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Gregory Winter
Gregory Winter
Gregory Winter
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Sir Gregory Paul Winter CBE FRS FMedSci (born 14 April 1951)[6][7] is a Nobel Prize-winning British molecular biologist best known for his work on the therapeutic use of monoclonal antibodies. His research career has been based almost entirely at the MRC Laboratory of Molecular Biology and the MRC Centre for Protein Engineering, in Cambridge, England.

Key Information

He is credited with the invention of techniques to both humanize (1986) and, later, to fully humanize using phage display, antibodies for therapeutic uses.[5][8][9][10][11][12][13] Previously, antibodies had been derived from mice, which made them difficult to use in human therapeutics because the human immune system had anti-mouse reactions to them.[6][14][15][16][17][18] For these developments Winter was awarded the 2018 Nobel Prize in Chemistry along with George Smith and Frances Arnold.[19][20]

He is a Fellow of Trinity College, Cambridge and was appointed Master of Trinity College, Cambridge on 2 October 2012, remaining in office until 2019. From 2006 to 2011, he was Deputy Director of the Laboratory of Molecular Biology, Medical Research Council, acting Director from 2007 to 2008 and Head of the Division of Protein and Nucleic Acids Chemistry from 1994 to 2006. He was also Deputy Director of the MRC Centre for Protein Engineering from 1990 to its closure in 2010.[21][22]

Education

[edit]

Winter was educated at the Royal Grammar School, Newcastle upon Tyne.[6] He went on to study Natural Sciences at the University of Cambridge graduating from Trinity College, Cambridge in 1973. He was awarded a PhD degree, from the MRC Laboratory of Molecular Biology, for research on the amino acid sequence of tryptophanyl tRNA synthetase from the bacterium Bacillus stearothermophilus in 1977[23] supervised by Brian S. Hartley.[24] Later, Winter completed a term of post-doctoral fellowship at Imperial College London, and another at the Institute of genetics in the University of Cambridge.[25]

Career and research

[edit]

Following his PhD, Winter completed postdoctoral research at the Laboratory of Molecular Biology in Cambridge.[26][27] He continued to specialise in protein and nucleic acid sequencing and became a Group Leader at the MRC Laboratory of Molecular Biology in 1981. He became interested in the idea that all antibodies have the same basic structure, with only small changes making them specific for one target. Georges J. F. Köhler and César Milstein had won the 1984 Nobel Prize for their work at the Laboratory of Molecular Biology, in discovering a method to isolate and reproduce individual, or monoclonal, antibodies from among the multitude of different antibody proteins that the immune system makes to seek and destroy foreign invaders attacking the body.[28] These monoclonal antibodies had limited application in human medicine, because mouse monoclonal antibodies are rapidly inactivated by the human immune response, which prevents them from providing long-term benefits.

Winter pioneered a technique to "humanise" mouse monoclonal antibodies; a technique used in the development of Campath-1H  by the Laboratory of Molecular Biology and University of Cambridge scientists.[29] This antibody now looks promising for the treatment of multiple sclerosis. Humanized monoclonal antibodies form the majority of antibody-based drugs on the market today and include several blockbuster antibodies, such as Keytruda.

Winter founded Cambridge Antibody Technology in 1989,[30][31] and Bicycle Therapeutics.[32][33] He worked on the Scientific Advisory Board of Covagen,[34][35] (now part of Cilag) and is also the chairman of the Scientific Advisory Board for Biosceptre International Limited.

In 1989, Winter was a founder of Cambridge Antibody Technology, one of the early commercial biotech companies involved in antibody engineering. One of the most successful antibody drugs developed was HUMIRA (adalimumab), which was discovered by Cambridge Antibody Technology as D2E7, and developed and marketed by Abbott Laboratories. HUMIRA, an antibody to TNF alpha, was the world's first fully human antibody,[36] which went on to become the world's top selling pharmaceutical with sales of over $18Bn in 2017[37] Cambridge Antibody Technology was acquired by AstraZeneca in 2006 for £702m.[38]

