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The Affinity Column: Biotechnology Around the World

UW Applied Biotechnology Program Team July 7, 2021
The Affinity Column: Biotechnology Around the World

This month’s Affinity Column is authored by guest writer Dr. Natalie Betz, the Academic Director of the 100% online UW Master of Science in Applied Biotechnology and the face-to-face UW-Madison Master of Science in Biotechnology. Natalie explores the global impact of biotechnology around the world.

The role biotechnology plays in addressing human, animal, energy, and environmental issues has come to the forefront more recently because of the COVID-19 pandemic. Given the increasing impact that biotechnology is having globally, I would like to highlight the countries and companies that are playing in this space, and how the equitable impact of biotechnology on both developed and less developed parts of the world are being at last partially addressed. 

The growth of biotechnology

A June 2021 market research report by Polaris Market Research Analysis showed the expected growth of the global biotechnology market size from $752.88 billion in 2020 to an estimated $1,006.68 billion in 2021. This steady rise will continue for the foreseeable future, with projections for it to reach $2.44 trillion by 2028 with a Compound Annual Growth Rate of 15.83 percent.

As seen in Figure 1 by Polaris Market Research, the overall biotechnology market size is expected to grow significantly. The United States continues to be the global leader in biotechnology, however Europe, Asia Pacific, Latin America,  the Middle East, and Africa are expected to have an increasing impact in this sector. Illustrated in Figure 2 by thinkBiotech, the United States (and North America in general), Europe, Australia, New Zealand, and parts of South America and Asia lead development in biotechnology products and services. The thinkBiotech website compiles measurement data of global biotechnology innovation and allows viewers to browse the results by category, country, or region. Each region is analyzed and ranked based on seven different criteria:

  • Productivity
  • IP Protection
  • Intensity (relative to population and economy size)
  • Enterprise Support (business friendly features and availability of capital)
  • Education and Workforce
  • Foundations (a country’s infrastructure)
  • Policy and Stability (governmental support)
Graph that shows the change of biotechnology market size by region from 2016 to 2028.
Figure 1. Biotechnology market size by region from 2016 to 2028. Source: Polaris Market Research Analysis
World map that shows global biotechnology ranking based by country.
Figure 2. Global biotechnology rankings. Source: thinkBiotech

The areas of biotechnology being addressed by these countries can be divided into six major areas, including biopharma, industrial, agricultural, food, environmental, and bioinformatics. Below, Figure 3 from Donald K. Martin, et. al’s journal report, A Brief Overview of Global Biotechnology, highlights the relative percentage of current activity in global biotechnology, with biopharma and industrial biotechnology being the largest sectors, and agriculture a very close third. This distribution speaks to the importance of human and animal health, the use of enzymes in many industrial processes, and the need to improve agricultural productivity to feed an ever-growing world population.

Pie chart that shows the distribution of biotechnology sectors around the world.
Figure 3. Distribution of biotechnology sectors around the world. Source: Donald K. Martin, et. al’s journal article, A Brief Overview of Global Biotechnology.
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Where biotechnology advancements are happening

While global biotechnology has been on the rise since the 1980s, the advancements in biotechnology are generally concentrated in the more developed or higher-income countries. According to Donald K. Martin, et. al, the U.S. and Europe see more investments in biotechnology than other countries, in particular, when compared to developing countries. The investments in biotechnology in the U.S. and Europe are not only in the government sector (20 percent), but a significant proportion occurs in the private sector as well (80 percent). This attests to the expensive nature of biotechnology research and product development, the need for advanced technologies to perform such development, and the highly regulated nature of biotechnology product development.

In the private sector, the top 25 global biotechnology companies, based on their stock market value, or market cap, as determined by BioSpace include):

