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Désiré Collen

March 10, 2023

Désiré, Baron Collen (born in Sint-Truiden, Belgium, 21 June 1943) is a Belgian physician, chemist, biotechnology entrepreneur and life science investor.[1][2] He made several discoveries in thrombosis, haemostasis and vascular biology in many of which serendipity played a significant role. His main achievement has been his role in the development of tissue-type plasminogen activator (t-PA) from a laboratory concept to a life-saving drug for dissolving blood clots causing acute myocardial infarction or acute ischemic stroke. Recombinant t-PA was produced and marketed by Genentech Inc as Activase and by Boehringer Ingelheim GmbH as Actilyse, and is considered biotechnology's first life saving drug.[3]

Désiré Collen
Désiré Collen in 2012
Born
Désiré Collen

(1943-06-21)21 June 1943
Sint-Truiden, Belgium
NationalityBelgian
Spouse
Louisa Reniers
(m. 1966)
Children
  • An Collen
  • Peter Collen
  • Christine Collen
Scientific career
Fields

In 2008 Collen reached the mandatory retirement age of 65 years as Professor of the Faculty of Medicine at KU Leuven (Belgium), where he served as Director of the Center for Thrombosis and Vascular Research (now Center for Molecular and Vascular Biology) and the VIB Department for Transgene Technology and Gene Therapy (now VIB-KU Leuven Center for Cancer Biology).[4] He authored and co-authored over 650 research papers in peer reviewed international journals which have been cited over 70,000 times, and 39 US Patents. He ranked among the 100 most cited scientific authors of the 1980s listed by Current Contents[5] and among the top 100 living contributors to biotechnology in polls conducted by Reed Elsevier in 2005.[6] In 2012 SciTech Strategies placed him among the top 400 most influential scientists in biomedical research for the period 1996–2011.[7]

In 1988, Désiré Collen founded the 'D. Collen Research Foundation vzw',[8] a not-for-profit organization with the mission to invest the mayor part of the royalties earned from Genentech on the t-PA patent in scientific research. The Foundation was renamed in 2007 into 'Life Sciences Research Partners vzw' of which Collen remained the Statutory Chairman until 2019.

In 1991 he spun out the company Thromb-X nv from the KU Leuven in Belgium. The primary focus of Thromb-X was in the cardiovascular space with an initial effort to develop staphylokinase as a more affordable thrombolytic medicine compared to t-PA ("poor man's t-PA"). With the constitution of ThromboGenics Ltd in Ireland in 1998, the company expanded its R&D scope to include cardiovascular, oncology and ophthalmology programs. ThromboGenics developed ocriplasmin, a truncated form of plasmin, for the treatment of vitreomacular traction in the eye.[9][10] Disappointed by the, in his opinion inadequate strategic and commercial governance of the company, Collen left ThromboGenics as Chairman and board member in December 2013.

With the help of Chris Buyse, his CFO and "companion de route" during their 7 years at ThromboGenics, he co-financed the start of Fund+, an ever-green investment fund that currently manages over 200 million euro . Fund+ is a private Fund for long term equity investment in innovative life sciences companies with a strong patient-centered approach aiming at both a financial return and a tangible societal impact.[11]

King Albert II of Belgium awarded Désiré Collen hereditary nobility, with the personal rank of Baron in 2013. He was also recipient of the Belgian Francqui Prize in 1984, Louis-Jeantet Prize for Medicine in 1986, Bristol-Myers Squibb Award for Cardiovascular Research in 1994, Interbrew-Baillet Latour Health Prize in 2005, Insead Innovator Prize in 2009, Robert P. Grant Medal of the International Society for Thrombosis and Haemostasis in 2011, Lifetime Achievement Award of the Belgian-American Chamber of Commerce (BelCham) in 2013, and Lifetime Achievement Award of Scrip in 2013. He received honorary doctorates from Erasmus University, Rotterdam, the Netherlands in 1988; Free University of Brussels (VUB), Brussels, Belgium in 1994; University of Notre Dame, Notre Dame, IN, United States in 1995; and Université de la Méditerranée, Marseille, France, in 1999.

Education

Désiré Collen, born on 21 June 1943 in the Flemish town of Sint-Truiden as the first of two children of Frans Collen and Maria Hoebrechs, started his studies in medicine at the University of Leuven (KU Leuven) in 1961. Since his third year of the seven-year curriculum he combined his studies with research: first in the laboratory of Belgian physiologist Joseph P. Bouckaert, and from the next year on in the Laboratory for Blood Coagulation under the direction of Marc Verstraete. Under the guidance of young gastroenterologist Guido Tytgat and biochemist René De Vreker he studied the rate at which the coagulation proteins fibrinogen and plasminogen are cleared from the circulation. This early experience with biochemical lab work inspired Désiré Collen to become a researcher rather than a practicing general physician or medical specialist. Realising his knowledge in chemistry was inadequate, he combined his education in medicine with academic studies in chemistry. He graduated from the KU Leuven as Doctor in Medicine in 1968 and as Master ("Licentiaat") in Chemistry in 1969.

Mid 1968 Désiré Collen became research assistant of the Belgian National Fund for Scientific Research in the Laboratory of Marc Verstraete. He worked simultaneously in the Department of Physical Chemistry under the supervision of Leo C.M. De Maeyer. He started a research project on factors influencing the polymerization of fibrinogen to fibrin. Only months later, he published his first, although a very short one, scientific paper in Nature.[12]

In 1971–1972 he went as an Associate Research Scientist of the National Institutes of Health (United States) to the New York University Medical Center to work with Alan Johnson. In 1972–1973 he worked in the laboratory of Birger Blombäck[13] at Karolinska Institutet in Stockholm (Sweden) as a NATO Research Fellow. After obtaining his PhD in Chemistry at the KU Leuven in 1974 and concluding his mandatory military service, Désiré Collen was appointed in 1976 as Lecturer (Docent) in the Faculty of Medicine at KU Leuven and as Adjunct Head of Clinic in the Section Bleeding and Vascular Diseases in the Department of Internal Medicine at the University Hospital Leuven.