In 2000, Winter founded Domantis to pioneer the use of domain antibodies, which use only the active portion of a full-sized antibody. Domantis was acquired by the pharmaceutical GlaxoSmithKline in December 2006 for £230 million.[4][39]

Winter subsequently founded another company, Bicycle Therapeutics Limited as a start up company which is developing very small protein mimics based on a covalently bonded hydrophobic core.[40]

Awards and honours

[edit]
Greg Winter during Nobel press conference in Stockholm, December 2018

Winter was elected a Fellow of the Royal Society (FRS) in 1990[41] and awarded the Royal Medal by the society in 2011 "for his pioneering work in protein engineering and therapeutic monoclonal antibodies, and his contributions as an inventor and entrepreneur".[42] He was given the Scheele Award in 1994.

In 1995, Winter won several international awards including the King Faisal International Prize for Medicine (Molecular Immunology) and in 1999, the Cancer Research Institute William B. Coley Award. Winter was formerly the Joint Head of the Division of Protein and Nucleic acid Chemistry-Biotechnology, and was Deputy Director,[43] at the Laboratory of Molecular Biology, Cambridge, an institution funded by the UK Medical Research Council. He was also Deputy Director of the MRC's Centre for Protein Engineering until its absorption into the Laboratory of Molecular Biology. He is a member of the Advisory Council for the Campaign for Science and Engineering.[44] Winter was appointed Commander of the Order of the British Empire (CBE) in 1997 and Knight Bachelor in 2004. He served as Master of Trinity College, Cambridge from 2012 to 2019.[45][46] In 2015 he received the Wilhelm Exner Medal.[47]

Along with George Smith, Winter was awarded half of the Nobel Prize in Chemistry on 3 October 2018 for his work on phage displays for antibodies (while Frances Arnold received the other half of the prize that same year "for the directed evolution of enzymes").[19] In 2020 he was featured on The Times' 'Science Power List'.[48][49] In 2024 he received the Copley Medal of the Royal Society.[50]In 2025, Winter received the Golden Plate Award of the American Academy of Achievement.[51]

References

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Gregory Winter

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Sir Gregory Paul Winter FRS (born 14 April 1951) is a British molecular and renowned for pioneering techniques, particularly the development of humanized monoclonal antibodies through and methods, which have revolutionized therapeutic treatments for cancer, autoimmune diseases, and other conditions. For these advancements in harnessing the evolution of antibodies, Winter shared the 2018 with George P. Smith and Frances H. Arnold. Winter was born in , , and spent part of his childhood in the Gold Coast (now ) before returning to in 1964. He earned a BA in Natural Sciences from , in 1973, followed by a PhD in protein chemistry from the same institution in 1976, where his doctoral research focused on the amino acid sequence of tryptophanyl-tRNA synthetase. Throughout his career, Winter has been affiliated with the Medical Research Council (MRC) Laboratory of Molecular Biology (LMB) in , joining as a research student in 1973 and advancing to scientific staff in 1981. He served as Head of the Division of Protein and Chemistry from 1994 to 2008, Deputy Director of the LMB from 2006 to 2011, and later as an emeritus group leader. From 2012 to 2019, he held the position of Master of . Winter's key contributions include the invention of techniques for the industrial production of fully human antibodies, enabling the creation of drugs like (Keytruda) for cancer and (Humira) for . His work on allowed for the selection and optimization of antibodies with enhanced specificity and reduced immunogenicity, transforming them from research tools into widely used therapeutics. He also advanced the field by developing bicyclic peptides as a new class of medicines, co-founding companies such as Cambridge Antibody Technology (acquired by ) and Bicycle Therapeutics to commercialize these innovations. In recognition of his impact on and , Winter was knighted in 2004, elected a in 1990, and received the —the Society's oldest and most prestigious award—in 2024 for his antibody engineering breakthroughs. As of 2025, he continues to contribute to through advisory roles and venture funding.

