selection (for pipeline drugs) ▪ Biomarker Selection and Validation ▪ Patient Selection ( a priori - responder analysis) ▪ De - Risk Clinical Trials ▪ Improve drug development efficiency with cost savings

   

 

Identifying Responders Increases “Signal - to - Noise” p. 8 Identify Responders from Big Data Sources using multi - omic approach (genomics, proteomics, metabolomics, lipidomics , patient traits) Supervised and Unsupervised Machine Learning Algorithms Model Inputs and Run Scenarios to Constantly Increase Response Rates AI - POWR™ Expected to Produce a Concentrated Set of Responders Which we Believe Will: ▪ Help to identify responders a priori ▪ Reduce need for post - hoc analysis ▪ Optimize spread between treatment and placebo

   

 

p. 9 ACCESSING DATA Inputs Are All Publicly Available, for everyone AI DATA - PROCESSING Is the Tough, and Proprietary part DEFENDING OUTCOMES Are the Ultimate Goals of Bioinformatic AI Platforms. Big Data Access We all have access to millions of studies, results and findings are now compiled for: x Disease State Specific Genomic x Proteomics, Genomics, Lipidomics , Metabolomics (‘Multi - Omics’) Data Bases x Patient Traits x Clinical Outcomes Data Mining Scripting Algorithms / AI Developing Big Data Processing Algorithms Supporting Predictions and Actions Continuous Learning Fine Tuning Algorithm Adjustment of Datasets / New Biomarkers Patient Selection Study Design Enrichment Demonstrate Improved Response Outcomes Through: Patient Selection Biomarker Selection Drug Target Selection Collect and Prepare Assessments for Trial Study Submission Clinical Success De - Risk Failure Improve Study Efficiencies Cost Savings Re - Analysis - Feedback Components AI - POWR ™

   

 

THE NET BENEFITS of AI - Driven, Bioinformatic Trials and Study Design p. 10 Novartis used AI to predict and monitor trial costs, enrollment and quality. As a result, the company reported a 10 - 15 % reduction in patient enrollment times in pilot trials . Healthcare Weekly, 2019. Increase Trial Success Rates Shorten Trial Timelines Decrease Costs Phase I - III selection and b iomarker verification reduce variability and increase study power which results in high levels of efficacy in clinical trial phases Modeling results, adjusting variables and honing scenario - based study designs shorten review times Shortening intervals between trials and decreasing the amount of time and effort and cost required to resubmit studies during trials Traditionally, most time and money are spent for trials which have the lowest efficacy rates. Patient targeting and recruitment accounts for approximately 32% of costs. Deloitte, 2019 The Pain Points in Traditional Clinical Trials Today – Long timelines, high costs and low response rates PHASE 1 PHASE 2 PHASE 3 Takes at least 3 - 6 months. Around 70% move to next phase Takes 1 - 2 years. Around 33% move to next phase. Takes 1 - 4 years. Around 25 - 30% move to next phase. Anticipated Benefits of AI - Enabled Bioinformatics in Trials and Study Design

   

 

a cyclophilin inhibitor in development using AI - POWR TM to produce anticipated market - leading efficacy rates to treat NASH JM1

   

 

THERAPY DISCOVERY PRE - CLINICAL Phase 1 Phase 2 Phase 3 NDA SUBMISSION Synthesized and screened ~200 molecules CRV431 for NASH p. 12 Projected NDA Filing 2025 Identified CRV431 as lead molecule Efficacy Models : 5 in vivo 5 in vitro fibroblast 2 human explants - liver and lung Toxicology In vitro and in vivo Pharmacology and MOA CMC Phase 2a 'AMBITION' Clinical Trial Ongoing Single and Multiple Ascending Dosing Completed Drug - Drug Interaction Study Completed

   

 