Career and research

Research output

The scientific output of Désiré Collen between 1968 and 2011 consists of 667 peer-reviewed research papers in international journals, 172 review articles and 39 issued US patents. His publications have been cited over 70,000 times in the scientific literature.[4] He made seminal contributions to the fields of thrombosis, haemostasis and vascular biology.[4] His pivotal achievement has been the development of tissue-type plasminogen activator (t-PA) from a laboratory concept to the first life saving biotech drug. Recombinant t-PA has been primarily used for dissolving blood clots causing acute myocardial infarction or acute ischemic stroke.[3]

The cloning of t-PA and preclinical research

T-PA is a protease that converts inactive plasminogen into active plasmin, which in turn cleaves fibrin, the main component of blood clots. Upon cleavage of the long fibrin strands by plasmin, the clot falls apart and dissolves. Between August 1977 and September 1978 Désiré Collen and Bjorn Wiman elucidated that the conversion of plasminogen to plasmin takes place when both proteins are bound to fibrin in the blood clot.[14][15][16] This molecular model for the regulation and control of fibrinolysis was presented in 1979 during an invited plenary lecture (Edward Kowalski Memorial Lecture) at the VIIth International Congress on Thrombosis and Haemostasis in London. The written report of this presentation has been cited over 1200 times in the scientific literature.[17]

Collen collaborated in the same period with Professor Alfons Billiau of the Rega Institute for Medical Research in Leuven, Belgium, on the inhibition of plasminogen activators secreted by malignant cells in culture, hypothesizing that synthetic inhibitors might suppress the malignant phenotype of these cells. In order to have a source for these "malignant plasminogen activators" the Bowes Melanoma Cell line was obtained from Professor Daniel Rifkin of the Rockefeller University, New York City at the end of 1978. It quickly appeared that this cell line produced large amounts of a plasminogen activator with a molecular weight of 70,000 dalton and a high affinity for fibrin, characteristic of human tissue-type plasminogen activator (t-PA), whereas most other malignant cells produced a plasminogen activator with a molecular weight of 54,000 dalton without affinity for fibrin, which is characteristic of pro-urokinase. This game-changing, although trivial serendipitous observation, made on 9 February 1979,[1] was to change the course of thrombolytic therapy.

In order to produce sufficient amounts of t-PA for further biochemical and preclinical studies, post-doctoral fellow Dingeman (Dick) Rijken succeeded in isolating sufficient amounts of pure and homogeneous t-PA from conditioned culture medium from the Bowes Melanoma Cell line.[18][19] This purified protein was used by post-doctoral fellow Osamu Matsuo to evaluate the thrombolytic potential of t-PA in rabbits suffering from an experimental pulmonary embolus.[20] The research led to a key patent (US4752603) entitled 'Plasminogen activator and pharmaceutical composition having thrombolytic activity'[21] which was first submitted in the Netherlands on 11 June 1980.

On 12 June 1980, one day after the submission of the patent application, Collen presented the results at the Fifth Congress on Fibrinolysis in Malmö (Sweden) in the presence of Diane Pennica, a young scientist from biotech company Genentech Inc, based in South San Francisco. Collen, KU Leuven and Genentech agreed to collaborate on the production of a recombinant version of t-PA (rt-PA), embarking on a new model for drug development: academic and biotech collaboration, today routine, but at that time a new modus operandi.[1] Within 18 months, Pennica and her team had cloned the cDNA (complementary DNA) of human t-PA messenger RNA and was producing rt-PA in cultures of Chinese hamster ovary cells.[22]

The therapeutic potential of rt-PA and its functional identity with natural t-PA was proven in a collaboration with Steven R. Bergman and Burton Sobel (Washington University School of Medicine, Saint Louis), Frans Van de Werf (KU Leuven), and Herman 'Chip' Gold and Tsunehori Yasuda (Massachusetts General Hospital, Harvard Medical School, Boston) using canine models of coronary thrombosis.[23][24][25]

Clinical studies with t-PA

Also in 1981, following a discussion with Alfons Billiau at a scientific congress in Amsterdam, Dutch nephrologist Willem Weimar of the Dijkzigt Hospital in Rotterdam treated for the first time a patient with t-PA purified from the Bowes Melanoma Cell line. The patient, a 29-year-old lady, was suffering from a renal transplant vein thrombosis and was successfully treated resulting in a decennia-long survival.[26] Cardiologists Frans Van de Werf and Burton Sobel tested t-PA in 1983 in a pilot clinical study on patients with acute myocardial infarction.[27] Also in 1983, the first prospective, randomized and placebo-controlled trial of recombinant t-PA took place in three US hospitals.[28]

The subsequent NIH Thrombolysis in Acute Myocardial Infarction (TIMI) trials led by Eugene Braunwald (Brigham and Women’s Hospital, Harvard School of Medicine, Boston),[29][30][31][32] and the European Cooperative Study Group Trials led by Marc Verstraete (KU Leuven)[33][34] culminated in the final approval of rt-PA as thrombolytic agent by the FDA on 13 November 1987.[35] Genentech immediately started to market the drug in the US under the brand name Activase®,[36] while Boehringer Ingelheim would distribute the drug in the rest of the world (except Japan) as Actilyse®.

A lifesaving drug

The controversy over whether the more expensive rt-PA was clinically superior over streptokinase as a thrombolytic agent climaxed in the scientific press between 1988 and 1992.[37][38][39][40] To end this controversy, the GUSTO trial (Global Utilization of Streptokinase and t-PA for Occluded Coronary Arteries) was set up, a head-to-head comparison between rt-PA and streptokinase. In the GUSTO-trial 41,021 heart attack patients were treated in 1,081 hospitals in 15 countries. Cardiologist Eric Topol of the Cleveland Clinic (USA), cardiologist/statistician Robert Califf of Duke University Medical Center (USA) and David Stump of Genentech coordinated the trial. In absolute figures the 30-day mortality rate in the rt-PA group was 1% lower (or in relative figures 14%) compared to the mortality in the streptokinase group.[41][42][43] After the GUSTO studies, rt-PA became the thrombolytic drug of choice for most of the cardiologists in the Western world and would save the lives of many tens of thousands of heart attack patients.[3]

Nowadays, cardiologists agree that timely performed percutaneous coronary intervention (PCI), also known as 'angioplasty’ and ‘stenting', is the preferred strategy to treat acute myocardial infarction instead of thrombolysis. PCI is associated with less mortality on the short term (7% versus 9% for thrombolysis), a lower risk of a recurrent infarct (3% versus 7%) and a lower frequency of cerebral hemorrhage (1% versus 2%). Also over a longer period of time, PCI leads to a lower mortality rate.[44]

However, because access to invasive facilities is limited in many countries, thrombolytic therapy is still employed in many centers worldwide for treating acute myocardial infarction.[45] Moreover, rt-PA based thrombolysis still is an important strategy to treat ischemic stroke[46][47] and to a lesser extent, pulmonary embolism[48][49] and deep vein thrombosis;[50] it has even been used to restore the blood flow in occluded central venous access ports and in the frozen limbs of mountaineers, resulting in a spectacular decrease in the amputation rate.[51]

Staphylokinase – poor man's t-PA

On many occasions Désiré Collen expressed his frustration that the lives of many more people could have been saved, had rt-PA been more readily available, also to people who were not living in the affluent western world.[1] Therefore, he invested part of Genentech's t-PA royalty stream in the search for a "t-PA for the poor".