Early Life and Education

Early Life

Gregory Winter was born on 14 April 1951 in , , to a British family. His father worked as a of French, which led the family to relocate to the Gold Coast (now ) during Winter's early childhood, where they spent much of that time. In 1964, the family returned to and settled in . Winter attended the Royal Grammar School in , a prestigious institution that provided a rigorous academic environment. It was during his time at this school that his interests in chemistry and first developed strongly, fostering an early passion for scientific inquiry through classroom experiments and discussions. These school experiences laid the groundwork for his subsequent pursuit of higher education in the sciences.

Education

Gregory Winter pursued his undergraduate studies in Natural Sciences at Trinity College, , where he focused on chemistry and biochemistry, earning a BA degree in 1973. He commenced his doctoral research in the autumn of 1973 at the (LMB) in Cambridge, supported by an MRC studentship and under the supervision of Brian S. Hartley. Winter's PhD thesis centered on the sequencing and comparative analysis of tryptophanyl-tRNA synthetase (TrpRS) from Bacillus stearothermophilus to elucidate catalytic motifs in these enzymes, leading to the award of his PhD from the University of Cambridge in 1976. Following his , Winter remained at the LMB as a postdoctoral fellow from 1977 to 1981, honing expertise in techniques such as —applied to the virus genome in collaboration with George Brownlee and Stan Fields—and protein structure-function investigations via methods.

Professional Career

Research Positions

Gregory Winter joined the Medical Research Council (MRC) Laboratory of Molecular Biology (LMB) in as a member of the scientific staff in 1981, following his postdoctoral work at the same institution. He was granted tenure in 1983, marking his progression to a permanent research position. Throughout his career at the LMB, Winter advanced to senior leadership roles within the research environment. In 1994, he became Head of the Division of Protein and Nucleic Acid Chemistry, a position he held until 2008. He also served as Deputy Director of the LMB from 2006 to 2011 and as acting Director from 2007 to 2008. Winter conducted research at the LMB from 1981, initially full-time and continuing part-time after becoming Master of Trinity College in , while balancing these duties with entrepreneurial activities. Following his retirement from active leadership roles, he was appointed Research Leader at the LMB, continuing his association with the institution in an emeritus capacity.

Administrative Roles

In 2012, Gregory Winter was elected as the Master of , a position he held until 2019, succeeding Lord Rees of Ludlow and overseeing the college's academic, financial, and administrative affairs. As Master, he played a key role in fostering interdisciplinary collaboration and supporting the college's research initiatives within the broader ecosystem. During his tenure, Winter contributed to university governance through trusteeships at several Cambridge-affiliated organizations, including the Newton Trust, which funds scientific research; the Cambridge Commonwealth and Overseas Trusts, supporting international scholarships; and the Kennedy Trust for Rheumatology Research, advancing medical studies. These roles enabled him to influence resource allocation and strategic priorities for education and scientific advancement at the institution. Following his mastership, Winter took on advisory responsibilities in academic policy, notably affiliated with the Centre for and (CSaP) at the , where he provides guidance on integrating scientific expertise into , including areas of research funding and higher education strategy. This involvement reflects his ongoing commitment to bridging academia and policy-making in the sciences.

Business Ventures

In 1989, Gregory Winter founded Cambridge Antibody Technology (CAT), a biotechnology company specializing in the development of antibody therapeutics using innovative selection techniques. CAT focused on creating fully human antibodies for pharmaceutical applications, leading to partnerships with major drug companies and the eventual marketing of several approved therapies. In 2006, AstraZeneca acquired CAT for £702 million, integrating it with its subsidiary MedImmune to expand antibody drug discovery capabilities. Winter co-founded Domantis in 2000, building on his research to advance domain antibodies—smaller, more stable fragments derived from human antibodies suitable for targeted therapies. The company emphasized aggregation-resistant domains for applications in and , securing collaborations with pharmaceutical firms to accelerate clinical development. In December 2006, GlaxoSmithKline acquired Domantis for £230 million, incorporating its technology into GSK's biologics pipeline. Winter also co-founded Bicycle Therapeutics, a company developing bicyclic peptides as a novel class of therapeutics for cancer and other diseases, leveraging constrained scaffolds for enhanced binding specificity and stability. As of 2025, he continues to serve on the company's , providing ongoing strategic guidance. Winter also serves on the board of Biosceptre, a company focused on cancer therapies, as of 2025. Through these ventures, Winter played a pivotal role in commercializing technology, establishing spin-out companies that translated academic innovations into viable therapeutic platforms and industry-wide adoption.