Theory Prediction and Experimentation Findings Modifying Cyclosporine A can greatly increase its immunosuppressive benefits Modifications of Cyclosporine A can either eliminate or enhance immunosuppression. Our team’s past discovery, voclosporin, was chemically modified to enhance immunosuppression Inhibition of each cyclophilin isoform produces distinct therapeutic effects THE GENESIS OF CRV431 Cyclosporine A N N H O OH O N N O O N N O O N N H OO N H N OO N H O N N H O OH O N N O O N N O O N N H OO N H N OO N H O NH O N N H O OH O N N O O N N O O N N H OO N H N OO N H O CH 2 Voclosporin Aurinia Pharma Nearly 40 years of clinical use as immunosuppressive drug for organ transplantation and autoimmune diseases Modifications increase affinity for calcineurin and increase immunosuppression potency Modifications increase affinity for cyclophilins (13 - fold) and eliminate immunosuppression CRV431 binds potently (Ki ≈ 1 nM ) to around 10 of 17 cyclophilin isoforms in the human body p. 13 CRV431 Cyclophilins shown to play negative roles in: Viral Hepatitis • Cancers • Acute And Chronic Lung Injury • Myocardial Infarction • Stroke • Arthritis • Atherosclerosis • T hro mbosis • Aortic Aneurysm • Coronary Artery Disease • Pulmonary Arterial Hypertension • ALS • Alzheimers Disease • Multiple Sclerosis • Muscular Dystrophies • Traumatic CNS Injury WHY TARGET CYCLOPHILINS

   

 

Patent Portfolio p. 14 Family 1 Composition of Matter 47 Issued Patents Family 2 CRV431 Formulation International PCT Application US Patent Application Nov 2019 Family 3 Treatment of Fibrotic Disease in Multiple Organs Family 4 Anti - Fibrotic and Anti - Cancer Activities US Provisional Patent Application Feb 2020 Family 5 AI - POWR: Biological Study Design and Results Analysis US Provisional Patent Application July 2020 US Trademark Application July 2020 US Provisional Patent Application Feb 2020 Family 6 CRV431 and COVID - 19 US Provisional Patent Application Oct 2020

   

 

p. 15 CRV431 MODE OF ACTION Cyclophilin enzymes regulate the structure and activity of many proteins throughout the body Cyclophilin A ( cytosol and secreted) Secreted from injured cells and acts as proinflammatory cytokine by binding to CD147. • Hijacked by viruses to assist in viral replication (e.g. SARS - CoV - 2) Cyclophilin B (endoplasmic reticulum ) Promotes fibrotic scarring by controlling collagen production Regulatory roles of cyclophilins in many disease pathways make them good candidates as drug targets Binds to Cyclophilin A to reduce inflammation Binds to Cyclophilin B to reduce fibrosis Binds to Cyclophilin D to mitigate mitochondrial damage CRV431 Pan - Cyclophilin Inhibitor Cyclophilin D (mitochondria) Promotes mitochondrial pore opening leading to mitochondrial and necrotic cell death Regulates mitochondrial metabolism

   

 

The Development of CRV431 Using AI - POWR™

   

 

Preclinical Antifibrotic Efficacy p. 17 FIBROSIS – a response to chronic injury – is a major cause of organ dysfunction and its reduction is the primary goal in the treatment of NASH Human Cell Cultures CRV431 Effects Hepatic stellate cells, fibroblasts (multiple organs) TGF β or endogenous stimulation ▼ fibrotic gene expression ▼ procollagen and fibronectin secretion Human Tissue Explants (Precision Cut Slice Cultures ) CRV431 Effects Liver explants (4 donors) TGF β +PDGF - BB or endogenous stimulation ▼ inflammatory/fibrotic gene expression ▼ inflammatory/fibrotic protein secretion ▼ tissue fibrosis IPF lung explants (1 donor) Endogenous stimulation Animal Models (8 independent studies) CRV431 Effects Mice (liver fibrosis) Western diet + carbon tetrachloride 82% ▼ fibrosis; ▼ weight gain Mice (liver fibrosis) High fat diet + streptozotocin (4 studies) 37 - 57% ▼ fibrosis; ▼ weight gain;50% ▼ liver tumors Mice (liver fibrosis) Carbon tetrachloride 44% ▼ fibrosis Mice (kidney fibrosis) Unilateral ureter obstruction 42% ▼ fibrosis Rats (liver fibrosis) Thioacetamide 48% ▼ fibrosis; prevented cirrhosis

   