In the early 1990s, together with Roger Lijnen (KU Leuven) and Osamu Matsuo (Kindai University, Osaka, Japan), Collen started to evaluate whether staphylokinase (STAR), a bacterial profibrinolytic agent with high fibrin specificity, could be a valid alternative for rt-PA in less wealthy territories.[52] By setting up spin off company Thromb-X, Collen had the clear objective to further develop staphylokinase through the preclinical and clinical research phases up to the market introduction. Although wild type staphylokinase and variants with reduced immunogenicity and preserved lytic potency have been tested with success in humans,[53][54] its further development came to an unfortunate standstill because of the prohibitive expense of a GUSTO-like clinical trial with a mortality end-point that had become the standard in the West. Not even licensing out the further clinical development, production and commercialization of staphylokinase to companies in developing countries (where for most people rt-PA is hardly available) could save this project.

VIB Department for Transgene Technology and Gene Therapy

With the constitution of the Flemish Institute for Biotechnology (Vlaams Instituut voor Biotechnologie – VIB), Collen was able to extend the capacity of his Leuven-based academic research laboratories. He became Director of the VIB Department for Transgene Technology and Gene Therapy (now VIB-KU Leuven Center for Cancer Biology) based on the Gasthuisberg Campus of the KU Leuven. Together with Professor Peter Carmeliet and colleagues, landmark contributions were made to the fields of vascular biology, tumor biology and neurobiology, e.g. between 1995 and 2008 the Department conducted breakthrough research on the role of vascular endothelial growth factor (VEGF) and placental growth factor (PlGF) in angiogenesis,[55][56][57] cancer,[58] and amyotrophic lateral sclerosis (ALS).[59][60]

Academic Appointments

From 1981 to 2008 Désiré Collen was Professor at the Faculty of Medicine of the KU Leuven in Belgium. Between 1998 and 2002 he temporarily resigned to develop ThromboGenics, but remained 'Extraordinary Professor' (Buitengewoon hoogleraar). In 2008 he reached the age of mandatory retirement at Belgian Universities.[1]

Désiré Collen was also Professor of Biochemistry and Medicine in the Department of Kenneth G. Mann at the University of Vermont College of Medicine, Burlington, Vermont, USA (1984–2005), Visiting Professor of Medicine in the group of Herman 'Chip' Gold of Massachusetts General Hospital at Harvard School of Medicine, Boston, MA, USA (1987–1994), Consultant in Medicine at the Massachusetts General Hospital, Boston, MA, USA (1987–2005) and Visiting Professor at the Division of Surgery and Anaesthesia of Kevin Burnand at United Medical and Dental Schools of Guy's and St Thomas' Hospitals, London, UK (1999–2002).[1]

Désiré Collen was Director of the Center for Molecular and Vascular Biology at the Faculty of Medicine of the KU Leuven from 1994 to 2008, Division Head of the Protein Research Division of Leuven Research and Development vzw of the KU Leuven from 1976 to 1998 and Director of the Department for Transgene Technology and Gene Therapy of the Vlaams Instituut voor Biotechnologie (VIB) from 1994 to 2008.[1]

D. Collen Research Foundation

On 2 July 1988 the D. Collen Research Foundation was constituted by Désiré Collen, Roger Dillemans Roger Dillemans, Rector of the KU Leuven, Karel Tavernier, General Manager of the KU Leuven, Jacques Vander Eecken, Chairman of Leuven Research and Development and Lawrence Fouraker, former Dean of the Harvard Business School representing the Harvard Medical School.[1] The mission of the Foundation was to canalize the major part of the income from the rt-PA royalties towards "the execution, promotion and support of scientific research in general, and biomedical and biotechnological research in particular, by making available research grants, research positions, travel bursaries, by organizing scientific congresses and symposia, providing financial support for publications and all related activities that support the advancement of science." With the support of the Foundation, over 100 young researchers were able to obtain further specialisation abroad; numerous congresses and symposia and two academic chairs were sponsored, the 9th floor of the research building on the Gasthuisberg Research Campus and a guesthouse on the Groot Begijnhof campus were built with financial support of the Foundation. These buildings housed for many years the Center for Thrombosis and Vascular Research and the VIB Department for Transgene Technology and Gene Therapy and their postdoctoral researchers, respectively.[1]

In 2007 the D. Collen Research Foundation was renamed to Life Sciences Research Partners vzw. It continued the activities of the D. Collen Research Foundation, but also started to invest in life science companies, such as Celyad, Ogeda, Amakem, Bone Therapeutics and others.

Thromb-X and ThromboGenics

In 1991, Désiré Collen spun out Thromb-X nv from the KU Leuven with an initial mission to develop staphylokinase as an equally effective but less expensive successor of rt-PA. With the foundation of ThromboGenics Ltd in Ireland in 1998, the Company expanded its R&D scope to include various cardiovascular, oncology and ophthalmology programs in-licensed from the KU Leuven and the Vlaams Instituut voor Biotechnologie (Flemish Institute for Biotechnologie – VIB). Collen was CEO and Chairman of ThromboGenics from 1998 to 2008. In 2008 Patrick De Haes succeeded him as CEO.