Scientific Research

Antibody Engineering

Gregory Winter pioneered the humanization of monoclonal antibodies in 1986, addressing the immunogenicity issues of rodent-derived antibodies used in human therapy. His approach involved grafting the complementarity-determining regions (CDRs)—the antigen-binding loops—from murine antibodies onto human antibody frameworks, retaining the specificity of the original antibody while minimizing immune rejection. This technique, detailed in a seminal paper by Jones et al., demonstrated that a reshaped human antibody could bind hapten with affinity comparable to its murine counterpart, marking a breakthrough in protein engineering for therapeutics. Chimeric antibodies, developed earlier in the , served as precursors by fusing variable regions to constant domains, resulting in molecules that were about two-thirds but still prone to eliciting responses. Winter's humanization method advanced this further, creating antibodies with up to 95% sequence content by limiting non-human elements to the CDRs, thereby improving and reducing for clinical use. These engineered antibodies represented a critical step toward fully versions, enhancing their safety and efficacy as drugs. An early application of Winter's humanization technique was the development of Campath-1H, a targeting the on lymphocytes for treating . Generated by his team at the Laboratory of Molecular Biology, Campath-1H was the first to enter clinical trials, showing tolerability in patients and efficacy in depleting malignant cells. It received FDA approval in 2001 as for B-cell in patients who had failed prior therapies. This success validated humanized antibodies as viable therapeutics and paved the way for their integration with methods to produce fully human antibodies from synthetic libraries.

Phage Display Technology

In the late 1980s, Gregory Winter adapted technology, originally developed by George Smith for peptide presentation, to generate libraries of human fragments. This innovation built on Smith's 1985 method of fusing foreign peptides to the minor coat protein of filamentous bacteriophages, such as M13, to display them on the phage surface. Winter's group focused on expressing functional antibody variable domains on phage, enabling the isolation of antigen-specific binders from diverse repertoires. The core process involves genetically linking antibody genes—typically encoding single-chain variable fragments (scFv) or Fab domains—to the encoding the phage's minor coat protein, such as III protein (pIII). This fusion results in phages that display the antibody fragment on their surface while retaining the genetic information inside the virion, creating a direct genotype-phenotype linkage. Selection, often termed biopanning, proceeds by immobilizing an on a solid support, incubating the phage library with it, washing away non-binders, and eluting bound phages, which are then amplified in for iterative rounds of enrichment. This affinity-based selection can achieve up to 1,000-fold enrichment in a single round and over 1 million-fold across multiple rounds. A key innovation by Winter was the creation of large, diverse antibody libraries using vectors, which allow monovalent display and facilitate the construction of synthetic repertoires from human V-gene segments. These libraries can encompass 10^7 to more than 10^10 unique variants, vastly exceeding the diversity achievable through or hybridoma methods, and enabling the isolation of high-affinity antibodies against a wide range of targets, including self-antigens. This approach was detailed in the foundational paper co-authored by Winter and colleagues, which demonstrated the display of complete antibody V domains on filamentous phage and their specific binding to antigens. The work, conducted in collaboration with George Smith, laid the groundwork for as a of .