 

p. 18 PHASE 1 STUDIES – Safety, tolerability and pharmacokinetics (PK) CRV431 in Healthy Subjects Single Ascending Dose (SAD) Multiple Ascending Dose (MAD) Drug - Drug Interaction (DDI) x N = 32 (24 CRV431; 8 Placebo). x Doses: 75 mg, 225 mg, 375mg, 525 mg (single doses) x Drug Exposure is in the range in which efficacy was demonstrated in pre - clinical models. x Pharmacokinetics are first order and support once daily dosing. x No SAE’s, Mild AE’s, No dose response in AE’s or changes in clinical labs. x No changes in vital signs or ECG. x N = 25 (All CRV431). x Doses: 75 mg, 150 mg, 225 mg, 300 mg, 375 mg QD x 28 Days. x Drug Exposure starting at 75 mg QD is in the range in which efficacy was demonstrated in pre - clinical models. x Pharmacokinetics are first order and support once daily dosing. x No SAE’s, Mild AE’s, No dose response in AE’s or changes in clinical labs. x No changes in vital signs or ECG. x Data supported initiation of Phase 2a NASH Trial x N= 18 x Single CRV431 Drug Interaction Study with tenofovir

   

 

p. 19 Example of AI - POWR ™ Utility with CRV431 in NASH/NAFLD Liver Slices AI - POWR ™ Rapid and Early Identification of Key NASH - Related Genes Altered by 3 - Days CRV431 ▪ NASH/NAFLD is heterogenous ▪ Genetic analysis of the effects of CRV431 on 28,278 genes, gene - variants, non - encoding microRNA and long RNA ▪ A study of genes and environmental interactions (epigenetics) may suggest specific genetic risk factors or specific genetic types of NASH. ▪ Decreased function of these genes is associated with NASH/NAFLD and fibrosis ▪ Bioinformatics will help guide clinical development of CRV431, and optimize for success Gene Implications for NASH (Down - regulation, loss - of - function, polymorphism) Fold Change p - value TM6SF2 Linked to NASH and fibrosis +4.2 0.0007 PNPLA3 Triacylglycerol hydrolysis: linked to NASH and fibrosis +1.6 0.046 ApoB Apolipoprotein of chylomicrons and LDL, ligand for LDL, linked to dyslipidemia, NASH and fibrosis +10.9 0.0001 MTTP Lipoprotein assembly: linked to NASH and fibrosis +5.5 0.0003 GCKR Linked to maturity - onset type 2 diabetes and NASH +2.7 0.0036 LPIN1 Mutations associated with metabolic syndrome: linked to NASH and fibrosis +1.9 0.01

   

 

p. 20 ONGOING PHASE 2a AI - POWERED PILOT STUDY ▪ Evaluate the safety and tolerability of once daily ( qd ) 75 mg and 225 mg dose of CRV431 in presumed nonalcoholic steatohepatitis (NASH) fibrosis stage 2 (F2)/fibrosis stage 3 (F3) patients compared to placebo control over 28 days of dosing ▪ Measure antifibrotic activity of CRV431 ▪ Produce exploratory antifibrotic biomarker data: collagen biomarkers, matrix metalloproteinases, lipidomics , and genomics: Multi - Omic /Trait Data for use in AI - POWR Algorithm F2/F3 NASH Patients (n=36) Cohort * Fibrosis Stage N Day 1 – 28, fasted oral dosing Day 29 - 42 A F2/F3 12 CRV431 75 mg Observation/Follow - up B 6 Placebo C F2/F3 12 CRV431 225 mg D 6 Placebo *randomized assignment; 2:1 – CRV431:placebo Multivariate multi - omics - trait AI - analysis to elucidate CRV431 activity biomarkers in F2/F3 NASH for Phase 2b Patient/Biomarker Selection ▪ Multi - center (10 Sites), single - blind, placebo - controlled study ▪ Univariate Endpoints: AST, Pro - C3, ELF Score, Fibroscan OBJECTIVES STUDY DESIGN

   