Following a successful IPO in 2006 on the basis of the expanded R&D portfolio, the company nevertheless narrowed its scope to the clinical development of ocriplasmin, a truncated form of plasmin for ophthalmology indications, culminating in the completion of a pivotal phase III program in 2010.[61][62] Following FDA approval, ThromboGenics launched ocriplasmin, marketed as Jetrea®, in the US on 14 January 2013 for the treatment of symptomatic vitreomacular adhesion (VMA).[63] Three months later, the European Commission approved ocriplasmin,[64] a decision that paved the way for Alcon to launch the product under licence of ThromboGenics. Disappointed by the, in his opinion, inadequate strategic and commercial governance of the company, Collen stepped down as Chairman and member of the board in December 2013.[65]

Fund+

In May 2015 Désiré Collen, through the private foundation Désiré Collen Stichting and the non-profit organisation Life Sciences Research Partners, founded Fund+ of which he was Chairman until 2019 and is the Honorary Chairman since 2019. Fund+ will invest in innovative life sciences companies seeking series A or B financing and with a Proof of Concept in therapeutics, diagnostics or medical devices.[11] Fund+ aims at realizing an attractive financial return for its investors, as well as a societal return. Fund+ wants to contribute in a sustainable way to the improvement of the eco system for biotech companies. Therefore, its major geographical focus will be Belgium. Fund+ had raised over 200 Million euro of financing commitments. The intended investment size per company will be between 5 and 15 million euro spread over different milestones.

Awards and honours

Désiré Collen was awarded the Belgian Francqui Prize in Biological and Medical Sciences in 1984. He received the Louis-Jeantet Prize for Medicine (Fondation L. Jeantet, Geneva, Switzerland) in 1986, the Bristol-Myers Squibb Award for Cardiovascular Research (New York, NY, USA) jointly with Mark Verstraete in 1994, the Interbrew-Baillet Latour Health Prize (Belgium) jointly with Peter Carmeliet in 2005, the Harvard Leadership Prize by the Harvard Club of Belgium in 2007, the Insead Innovator Prize in 2009, the Robert P. Grant Medal from the International Society for Thrombosis and Haemostasis in 2011, the Lifetime Achievement Award of Belcham (New York, NY, USA) in 2013 and the Lifetime Achievement Award of Scrip (London, UK) in 2013.

He became Ereburger (Honorary Citizen) of his native town Sint-Truiden (Belgium) in 2013 and Alumnus of the Year 2014 of Alfagen KU Leuven. In 2013 his majesty King Albert II of Belgium awarded him the hereditary nobility status (personal title of Baron).

In addition he received honorary doctorates from Erasmus University, Rotterdam (The Netherlands) in 1988, Free University of Brussels (VUB), Brussels (Belgium) in 1994, University of Notre Dame, Notre Dame (IN, USA) in 1995 and Université de la Méditerranée, Marseille (France) in 1999.

Books

Collen's memoires (in Dutch) 'Een hart voor onderzoek en ondernemen' were published in 2009 by VandenBroele (ISBN 978-90-496-0056-3). Désiré Collen, biotechpionier (in Dutch) was published in 2018 by LannooCampus (ISBN 978-94-014-5353-0).