Therapeutic Applications

Gregory Winter's pioneering techniques in antibody humanization and have directly contributed to the development of several blockbuster therapeutic antibodies, revolutionizing treatments for cancer and autoimmune disorders. One prominent example is (Keytruda), a humanized targeting the PD-1 , approved by the FDA in September 2014 as the first therapy in its class for advanced and later expanded to other cancers. This drug, derived using humanization methods inspired by Winter's CDR-grafting approach, has become a cornerstone of , enabling the to attack tumors more effectively.69927-3/fulltext) Another key application is (Humira), the first fully human antibody generated via technology developed in Winter's laboratory, targeting tumor necrosis factor-alpha (TNF-α) to treat and other autoimmune conditions. Approved by the FDA in 2002, adalimumab exemplified the potential of phage display to produce non-immunogenic antibodies directly from human repertoires, avoiding the need for animal-derived sources. By 2025, despite the rise of biosimilars and competition, it remains one of the highest-grossing pharmaceuticals ever, with cumulative sales exceeding $200 billion and transforming management of inflammatory diseases. Ustekinumab (Stelara), a fully against the IL-12/23 p40 subunit, also benefited from advancements in human antibody production techniques influenced by Winter's humanization strategies, generated through immunization of transgenic mice expressing immunoglobulin genes. Approved in 2009 for moderate-to-severe plaque and later for , it modulates immune responses in autoimmune conditions, demonstrating the broader applicability of humanized antibodies in and .69927-3/fulltext) Overall, Winter's innovations have enabled the approval of over 100 therapeutic antibodies by , accounting for a significant portion of the more than 180 monoclonal antibodies in clinical use worldwide, profoundly impacting , , and by providing safer, more effective targeted therapies.69927-3/fulltext)

Awards and Honours

Nobel Prize

On 3 October 2018, the Royal Swedish Academy of Sciences announced that Sir Gregory P. Winter had been awarded the in Chemistry, sharing the honor with George P. Smith of the and Frances H. Arnold of the . The prize recognized groundbreaking advancements in harnessing the power of evolution: Arnold for of enzymes, and Smith and Winter jointly for the of peptides and antibodies, a technique Winter pioneered to generate therapeutic antibodies. Winter's specific citation was "for the of peptides and antibodies." The total prize amount was 9 million Swedish kronor (SEK), with one half awarded to Arnold and the other half divided between and Winter. The award ceremony took place on 10 December 2018 at the , where King of presented the Nobel diplomas, medals, and to the laureates in a formal marking the anniversary of Alfred Nobel's death. This event, attended by Swedish royalty and international dignitaries, highlighted the global impact of the laureates' work on and medicine. Prior to the Nobel recognition, Winter had been knighted in 2004 for services to molecular biology, earning the title Sir Gregory Winter, but the Nobel Prize stood as the pinnacle of his scientific honors. As part of the Nobel proceedings, Winter delivered his lecture on 8 December 2018 at Aula Magna, Stockholm University, titled "Harnessing Evolution to Make Medicines," where he discussed the evolution of antibodies through phage display and its applications in developing treatments for immune disorders. This lecture underscored the transformative potential of his contributions, which have led to several approved antibody-based drugs.

Other Awards

In addition to the Nobel Prize, Sir Gregory Winter has received numerous prestigious honors recognizing his contributions to protein engineering and therapeutic antibody development. He was elected a (FRS) in 1990, acknowledging his early innovations in and research. In 1997, he was appointed Commander of the (CBE) for services to , a distinction that preceded his knighthood in 2004. Winter was elected a Fellow of the Academy of Medical Sciences (FMedSci) in 2006, highlighting his impact on medical research and biotechnology. In 2011, he received the Royal Medal from the Royal Society for his pioneering work in , particularly the development of therapeutic monoclonal antibodies through techniques, which revolutionized drug discovery. Other notable awards include the 1989 Louis-Jeantet Prize for Medicine, the 1999 William B. Coley Award for tumor , the 2008 Dr H.P. Heineken Prize for Biochemistry and from the Royal Academy of Arts and Sciences, the 2012 Award for Scientific and Technical Research (shared with Richard A. Lerner), the 2015 [Linus Pauling](/page/Linus_Paul ing) Award (shared with Lerner), the 2017 in Advanced Technology, and the 2024 —the Royal Society's oldest and most prestigious honor—for his groundbreaking contributions to and the production of life-saving therapeutics. In 2025, he received the Golden Plate Award from the American Academy of Achievement, recognizing his lifetime achievements in scientific innovation and .