 

p. 21 PHASE 2b AI - POWR NASH REGISTRATION TRIAL OBJECTIVES: • Evaluate the efficacy of once daily ( qd ) 75 mg and 225 mg dose of CRV431 in biopsy proven NASH fibrosis stages F2 and F3 patients compared to placebo over 6 months of dosing. • Measure antifibrotic activity of CRV431 • Validate antifibrotic biomarker data: collagen biomarkers, matrix metalloproteinases , lipidomics , proteomics and genomics derived via AI - POWR Algorithm with clinical outcomes including a 1 - point reduction in biopsy F score. STUDY DESIGN: • Multi - Center (28 US Sites), triple - blind, placebo - controlled (2:1), study • Univariate Endpoints: AST, Pro - C3, ELF - Score, Fibroscan , biopsy histopathology • Multivariate Endpoints: AI - POWR Multi - Omics Biomarker Panel confirmation and validation • Enriched Design: Inclusion criteria includes AI - POWR Panel F2/F3 NASH Patients (n=300) Cohort * Fibrosis Stage N 6 Months 3 Month A F2/F3 100 CRV431 75 mg Observation/Follow - up B 50 Placebo C F2/F3 100 CRV431 225 mg D 50 Placebo *randomized assignment; 2:1 – CRV431:placebo Multivariate multi - omics - trait AI - analysis to update CRV431 activity biomarkers in F2/F3 NASH for Phase 3 Patient/Biomarker Selection

   

 

p. 22 ANTICIPATED EVENTS CRV431 ▪ Complete Ongoing Phase 2A NASH program (first dosing (75 mg) cohort completion expected Q4, 2020) ▪ Top line data for 75 mg cohort expected by end of Q4, 2020 ▪ Complete long - term animal toxicology (Q2, 2021) ▪ Continue to optimize and scale - up chemistry and manufacturing (ongoing) ▪ Complete Additional Clinical Drug - Drug Interaction Studies (Q2, 2021) ▪ Prepare for NASH Phase 2B (to start mid - 2021) using AI - POWR ™ (ongoing) AI - POWR ™ ▪ Continue to refine and extend AI - POWR ™ for NASH and possible other indications (e.g., COVID - 19) ▪ Continue to develop intellectual property (IP) for future CRV431 indications (e.g., additional fibrosis, viral disease) and business development strategies

   

 

p. 23 CAPITALIZATION TABLE PRE - OFFERING As of June 30, 2020 1 Aggregate liquidation value. The Series A Convertible Preferred is convertible into 3,184 shares of common stock. Each share of Series A Convertible Preferred is convertible into that number of shares of common stock determined by dividing $10 (the stated value of such shar e) by $268.80 . The Series A Convertible Preferred has no dividend rate. 2 Aggregate liquidation value. The Series C Convertible Preferred is convertible into 16,839 shares of common stock. Each share of Series C Convertible Preferred is convertible into that number of shares of common stock determined by dividing $1,000 (the stated value of such s har e) by $108.50. The Series C Convertible Preferred has no dividend rate. 3 As of September 30, 2020, 2,499,473 shares of our common stock are issuable upon exercise of outstanding options under our 2013 Eq uity Incentive Plan. Shares of Common Stock Outstanding 9,025,061 Series A Convertible Preferred Stock 1 $855,810 Series C Convertible Preferred Stock 2 $1,827,000 Warrants (WAEP $19.35) 2,536,566 Options (WAEP $7.76) 3 1,402,771

   

 

p. 24 SUMMARY HIGHLIGHTS ▪ CRV431: ▪ Safe and well - tolerated ▪ Is currently in Phase 2a (Pilot) NASH patient study, 75 mg dosing cohort with first read - out expected Q4, 2020 ▪ Expected to initiate Phase 2b in NASH patients, mid - year 2021 ▪ AI - POWR: ▪ Expected to continue to drive CRV431 progress in NASH and potentially in additional indications ▪ May be applied to identify novel/complementary collaborations/expansions ▪ Intellectual Property: ▪ Continue to pursue and expand as warranted ▪ Use of Proceeds: ▪ Fund our Research & Development activities and general corporate purposes

   

 

HEPA CONTACT US Robert T. Foster, PharmD, PhD Chief Executive Officer HEPION PHARMACEUTICALS INC. 399 Thornall Street, First Floor Edison, New Jersey, USA, 08837 Email: rfoster@hepionpharma.com p. 25 www.hepionpharma.com