References

  1. ^ a b c d e f g h i Huybrechts, Paul; Van Wijck, Frieda (2020). Désiré Collen, Biotech Pioneer. Google Books. ISBN 978-1-64999-608-4.
  2. ^ Huybrechts, Paul; Van Wijck, Frieda (2018). Désiré Collen, Biotechpionier. Belgium: LannooCampus. ISBN 978-94-014-5353-0.
  3. ^ a b c Delude C. Clot-Busters !! - Discovery of thrombolitic therapy for treating heart attack and stroke. Breakthrough in Bioscience. FASEB 2004, 6.
  4. ^ a b c Lijnen R. Retirement of Désiré Collen. J Thromb Haemost. 2009 Jan;7(1):2–3. doi:10.1111/j.1538-7836.2008.03194.x PMID 18983506
  5. ^ Current contents, 31 Aug 1992, p.3
  6. ^ The top 100 Living Contributors to Biotechnology, http://www.goldenrice.org/PDFs/Top_100.pdf
  7. ^ Boyack KW, Klavans R, Sorensen AA, Ioannidis JP. A list of highly influential biomedical researchers, 1996–2011. Eur J Clin Invest. 2013 Dec;43(12):1339–65 doi:10.1111/eci.12171. Epub 2013 Oct 21. PMID 24134636.
  8. ^ "LSRP – Life Science Research Partners".
  9. ^ FDA Approves Ocriplasmin for Vitreomacular Adhesions. Medscape Medical News. 18 October 2012. http://www.medscape.com/viewarticle/772845
  10. ^ Prospero Ponce CM, Stevenson W, Gelman R, Agarwal DR, Christoforidis JB. Ocriplasmin: who is the best candidate? Clin Ophthalmol. 2016 Mar 17;10:485-95. doi:10.2147/OPTH.S97947. eCollection 2016. Review. PMID 27051270; PMC 4803238.
  11. ^ a b Fund+ Impacting Life Sciences. http://fundplus.be
  12. ^ Collen D, Vandereycken G, De Maeyer L. Influence of hydrostatic pressure on the reversible polymerization of fibrin monomers. Nature. 1970 Nov 14;228(5272):669-71. PMID 5529056.
  13. ^ Lord ST, Henschen-Edman A. Birger Blombäck (7 May 1926 – 2 October 2008). J Thromb Haemost. 2009 May;7(5):908-9. doi:10.1111/j.1538-7836.2009.03320.x. Epub 2009 Feb 13. PMID 19220733; PMC 2965830.
  14. ^ Wiman B, Collen D. Molecular mechanism of physiological fibrinolysis. Nature. 1978; 272: 549–50.
  15. ^ Collen D, Wiman B. Fast-acting plasmin inhibitor in human plasma. Blood. 1978; 51: 563–9. Review.
  16. ^ Collen D, Wiman B. The fast-acting plasmin inhibitor of human plasma: The Prix Servier Lecture 1978. In: 'Progress in Chemical Fibrinolysis and Thrombolysis, Vol. 4'. Ed.: J.F. Davidson. Churchill Livingstone, Edinburg, 1979; 11–19.
  17. ^ Collen D. On the regulation and control of fibrinolysis. Edward Kowalski Memorial Lecture. Thromb Haemost. 1980; 43: 77–89. Review.
  18. ^ Rijken DC and Collen D. Purification and characterization of the plasminogen activator secreted by human melanoma cells in culture. J Biol Chem. 1981; 256: 7035–41.
  19. ^ Collen D, Rijken DC, Van Damme J, Billiau A. Purification of human tissue-type plasminogen activator in centigram quantities from human melanoma cell culture fluid and its conditioning for use in vivo. Thromb Haemost. 1982; 48: 294–6.
  20. ^ Matsuo O, Rijken DC, Collen D. Thrombolysis by human tissue plasminogen activator and urokinase in rabbits with experimental pulmonary embolus. Nature. 1981; 291: 590–1.
  21. ^ Collen DJ, Rijken DC, Matsuo OM. Plasminogen activator and pharmaceutical composition having thrombolytic activity. US 4752603. http://www.google.com/patents/US4752603
  22. ^ Pennica D. et al. Cloning and expression of human tissue-type plasminogen activator cDNA in E. coli. Nature. 1983 Jan 20;301(5897):214-21.
  23. ^ Bergmann SR, Fox KA, Ter-Pogossian MM, Sobel BE, Collen D. Clot-selective coronary thrombolysis with tissue-type plasminogen activator. Science. 1983; 220: 1181–3.
  24. ^ Van de Werf F et al. Coronary thrombolysis with intravenously administered human tissue-type plasminogen activator produced by recombinant DNA technology. Circulation. 1984; 69: 605–10.
  25. ^ Gold HK et al. Coronary thrombolysis with recombinant human tissue-type plasminogen activator. Circulation. 1984; 70: 700- 7.
  26. ^ Weimar W, Stibbe J, van Seyen AJ, Billiau A, De Somer P, Collen D. Specific lysis of an iliofemoral thrombus by administration of extrinsic (tissue-type) plasminogen activator. Lancet. 1981; 2: 1018–20.
  27. ^ Van de Werf F et al. Coronary thrombolysis with tissue-type plasminogen activator in patients with evolving myocardial infarction. N Engl J Med. 1984; 310: 609–13.
  28. ^ Collen D et al. Coronary thrombolysis with recombinant human tissue-type plasminogen activator: a prospective, randomized, placebo-controlled trial. Circulation. 1984 Dec; 70: 1012–7.
  29. ^ The Thrombolysis in Myocardial Infarction (TIMI) trial. Phase I findings. TIMI Study Group. N Engl J Med. 1985; 312: 932–6.
  30. ^ Sheehan FH et al., The effect of intravenous thrombolytic therapy on left ventricular function: a report on tissue-type plasminogen activator and streptokinase from the Thrombolysis in Myocardial Infarction (TIMI Phase I) trial. Circulation. 1987; 75: 817–29.
  31. ^ Chesebro JH et al. Thrombolysis in Myocardial Infarction (TIMI) Trial, Phase I: A comparison between intravenous tissue plasminogen activator and intravenous streptokinase. Clinical findings through hospital discharge. Circulation. 1987; 76: 142–54.
  32. ^ Mueller HS, Rao AK, Forman SA. Thrombolysis in myocardial infarction (TIMI): comparative studies of coronary reperfusion and systemic fibrinogenolysis with two forms of recombinant tissue-type plasminogen activator. J Am Coll Cardiol. 1987; 10: 479–90.
  33. ^ Verstraete M et al. Double-blind randomised trial of intravenous tissue-type plasminogen activator versus placebo in acute myocardial infarction. Lancet. 1985; 2: 965–9.
  34. ^ Verstraete M et al. Randomised trial of intravenous recombinant tissue-type plasminogen activator versus intravenous streptokinase in acute myocardial infarction. Report from the European Cooperative Study Group for Recombinant Tissue- type Plasminogen Activator. Lancet. 1985; 1: 842–7.