Later Career and Legacy

Post-Nobel Activities

Following his receipt of the in 2018, Sir Gregory Winter continued his involvement in as a co-founder and on the board of Bicycle Therapeutics, where he advises on the development of bicyclic . As of 2025, Winter remains active in this capacity, contributing to the company's strategic direction in harnessing phage display-derived technologies for novel drug candidates. Winter has engaged in numerous public lectures and interviews to share insights on scientific innovation and antibody research. In December 2024, he participated in "The Nobel Inspiration" interview series hosted by the University of Science and Technology, discussing the drivers of breakthroughs in chemistry and . This was followed by a appearance in February 2025 on the 50th anniversary of the Milstein-Köhler paper, where he reflected on the evolution of techniques. In August 2025, Winter joined a tea session at in titled "Science, Failures and Ideas that Endure," engaging with academics on the role of perseverance in research. In 2020, Winter was recognized on ' Science Power List for his enduring influence in and therapeutics. As Research Leader Emeritus at the (LMB), Winter has focused on advisory roles in , including affiliations with the at the to bridge research and policymaking.

Influence on Biotechnology

Gregory Winter's pioneering development of phage display and antibody humanization techniques has fundamentally transformed the biotechnology landscape, particularly in the field of therapeutic antibodies. By enabling the directed evolution of fully human antibodies, his innovations have driven the exponential growth of the monoclonal antibody market, which exceeded $200 billion in 2023 and is projected to surpass $250 billion by 2025, fueled by advancements in targeted therapies for cancer, autoimmune diseases, and infectious conditions. These technologies now underpin over 50% of antibody therapeutics on the market, shifting production from labor-intensive hybridoma methods to efficient, scalable library-based screening that accelerates drug discovery and reduces development costs. This revolution has not only expanded the therapeutic arsenal but also positioned biotechnology as a cornerstone of modern medicine, with phage display libraries serving as a foundational tool in pharmaceutical R&D pipelines worldwide. Winter's work has been instrumental in advancing , particularly through the creation of customizable antibodies tailored to individual patient needs or targets. Phage display allows for the rapid isolation of high-affinity antibodies against unique antigens, including those associated with rare genetic disorders or patient-specific tumor markers, thereby enabling precision therapies that were previously unattainable with animal-derived antibodies. For instance, this approach supports the development of bespoke immunotherapies for orphan diseases, where low prevalence limits traditional or strategies, fostering a move toward individualized treatment regimens that improve efficacy and patient outcomes. Through his long tenure as a group leader at the , Winter supervised numerous PhD students and postdoctoral researchers who have extended his innovations into new applications. Notable mentees include Ian Tomlinson, whom he supervised during PhD studies and who later co-founded Domantis to commercialize domain technologies, and Christian Heinis, a postdoc whose work on constrained peptides contributed to the founding of Therapeutics. Collaborators such as John McCafferty, who co-developed early for , further amplified these efforts, leading to widespread adoption of display technologies in academic and industrial settings. This mentorship legacy has cultivated a generation of scientists driving ongoing refinements in engineering, including synthetic libraries and multi-specific formats. Winter's broader contributions have catalyzed a global shift from animal-derived monoclonal antibodies to fully human versions, markedly reducing and associated side effects in clinical use. Humanized antibodies, achieved by complementarity-determining regions onto human frameworks, exhibit improved and lower risks of immune reactions, allowing for safer long-term administration in diverse patient populations. This transition has minimized adverse events like in therapies for chronic conditions, enhancing tolerability and expanding access to antibody-based treatments across healthcare systems worldwide. Overall, Winter's legacy endures in the biotech sector's emphasis on evolutionary principles, paving the way for future innovations in bispecific antibodies and next-generation immunotherapies.

