As per recent estimates (reported in May 2022), more than 11.6 billion doses of COVID-19 vaccines have been administered across 184 countries; this value roughly translates to 20.9 million doses per day. Vaccines have enabled the prevention of more than 37 million deaths due to various disease indications, such as cholera, diphtheria, influenza, tetanus, whooping cough and measles, between 2000 to 2019. Given the rate at which the global population is growing and taking into consideration the prevalent (such as the COVID-19 pandemic) and anticipated future trends, the demand for vaccines is likely to increase significantly. According to experts, the global vaccines market is anticipated to generate revenues worth USD 100 billion by 2025. In this regard, significant strides have been made to develop safe and effective, next generation vaccine candidates, such as sub-unit vaccines, recombinant vaccines, conjugate vaccines and DNA vaccines. However, such vaccines employ purified non-living vaccine antigens (unlike their counterparts, live attenuated and inactivated vaccines) and are, most often, less immunogenic and require an additional aid to increase their immunogenicity against the target antigens. As a result, a variety of vaccine adjuvants (substances with the innate potential to augment an immune response), such as AS04 (Cervarix®), MF59 (Fluad®), AS01B (Shingrix®) and CpG 1018 (Heplisav-B®), have been discovered and are now available for the development of more effective and versatile vaccine formulations.
Presently, an increasing number of vaccines under development are incorporating vaccine adjuvants owing to various advantages offered by such agents, including improved adaptive response to a vaccine, guiding the type of adaptive response to produce the most effective forms of immunity for each specific pathogen and facilitation of the use of smaller doses of antigen. Further, majority of the adjuvants used in human vaccines enhance humoral immunity; however, several novel adjuvants in clinical or preclinical development are focused on enhancing specific types of T-cell responses to generate multifaceted immune responses required for complex indications, such as malaria and HIV-AIDS. Currently, more than 70 companies and academic / research institutes are engaged in the development of various types of vaccine adjuvants. It is worth highlighting that capital investments worth over USD 5.5 billion have been made by various private and public sector investors during the last five years to fund the product development activity in this domain. In addition, there have been several recently reported instances of collaborations between industry / academic stakeholders to advance the development of various vaccine adjuvants. Driven by the increasing demand for safe and effective vaccines, ongoing pace of innovation in this field and financial support from the investors, the vaccine adjuvants market is likely to witness substantial growth in the mid to long-term.
The ‘Vaccine Adjuvants Market - Distribution by Type of Vaccine Adjuvant (Aluminum Salts, Oil-based Emulsions, Bacterial Compounds, Lipids, Nucleic Acids and Others), Route of Administration (Intramuscular, Subcutaneous, Oral, Intravenous and Others), Target Therapeutic Area (Infectious Diseases, Oncological Disorders and Others) and Key Geographies (North America, Europe, Asia-Pacific, Latin America, MENA and RoW): Industry Trends and Global Forecasts, 2022-2035’ report features an extensive study of the current market landscape and future potential of the vaccine adjuvant market. The study features an in-depth analysis, highlighting the capabilities of vaccine adjuvant developers.
One of the key objectives of the report was to evaluate the current opportunity and future potential associated with the vaccine adjuvant market, over the coming 13 years. We have provided informed estimates
of the likely evolution of the market in the short to mid-term and long term, for the period 2022-2035. Our year-wise projections of the current and future opportunity have further been segmented based on relevant parameters, such as [A] type of vaccine adjuvant (aluminum salts, oil-based emulsions, bacterial compounds, lipids, nucleic acids, and others), [B] route of administration (intramuscular, subcutaneous, oral, intravenous, and others), [C] target therapeutic area (infectious diseases, oncological disorders, and others), and [D] key geographical regions (North America, Europe, Asia-Pacific, Latin America, MENA and rest of the world). To account for future uncertainties in the market and to add robustness to our model, we have provided three forecast scenarios, portraying the conservative, base and optimistic tracks of the market’s evolution.
The opinions and insights presented in the report were also influenced by discussions held with senior stakeholders in the industry.