  35. ^ Boffey, Philip M.; Times, Special To the New York (13 November 1987). "U.S. TO BACK GENE-ENGINEERED DRUG FOR CLOTTING". The New York Times. ISSN 0362-4331. Retrieved 3 March 2023.
  36. ^ Genentech Press Release. Licensing of Activase Marks New Era in Treating Heart Attacks. 13 November 1987. https://www.gene.com/media/press-releases/4271/1987-11-13/licensing-of-activase-marks-new-era-in-t
  37. ^ Marx J.L. Which clot-dissolving drug is best? Science. 1988; 242: 1505–6.
  38. ^ Collen D. Coronary thrombolysis: streptokinase or recombinant tissue-type plasminogen activator? Ann Intern Med. 1990; 112: 529–38.
  39. ^ Sobel BE, Collen D. After ISIS-3. Lancet. 1992; 339: 1225–6.
  40. ^ Sobel BE, Collen D. Questions unresolved by the Third International Study of Infarct Survival. Am J Cardiol. 1992; 70: 385–9.
  41. ^ An international randomized trial comparing four thrombolytic strategies for acute myocardial infarction. The GUSTO investigators. N Engl J Med. 1993; 329: 673–82.
  42. ^ The effects of tissue plasminogen activator, streptokinase, or both on coronary-artery patency, ventricular function, and survival after acute myocardial infarction. The GUSTO Angiographic Investigators. N Engl J Med. 1993; 329: 1615–22.
  43. ^ Sobel BE and Collen D. Controversy and clarification: preliminary results of the GUSTO trial. In: "Coronary thrombolysis in perspective", Eds. BE Sobel and D Collen, Marcel Dekker Inc, New York, N.Y. 1993, p. 303-316.
  44. ^ Keeley EC, Boura JA, Grines CL. Primary angioplasty versus intravenous thrombolytic therapy for acute myocardial infarction: a quantitative review of 23 randomised trials. Lancet. 2003; 361: 13–20. Review.
  45. ^ Van de Werf FJ, Topol EJ, Sobel BE. The impact of fibrinolytic therapy for ST-segment-elevation acute myocardial infarction. J Thromb Haemost 2009; 7: 14_20.
  46. ^ Tissue plasminogen activator for acute ischemic stroke. The National Institute of Neurological Disorders and Stroke rt-PA Stroke Study Group. N Engl J Med 1995; 333: 1581–7.
  47. ^ Albers GW, Amarenco P, Easton JD, Sacco RL, Teal P; American College of Chest Physicians. Antithrombotic and thrombolytic therapy for ischemic stroke: American College of Chest Physicians Evidence-Based Clinical Practice Guidelines (8thEdition). Chest. 2008; 133: 630S-69S.
  48. ^ Wan S, Quinlan DJ, Agnelli G, Eikelboom JW. Thrombolysis compared with heparin for the initial treatment of pulmonary embolism: a meta-analysis of the randomized controlled trials. Circulation. 2004; 110: 744–9.
  49. ^ Dong B, Jirong Y, Liu G, Wang Q, Wu T. Thrombolytic therapy for pulmonary embolism. Cochrane Database Syst Rev. 2006; 2: CD004437. Review.
  50. ^ Watson LI, Armon MP. Thrombolysis for acute deep vein thrombosis. Cochrane Database Syst Rev. 18; 4: CD002783. Review.
  51. ^ Bruen KJ, Ballard JR, Morris SE, Cochran A, Edelman LS, Saffle JR. Reduction of the incidence of amputation in frostbite injury with thrombolytic therapy. Arch Surg. 2007; 142: 546–51.
  52. ^ Lijnen HR, Van Hoef B, De Cock F, Okada K, Ueshima S, Matsuo O, Collen D. On the mechanism of fibrin-specific plasminogen activation by staphylokinase. J Biol Chem. 1991; 266: 11826-32.
  53. ^ Collen D, Van de Werf F. Coronary thrombolysis with recombinant staphylokinase in patients with evolving myocardial infarction. Circulation. 1993; 87: 1850–3.
  54. ^ Vanderschueren S, et al. A randomized trial of recombinant staphylokinase versus alteplase for coronary artery patency in acute myocardial infarction. The STAR Trial Group. Circulation. 1995; 92: 2044–9.
  55. ^ Carmeliet P, et al. Abnormal blood vessel development and lethality in embryos lacking a single VEGF allele. Nature. 1996; 380: 435–9.
  56. ^ Carmeliet P, et al., Targeted deficiency or cytosolic truncation of the VE-cadherin gene in mice impairs VEGFmediated endothelial survival and angiogenesis. Cell. 1999; 98: 147–57.
  57. ^ Carmeliet P, et al. Synergism between vascular endothelial growth factor and placental growth factor contributes to angiogenesis and plasma extravasation in pathological conditions. Nat Med. 2001; 7: 575–83.
  58. ^ Fischer C, Jonckx B, Mazzone M, Zacchigna S, Loges S, Pattarini L, Chorianopoulos E, Liesenborghs L, Koch M, De Mol M, Autiero M, Wyns S, Plaisance S, Moons L, van Rooijen N, Giacca M, Stassen JM, Dewerchin M, Collen D, Carmeliet P. Anti-PlGF inhibits growth of VEGF(R)-inhibitor-resistant tumors without affecting healthy vessels. Cell. 2007 Nov 2;131(3):463-75.
  59. ^ Oosthuyse B. et al. Deletion of the hypoxia-response element in the vascular endothelial growth factor promoter causes motor neuron degeneration. Nat Genet. 2001; 28: 131-8.
  60. ^ Lambrechts D. et al. VEGF is a modifier of amyotrophic lateral sclerosis in mice and humans and protects motoneurons against ischemic death. Nat Genet. 2003; 34: 383-94.
  61. ^ Stalmans P, Benz MS, Gandorfer A, Kampik A, Girach A, Pakola S, Haller JA; MIVI-TRUST Study Group. Enzymatic vitreolysis with ocriplasmin for vitreomacular traction and macular holes. N Engl J Med. 2012 Aug 16;367(7):606-15. doi:10.1056/NEJMoa1110823. PMID 22894573.
  62. ^ Varma R, Haller JA, Kaiser PK. Improvement in Patient-Reported Visual Function After Ocriplasmin for Vitreomacular Adhesion: Results of the Microplasmin for Intravitreous Injection-Traction Release Without Surgical Treatment (MIVI-TRUST) Trials. JAMA Ophthalmol. 2015 Sep;133(9):997–1004. doi:10.1001/jamaophthalmol.2015.1746. PMID 26068086.
  63. ^ "Drug Approval Package: Jetrea (ocriplasmin) BLA 125422". www.accessdata.fda.gov.
  64. ^ "Jetrea | European Medicines Agency".
  65. ^ ThromboGenics' Founder Prof Désiré Collen Retiring as Chairman. ThromboGenics Press Release. 6 December 2013. http://www.thrombogenics.com/sites/default/files/upload/news/THR_13_30DesireChairmanfinal.pdf