References

  1. https://www.nobelprize.org/prizes/chemistry/2018/winter/biographical/
  2. https://royalsociety.org/news/2024/08/medals-and-awards-recipients-2024/
  3. https://www.nobelprize.org/prizes/chemistry/2018/winter/facts/
  4. https://www2.mrc-lmb.cam.ac.uk/group-leaders/emeritus/greg-winter/
  5. https://www.biosceptre.com/team/
  6. https://www.trin.cam.ac.uk/news/sir-gregory-winter-awarded-the-royal-societys-copley-medal/
  7. https://investors.bicycletherapeutics.com/board-member/sir-greg-winter
  8. https://www.cam.ac.uk/research/news/sir-greg-winter-wins-the-2018-nobel-prize-in-chemistry
  9. https://mediatheque.lindau-nobel.org/laureates/winter/cv
  10. https://www.csap.cam.ac.uk/network/greg-winter/
  11. https://www.cam.ac.uk/stories/antibodies-research-nobel-prize
  12. https://www.labiotech.eu/interview/greg-winter-interview-history/
  13. https://www.fiercebiotech.com/biotech/press-release-glaxosmithkline-to-acquire-domantis-for-%25C3%25A2%25C2%25A3230-million
  14. https://www.theguardian.com/business/2006/dec/09/glaxosmithklinebusiness
  15. https://www.bicycletherapeutics.com/profile/leadership/
  16. https://www.nobelprize.org/uploads/2018/10/winter-lecture.pdf
  17. https://www.nature.com/articles/321522a0
  18. https://www.accessdata.fda.gov/scripts/opdlisting/oopd/detailedIndex.cfm?cfgridkey=107197
  19. https://www.nature.com/articles/348552a0
  20. https://www2.mrc-lmb.cam.ac.uk/archive/articles/Celebrating_UK_bioscience.pdf
  21. https://www.supremecourt.gov/DocketPDF/21/21-757/254497/20230210100916044_WinterSanofi%2520Amici%2520Main%2520E%2520FILE%2520Feb%252010%252023.pdf
  22. https://www.genengnews.com/topics/drug-discovery/top-10-best-selling-drugs-2/
  23. https://www.tandfonline.com/doi/abs/10.4161/mabs.3.6.17815
  24. https://www.antibodysociety.org/resources/approved-antibodies/
  25. https://pubmed.ncbi.nlm.nih.gov/39711140/
  26. https://www.nobelprize.org/prizes/chemistry/2018/press-release/
  27. https://www.nobelprize.org/ceremonies/the-nobel-prize-award-ceremony-2018/
  28. http://news.bbc.co.uk/2/hi/science/nature/3804553.stm
  29. https://www.nobelprize.org/prizes/chemistry/2018/winter/lecture/
  30. https://royalsociety.org/people/gregory-winter-12548/
  31. https://www.telegraph.co.uk/science/2018/10/03/british-nobel-prize-winner-celebrate-champagne-re-engineering/
  32. https://acmedsci.ac.uk/fellows/fellows-directory/ordinary-fellows/fellow/Sir-Gregory-Winter-0006311
  33. https://www.aacr.org/professionals/membership/aacr-academy/fellows/sir-gregory-p-winter-cbe-frs-fmedsci/
  34. https://www.fpa.es/en/princess-of-asturias-awards/scientific-and-technical-research/2012/
  35. https://www.kyotoprize.org/en/laureates/2017_winter/
  36. https://achievement.org/summit/2024/
  37. https://www.marketscreener.com/quote/stock/BICYCLE-THERAPEUTICS-PLC-58981492/company-governance/
  38. https://www.youtube.com/watch?v=_rVhg9yogrU
  39. https://www.healthtech.com/the-chain/conversation-with-sir-greg-winter-on-the-50th-anniversary-of-the-milstein-and-kohler-paper
  40. https://www.ntu.edu.sg/ias/news-events/news/detail/science--failures-and-ideas-that-endure--tea-session-with-chemistry-nobel-laureate-prof-sir-gregory-winter
  41. https://www.aurumbureau.com/speaker/gregory-winter/
  42. https://www.genscript.com/learning-center/antibody-drugs-market-analysis-and-future-trends.html
  43. https://www.thelancet.com/journals/lancet/article/PIIS0140-6736(06)69927-3/fulltext
  44. https://oxfordglobal.com/nextgen-biomed/resources/revolutionising-antibody-engineering-the-groundbreaking-work-of-sir-gregory-winter
  45. https://www.nature.com/articles/s42003-023-05390-0
  46. https://pubmed.ncbi.nlm.nih.gov/8212307/
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