Presently, an increasing number of vaccines under development are incorporating vaccine adjuvants owing to various advantages offered by such agents, including improved adaptive response to a vaccine, guiding the type of adaptive response to produce the most effective forms of immunity for each specific pathogen and facilitation of the use of smaller doses of antigen. Further, majority of the adjuvants used in human vaccines enhance humoral immunity; however, several novel adjuvants in clinical or preclinical development are focused on enhancing specific types of T-cell responses to generate multifaceted immune responses required for complex indications, such as malaria and HIV-AIDS. Currently, more than 70 companies and academic / research institutes are engaged in the development of various types of vaccine adjuvants. It is worth highlighting that capital investments worth over USD 5.5 billion have been made by various private and public sector investors during the last five years to fund the product development activity in this domain. In addition, there have been several recently reported instances of collaborations between industry / academic stakeholders to advance the development of various vaccine adjuvants. Driven by the increasing demand for safe and effective vaccines, ongoing pace of innovation in this field and financial support from the investors, the vaccine adjuvants market is likely to witness substantial growth in the mid to long-term.
Scope of the Report
The ‘Vaccine Adjuvants Market - Distribution by Type of Vaccine Adjuvant (Aluminum Salts, Oil-based Emulsions, Bacterial Compounds, Lipids, Nucleic Acids and Others), Route of Administration (Intramuscular, Subcutaneous, Oral, Intravenous and Others), Target Therapeutic Area (Infectious Diseases, Oncological Disorders and Others) and Key Geographies (North America, Europe, Asia-Pacific, Latin America, MENA and RoW): Industry Trends and Global Forecasts, 2022-2035’ report features an extensive study of the current market landscape and future potential of the vaccine adjuvant market. The study features an in-depth analysis, highlighting the capabilities of vaccine adjuvant developers.
Amongst other elements, the report features:
- A detailed overview of the overall landscape of vaccine adjuvant developers, along with information on several relevant parameters, such as their year of establishment, company size (in terms of employee count), location of headquarters (North America, Europe, Asia-Pacific and rest of the world), type of vaccine adjuvant (based on composition (aluminum salts, oil-based emulsions, bacterial compounds, lipids, nucleic acids, and others), based on chemical structure (inorganic adjuvants and organic adjuvants), based on function (humoral immunity activator, cell-mediated immunity activator and others)), phase of development (preclinical, clinical, commercial, and undisclosed), type of product (combinational adjuvants and individual adjuvants), type of molecular target (toll-like receptors, CD4 + T cells, and others), route of administration (intramuscular, subcutaneous, intranasal, intravenous, intraperitoneal, intradermal, oral and sublingual), target therapeutic area (infectious diseases, oncological disorders, immunological disorders, and dermatological disorders), type of compatible vaccine (Sub-unit, Inactivated, DNA / RNA, conjugate, live-attenuated, toxoid and others) and application area (human vaccine adjuvants, veterinary vaccine adjuvants and research vaccine adjuvants).
- An insightful competitiveness analysis of vaccine adjuvant developers, based on supplier power (in terms of years of experience), company competitiveness (type of vaccine adjuvant (based on composition, chemical structure, function), type of product, type of molecular target, phase of development, type of compatible vaccine, route of administration, type of therapeutic area and application area) and number of vaccine adjuvants developed.
- Elaborate profiles of prominent players (shortlisted based on a proprietary criterion) engaged in this domain. Each profile features a brief overview of the company (including information on year of establishment, number of employees, location of headquarters and key executives), financial information (if available), details related to vaccine adjuvant portfolio, recent developments, and an informed future outlook.
- A detailed analysis of completed, ongoing and planned clinical studies, based on several relevant parameters, such as trial registration year, enrolled patient population, trial recruitment status, trial phase, target patient segment, type of sponsor / collaborator, most active players and regional distribution of trials.
- An in-depth analysis of patents related to vaccine adjuvants, filed / granted since 2017, based on several relevant parameters, such as patent type, application year, publication year, geographical distribution, Cooperative Patent Classification (CPC) symbols, emerging focus areas, type of applicant, leading players (on the basis of number of patents) and patent benchmarking. In addition, it features a patent valuation analysis which evaluates the qualitative and quantitative aspects of the patents.