Company Market Cap (billion) Global Headquarters
Johnson & Johnson 435.77 New Brunswick, New Jersey
Roche (Genentech) 287.85 Basel, Switzerland
Pfizer 220.56 New York, New York
Abbott 213.19 Chicago, Illinois
Abbvie 202.25 Lake Bluff, Illinois
Novartis 194.0 Basel, Switzerland
Merck & Co. 191.89 Kenilworth, New Jersey
Eli Lilly and Co. 178.13 Indianapolis, Indiana
Novo Nordisk 173.37 Bagsvaerd, Denmark
AstraZeneca 141.88 Cambridge, United Kingdom
Bristol Myers Squibb 141.65 New York, New York
Amgen 140.75 Thousand Oaks, California
Sanofi 127.55 Paris, France
GlaxoSmithKline (GSK) 94.57 Brentford, United Kingdom
Gilead Sciences Inc. 81.75 Foster City, California
Moderna Inc. 74.98 Cambridge, Massachusetts
Bayer 63.89 Leverkusen, Germany
Illumina Inc. 56.89 San Diego, California
Vertex Pharmaceuticals 56.76 Boston, Massachusetts
Takeda Pharmaceutical 52.99 Tokyo, Japan
Regeneron Pharmaceuticals, Inc. 52.30 Tarrytown, New York
BioNTech 49.56 Mainz, Germany
Biogen 41.03 Cambridge, Massachusetts
Alexion Pharmaceuticals, Inc. 37.42 Boston, Massachusetts
BeiGene Co. Ltd. 32.38 Beijing, China

These companies are all in the biopharma or medical device/diagnostic testing sectors, as they tend to have the highest stock market values. However, major biotechnology companies in other sectors included in the agricultural arena are: Bayer CropScience, BASF, DuPont Pioneer, Dow AgroSciences, and Syngenta. Companies in industrial biotechnology are equally numerous and cover such areas as industrial enzymes, research tools, bioenergy, bioremediation, and bioprospecting. Worldwide, Donald K. Martin, et. al estimates that the biotechnology industry employs over 900,000 people, which may be an underestimate as the number of biotechnology companies and employees is constantly changing and growing.

Biotechnology and a better quality of life

Access to medical treatments, bioengineered crops, and environmental remediation using biotechnology solutions could have a dramatic impact on the quality of life in countries around the world. To address the inequities in the development of, and access to, biotechnology products among higher and lower income nations, several organizations and initiatives are being developed.  A few organizations are highlighted for their efforts in these areas and include  the Food and Agriculture Organization of the United Nations (FAO) and the World Health Organization (WHO).

The FAO established the GM Foods Platform and recently submitted a report on effective risk-based food safety and regulatory management. This platform is a transparent and reliable repository of safety data for all countries to access that is based on the Codex guideline for the conduct of food safety assessment of genetically modified foods. The platform  also addresses and mitigates trade problems between countries, sets up mentoring schemes between geographically distant countries for testing collaborations, and provides references for how to conduct safety studies by countries with less experience in this area. In addition, it can be used to establish effective and appropriate communication strategies to educate various populations about genetically modified foods. The FAO will continue to facilitate global information-sharing opportunities to ensure food safety and food security around the world.

Based at the WHO headquarters, the Special Program for Research and Training in Tropical Diseases (TDR), is a global program of scientific collaboration that facilitates and supports efforts to combat diseases of poverty. The program is jointly sponsored by the United Nations Children’s Fund, the United Nations Development Program (UNDP), the World Bank, and the WHO. This program focuses on malaria, tuberculosis, vector-borne diseases, and neglected tropical diseases, and utilizes educational programs, training and research centers, clinical research, and grant funding to promote treatments and cures for these diseases.

TDR is part of a multi-partner effort to improve the capacity in low- and middle-income countries to enhance access to and delivery of new health technologies, including biotechnology drugs, diagnostic tests, and vaccines. Led by the UNDP and funded by the government of Japan, this aspect of TDR is called the Access and Delivery Partnership . Throughout the pandemic, TDR has been instrumental in connecting at-risk populations with COVID-19 testing and vaccination campaigns, as well as providing safety monitoring. 

Global biotechnology will continue to impact healthcare and the environment for years to come, and further emphasis should be placed on initiatives to make biotechnology solutions available equally to all.

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Professional headshot photo of Dr. Natalie Betz.About the author: Dr. Natalie Betz received her Ph.D. in Biochemistry and Molecular Biology from the University of Nebraska Medical Center and Eppley Institute for Research in Cancer and Allied Diseases, where she studied the role of the Ha-ras oncogene in skin tumorigenesis.

After working as a postdoctoral fellow at Kansas State University and UW-Madison, she was a Technical Service Scientist at Promega for more than nine years. In 2006, Natalie joined the in-person UW-Madison M.S. in Biotechnology program full time, where she now serves as the Associate Director of the program. 

Natalie became the Academic Director for the UW Extended Campus collaborative 100% online M.S. in Applied Biotechnology program in 2018, and she continues to design and coordinate courses for the program, as well as recruit industry faculty members.

 

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