External links

  • Official website (in Dutch and English)


March 10, 2023
désiré, collen, désiré, baron, collen, born, sint, truiden, belgium, june, 1943, belgian, physician, chemist, biotechnology, entrepreneur, life, science, investor, made, several, discoveries, thrombosis, haemostasis, vascular, biology, many, which, serendipity. Desire Baron Collen born in Sint Truiden Belgium 21 June 1943 is a Belgian physician chemist biotechnology entrepreneur and life science investor 1 2 He made several discoveries in thrombosis haemostasis and vascular biology in many of which serendipity played a significant role His main achievement has been his role in the development of tissue type plasminogen activator t PA from a laboratory concept to a life saving drug for dissolving blood clots causing acute myocardial infarction or acute ischemic stroke Recombinant t PA was produced and marketed by Genentech Inc as Activase and by Boehringer Ingelheim GmbH as Actilyse and is considered biotechnology s first life saving drug 3 Desire CollenDesire Collen in 2012BornDesire Collen 1943 06 21 21 June 1943Sint Truiden BelgiumNationalityBelgianSpouseLouisa Reniers m 1966 wbr ChildrenAn Collen Peter Collen Christine CollenScientific careerFieldsThrombosis Thrombolysis Biomedical research Translational Research on Drug Development Private equity funding of Life sciences companiesIn 2008 Collen reached the mandatory retirement age of 65 years as Professor of the Faculty of Medicine at KU Leuven Belgium where he served as Director of the Center for Thrombosis and Vascular Research now Center for Molecular and Vascular Biology and the VIB Department for Transgene Technology and Gene Therapy now VIB KU Leuven Center for Cancer Biology 4 He authored and co authored over 650 research papers in peer reviewed international journals which have been cited over 70 000 times and 39 US Patents He ranked among the 100 most cited scientific authors of the 1980s listed by Current Contents 5 and among the top 100 living contributors to biotechnology in polls conducted by Reed Elsevier in 2005 6 In 2012 SciTech Strategies placed him among the top 400 most influential scientists in biomedical research for the period 1996 2011 7 In 1988 Desire Collen founded the D Collen Research Foundation vzw 8 a not for profit organization with the mission to invest the mayor part of the royalties earned from Genentech on the t PA patent in scientific research The Foundation was renamed in 2007 into Life Sciences Research Partners vzw of which Collen remained the Statutory Chairman until 2019 In 1991 he spun out the company Thromb X nv from the KU Leuven in Belgium The primary focus of Thromb X was in the cardiovascular space with an initial effort to develop staphylokinase as a more affordable thrombolytic medicine compared to t PA poor man s t PA With the constitution of ThromboGenics Ltd in Ireland in 1998 the company expanded its R amp D scope to include cardiovascular oncology and ophthalmology programs ThromboGenics developed ocriplasmin a truncated form of plasmin for the treatment of vitreomacular traction in the eye 9 10 Disappointed by the in his opinion inadequate strategic and commercial governance of the company Collen left ThromboGenics as Chairman and board member in December 2013 With the help of Chris Buyse his CFO and companion de route during their 7 years at ThromboGenics he co financed the start of Fund an ever green investment fund that currently manages over 200 million euro Fund is a private Fund for long term equity investment in innovative life sciences companies with a strong patient centered approach aiming at both a financial return and a tangible societal impact 11 King Albert II of Belgium awarded Desire Collen hereditary nobility with the personal rank of Baron in 2013 He was also recipient of the Belgian Francqui Prize in 1984 Louis Jeantet Prize for Medicine in 1986 Bristol Myers Squibb Award for Cardiovascular Research in 1994 Interbrew Baillet Latour Health Prize in 2005 Insead Innovator Prize in 2009 Robert P Grant Medal of the International Society for Thrombosis and Haemostasis in 2011 Lifetime Achievement Award of the Belgian American Chamber of Commerce BelCham in 2013 and Lifetime Achievement Award of Scrip in 2013 He received honorary doctorates from Erasmus University Rotterdam the Netherlands in 1988 Free University of Brussels VUB Brussels Belgium in 1994 University of Notre Dame Notre Dame IN United States in 1995 and Universite de la Mediterranee Marseille France in 1999 Contents 1 Education 2 Career and research 2 1 Research output 2 2 The cloning of t PA and preclinical research 2 3 Clinical studies with t PA 2 4 A lifesaving drug 2 5 Staphylokinase poor man s t PA 2 6 VIB Department for Transgene Technology and Gene Therapy 2 7 Academic Appointments 2 8 D Collen Research Foundation 2 9 Thromb X and ThromboGenics 2 10 Fund 3 Awards and honours 4 Books 5 References 6 External linksEducation EditDesire Collen born on 21 June 1943 in the Flemish town of Sint Truiden as the first of two children of Frans Collen and Maria Hoebrechs started his studies in medicine at the University of Leuven KU Leuven in 1961 Since his third year of the seven year curriculum he combined his studies with research first in the laboratory of Belgian physiologist Joseph P Bouckaert and from the next year on in the Laboratory for Blood Coagulation under the direction of Marc Verstraete Under the guidance of young gastroenterologist Guido Tytgat and biochemist Rene De Vreker he studied the rate at which the coagulation proteins fibrinogen and plasminogen are cleared from the circulation This early experience with biochemical lab work inspired Desire Collen to become a researcher rather than a practicing general physician or medical specialist Realising his knowledge in chemistry was inadequate he combined his education in medicine with academic studies in chemistry He graduated from the KU Leuven as Doctor in Medicine in 1968 and as Master Licentiaat in Chemistry in 1969 Mid 1968 Desire Collen became research assistant of the Belgian National Fund for Scientific Research in the Laboratory of Marc Verstraete He worked simultaneously in the Department of Physical Chemistry under the supervision of Leo C M De Maeyer He started a research project on factors influencing the polymerization of fibrinogen to fibrin Only months later he published his first although a very short one scientific paper in Nature 12 In 1971 1972 he went as an Associate Research Scientist of the National Institutes of Health United States to the New York University Medical Center to work with Alan Johnson In 1972 1973 he worked in the laboratory of Birger Blomback 13 at Karolinska Institutet in Stockholm Sweden as a NATO Research Fellow After obtaining his PhD in Chemistry at the KU Leuven in 1974 and concluding his mandatory military service Desire Collen was appointed in 1976 as Lecturer Docent in the Faculty of Medicine at KU Leuven and as Adjunct Head of Clinic in the Section Bleeding and Vascular Diseases in the Department of Internal Medicine at the University Hospital Leuven Career and research EditResearch output Edit The scientific output of Desire Collen between 1968 and 2011 consists of 667 peer reviewed research papers in international journals 172 review articles and 39 issued US patents His publications have been cited over 70 000 times in the scientific literature 4 He made seminal contributions to the fields of thrombosis haemostasis and vascular biology 4 His pivotal achievement has been the development of tissue type plasminogen activator t PA from a laboratory concept to the first life saving biotech drug Recombinant t PA has been primarily used for dissolving blood clots causing acute myocardial infarction or acute ischemic stroke 3 The cloning of t PA and preclinical research Edit T PA is a protease that converts inactive plasminogen into active plasmin which in turn cleaves fibrin the main component of blood clots Upon cleavage of the long fibrin strands by plasmin the clot falls apart and dissolves Between August 1977 and September 1978 Desire Collen and Bjorn Wiman elucidated that the conversion of plasminogen to plasmin takes place when both proteins are bound to fibrin in the blood clot 14 15 16 This