- An in-depth analysis of around 50 vaccine developers that are likely to partner with vaccine adjuvant developers, based on several relevant parameters, such as developer strength (on the basis of company size and its experience), pipeline strength and maturity (on the basis of number of vaccines in pipeline and their stage of development) and type of vaccine.
- An analysis of recent partnerships inked between stakeholders engaged in this domain, during the period 2018-2022 (till February), covering acquisitions, commercialization agreements, joint ventures, licensing agreements, manufacturing agreements, material transfer agreements, mergers, product development agreements, research development agreements, service agreements, service alliances and supply agreements. Further, the partnership activity in this domain has been analyzed based on various parameters, such as year of partnership, type of partnership, type of vaccine adjuvant, type of product and most active players (on the basis of number of partnerships). It also highlights the regional distribution of the partnership activity in this market.
- A detailed analysis of various investments received by players engaged in this domain, during the period 2018-2022 (till February), based on several relevant parameters, such as year of investment, number of funding instances, amount invested, type of funding (grant, seed, venture capital, initial public offering, secondary offering, other equity, and debt) and type of investor, along with information on the most active players (in terms of number of funding instances and amount raised), most active investors (in terms of number of funding instances) and geographical distribution (in terms of number of funding instances and amount invested).
- A case study presenting the USFDA approved vaccines, along with the information on their year of approval, type of vaccine, type of vaccine adjuvant and target therapeutic area.
One of the key objectives of the report was to evaluate the current opportunity and future potential associated with the vaccine adjuvant market, over the coming 13 years. We have provided informed estimates
of the likely evolution of the market in the short to mid-term and long term, for the period 2022-2035. Our year-wise projections of the current and future opportunity have further been segmented based on relevant parameters, such as [A] type of vaccine adjuvant (aluminum salts, oil-based emulsions, bacterial compounds, lipids, nucleic acids, and others), [B] route of administration (intramuscular, subcutaneous, oral, intravenous, and others), [C] target therapeutic area (infectious diseases, oncological disorders, and others), and [D] key geographical regions (North America, Europe, Asia-Pacific, Latin America, MENA and rest of the world). To account for future uncertainties in the market and to add robustness to our model, we have provided three forecast scenarios, portraying the conservative, base and optimistic tracks of the market’s evolution.
The opinions and insights presented in the report were also influenced by discussions held with senior stakeholders in the industry.
The report features detailed transcripts of interviews held with the following individuals:
- Bernard Verrier (Co-founder, Adjuvatis)
- Johanna Holldack (Chief Executive Officer, Kupando)
- Cindy Tsang (Director of Business Development, Pacific GeneTech
Key Questions Answered
- Who are the leading players engaged in the vaccine adjuvants domain?
- Which global regions are considered as key hubs for vaccine adjuvant research and development?
- What is the relative competitiveness of different vaccine adjuvant developers?
- Which type of vaccines are suitable for vaccine adjuvants?
- Which type of partnership model is most commonly adopted by industry stakeholders?
- Who are the key investors in this domain?
- How is the current and future market opportunity likely to be distributed across key market segments?
Table of Contents
1. PREFACE
2. EXECUTIVE SUMMARY
3. INTRODUCTION
4. MARKET LANDSCAPE
5. COMPANY COMPETITIVENESS ANALYSIS
6. COMPANY PROFILES: VACCINE ADJUVANT DEVELOPERS BASED IN NORTH AMERICA
7. COMPANY PROFILES: VACCINE ADJUVANT DEVELOPERS BASED IN EUROPE
8. COMPANY PROFILES: VACCINE ADJUVANT DEVELOPERS BASED IN ASIA-PACIFIC
9. CLINICAL TRIAL ANALYSIS
10. PATENT ANALYSIS
11. LIKELY PARTNERS ANALYSIS
12. PARTNERSHIPS AND COLLABORATIONS
13. FUNDING AND INVESTMENT ANALYSIS
14. MARKET FORECAST
15. CASE STUDY: USFDA APPROVED ADJUVANTED VACCINES
List Of Figures
List Of Tables
Companies Mentioned
- 3M
- 4D Pharma
- Adit Ventures
- Adjuvance Technologies
- Adjuvatis
- Advaccine
- Advagene Biopharma
- Afrigen Biologics
- AGC Biologics
- Agenus
- AgriLabs
- Albertsons Companies
- Allergy Therapeutics
- Alliance Foundation Trials
- AlphaVax
- Amgen
- Amyris
- APC
- Aston Sci
- AuraVax Therapeutics
- Avanti Polar Lipids
- Avenue Capital
- Aviragen Therapeutics
- Bavarian Nordic
- Bharat Biotech
- Bill & Melinda Gates Foundation
- Biological E
- BioNTech
- Biosonda
- Biovac
- BlueWillow Biologics
- Boehringer Ingelheim
- Breast International Group
- Brenntag Biosector
- Bristol Myers Squibb
- CaPtivate Pharmaceuticals
- Catalent Biologics
- Celgene
- CEPI
- CinnaGen
- Cleveland BioLabs
- Clover Biopharmaceuticals
- Coalition for Epidemic Preparedness Innovations
- Coley Pharmaceutical
- Commonwealth of Australia
- CordenPharma
- Core Research Grant (CRG)
- Croda
- CSL
- CureVac
- CyTuVax
- Dana-Farber Cancer Institute
- Duke University
- Dynavax Technologies
- Eisai
- Emergent BioSolutions
- eTheRNA immunotherapies
- European Commission
- EuBiologics
- Eurocine Vaccines
- European Commission
- European Investment Bank
- Foris Ventures
- FUJIFILM Diosynth Biotechnologies
- Gavi
- Genocea Biosciences
- Georgia Institute of Technology
- German Federal Ministry of Education and Research
- German Federal Government (Kreditanstalt für Wiederaufbau)
- GI Innovation
- Ginkgo Bioworks
- Global Emerging Markets (GEM)
- Government of Canada
- Government of New Zealand
- Government of Switzerland
- Government of UK
- GSK
- Harvard College
- Hawaii Biotech
- Hayashibara
- Heat Biologics
- Herlev Hospital
- Huvepharma
- iBio
- Icahn School of Medicine
- Immatics Biotechnologies
- Immune Response BioPharma
- ImmuneRegen BioSciences
- ImmunoPrecise Antibodies
- Infectious Disease Research Institute (IDRI)
- Innovate UK
- International Vaccine Institute (IVI)
- Invest-NL
- ISA Pharmaceuticals
- Immune System Regulation (ISR)
- Ministry of Health Israel
- Jiangsu Recbio Technology
- Kemin Industries
- Kineta
- Kupando
- La Jolla Institute
- Line Moon Ventures
- LiteVax
- Mabion
- Massachusetts General Hospital
- Massachusetts Institute of Technology
- Matrix Partners
- Medicago
- Medigen Vaccine Biologics
- Medytox
- Memorial Sloan Kettering Cancer Center
- Merck
- Molecular Express
- Morningside Venture Investments
- N4 Pharma
- Nanometrics
- National Institute of Allergy and Infectious Diseases (NIAID)
- National Institutes of Health
- NeoImmuneTech
- NIH Small Business Innovation Research (SBIR)
- North Coast Technology Investors
- Novartis
- Novavax
- OBI Pharma
- Oncovir
- Oragenics
- OX2 Therapeutics
- OZ Biosciences
- Pacific GeneTech
- Phibro Animal Health
- Praha Vaccines
- Qatar Investment Authority
- RA Capital
- Regeneron
- Roche
- Roquette
- Sam’s Club
- Sanofi
- Sanofi Pasteur
- SapVax
- Scarab Genomics
- Seppic
- Seqirus
- Serum Institute of India
- Shenzhen Rhegen Biotechnology
- Sinocelltech
- Sinovac Biotech
- STAR Capital
- Statens Serum Institut
- Statera Biopharma
- Sumitomo Dainippon Pharma
- Takeda Pharmaceutical
- US Government
- TRANSVAC2
- Ubix Therapeutics
- University of California
- University of Houston
- University of Michigan
- University of Pennsylvania
- University of Queensland
- University of Saskatchewan (Usask)
- University of Texas
- USHealth
- Vaccine Formulation Institute (VFI)
- Valneva
- Vaxart
- Vaxine
- Vir Biotechnology
- ViroVax
- Viscogel
- Wisconsin Alumni Research Foundation (WARF)
- Zoetis
Methodology
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