molecular model for the regulation and control of fibrinolysis was presented in 1979 during an invited plenary lecture Edward Kowalski Memorial Lecture at the VIIth International Congress on Thrombosis and Haemostasis in London The written report of this presentation has been cited over 1200 times in the scientific literature 17 Collen collaborated in the same period with Professor Alfons Billiau of the Rega Institute for Medical Research in Leuven Belgium on the inhibition of plasminogen activators secreted by malignant cells in culture hypothesizing that synthetic inhibitors might suppress the malignant phenotype of these cells In order to have a source for these malignant plasminogen activators the Bowes Melanoma Cell line was obtained from Professor Daniel Rifkin of the Rockefeller University New York City at the end of 1978 It quickly appeared that this cell line produced large amounts of a plasminogen activator with a molecular weight of 70 000 dalton and a high affinity for fibrin characteristic of human tissue type plasminogen activator t PA whereas most other malignant cells produced a plasminogen activator with a molecular weight of 54 000 dalton without affinity for fibrin which is characteristic of pro urokinase This game changing although trivial serendipitous observation made on 9 February 1979 1 was to change the course of thrombolytic therapy In order to produce sufficient amounts of t PA for further biochemical and preclinical studies post doctoral fellow Dingeman Dick Rijken succeeded in isolating sufficient amounts of pure and homogeneous t PA from conditioned culture medium from the Bowes Melanoma Cell line 18 19 This purified protein was used by post doctoral fellow Osamu Matsuo to evaluate the thrombolytic potential of t PA in rabbits suffering from an experimental pulmonary embolus 20 The research led to a key patent US4752603 entitled Plasminogen activator and pharmaceutical composition having thrombolytic activity 21 which was first submitted in the Netherlands on 11 June 1980 On 12 June 1980 one day after the submission of the patent application Collen presented the results at the Fifth Congress on Fibrinolysis in Malmo Sweden in the presence of Diane Pennica a young scientist from biotech company Genentech Inc based in South San Francisco Collen KU Leuven and Genentech agreed to collaborate on the production of a recombinant version of t PA rt PA embarking on a new model for drug development academic and biotech collaboration today routine but at that time a new modus operandi 1 Within 18 months Pennica and her team had cloned the cDNA complementary DNA of human t PA messenger RNA and was producing rt PA in cultures of Chinese hamster ovary cells 22 The therapeutic potential of rt PA and its functional identity with natural t PA was proven in a collaboration with Steven R Bergman and Burton Sobel Washington University School of Medicine Saint Louis Frans Van de Werf KU Leuven and Herman Chip Gold and Tsunehori Yasuda Massachusetts General Hospital Harvard Medical School Boston using canine models of coronary thrombosis 23 24 25 Clinical studies with t PA Edit Also in 1981 following a discussion with Alfons Billiau at a scientific congress in Amsterdam Dutch nephrologist Willem Weimar of the Dijkzigt Hospital in Rotterdam treated for the first time a patient with t PA purified from the Bowes Melanoma Cell line The patient a 29 year old lady was suffering from a renal transplant vein thrombosis and was successfully treated resulting in a decennia long survival 26 Cardiologists Frans Van de Werf and Burton Sobel tested t PA in 1983 in a pilot clinical study on patients with acute myocardial infarction 27 Also in 1983 the first prospective randomized and placebo controlled trial of recombinant t PA took place in three US hospitals 28 The subsequent NIH Thrombolysis in Acute Myocardial Infarction TIMI trials led by Eugene Braunwald Brigham and Women s Hospital Harvard School of Medicine Boston 29 30 31 32 and the European Cooperative Study Group Trials led by Marc Verstraete KU Leuven 33 34 culminated in the final approval of rt PA as thrombolytic agent by the FDA on 13 November 1987 35 Genentech immediately started to market the drug in the US under the brand name Activase 36 while Boehringer Ingelheim would distribute the drug in the rest of the world except Japan as Actilyse A lifesaving drug Edit The controversy over whether the more expensive rt PA was clinically superior over streptokinase as a thrombolytic agent climaxed in the scientific press between 1988 and 1992 37 38 39 40 To end this controversy the GUSTO trial Global Utilization of Streptokinase and t PA for Occluded Coronary Arteries was set up a head to head comparison between rt PA and streptokinase In the GUSTO trial 41 021 heart attack patients were treated in 1 081 hospitals in 15 countries Cardiologist Eric Topol of the Cleveland Clinic USA cardiologist statistician Robert Califf of Duke University Medical Center USA and David Stump of Genentech coordinated the trial In absolute figures the 30 day mortality rate in the rt PA group was 1 lower or in relative figures 14 compared to the mortality in the streptokinase group 41 42 43 After the GUSTO studies rt PA became the thrombolytic drug of choice for most of the cardiologists in the Western world and would save the lives of many tens of thousands of heart attack patients 3 Nowadays cardiologists agree that timely performed percutaneous coronary intervention PCI also known as angioplasty and stenting is the preferred strategy to treat acute myocardial infarction instead of thrombolysis PCI is associated with less mortality on the short term 7 versus 9 for thrombolysis a lower risk of a recurrent infarct 3 versus 7 and a lower frequency of cerebral hemorrhage 1 versus 2 Also over a longer period of time PCI leads to a lower mortality rate 44 However because access to invasive facilities is limited in many countries thrombolytic therapy is still employed in many centers worldwide for treating acute myocardial infarction 45 Moreover rt PA based thrombolysis still is an important strategy to treat ischemic stroke 46 47 and to a lesser extent pulmonary embolism 48 49 and deep vein thrombosis 50 it has even been used to restore the blood flow in occluded central venous access ports and in the frozen limbs of mountaineers resulting in a spectacular decrease in the amputation rate 51 Staphylokinase poor man s t PA Edit On many occasions Desire Collen expressed his frustration that the lives of many more people could have been saved had rt PA been more readily available also to people who were not living in the affluent western world 1 Therefore he invested part of Genentech s t PA royalty stream in the search for a t PA for the poor In the early 1990s together with Roger Lijnen KU Leuven and Osamu Matsuo Kindai University Osaka Japan Collen started to evaluate whether staphylokinase STAR a bacterial profibrinolytic agent with high fibrin specificity could be a valid alternative for rt PA in less wealthy territories 52 By setting up spin off company Thromb X Collen had the clear objective to further develop staphylokinase through the preclinical and clinical research phases up to the market introduction Although wild type staphylokinase and variants with reduced immunogenicity and preserved lytic potency have been tested with success in humans 53 54 its further development came to an unfortunate standstill because of the prohibitive expense of a GUSTO like clinical trial with a mortality end point that had become the standard in the West Not even licensing out the further clinical development production and commercialization of staphylokinase to companies in developing countries where for most people rt PA is hardly available could save this project VIB Department for Transgene Technology and Gene Therapy Edit With the constitution of the Flemish Institute for Biotechnology Vlaams Instituut voor Biotechnologie VIB Collen was able to extend the capacity of his Leuven based academic research laboratories He became Director of the VIB Department for Transgene Technology and Gene Therapy now VIB KU Leuven Center for Cancer Biology based on the Gasthuisberg Campus of the KU Leuven Together with Professor Peter Carmeliet and colleagues landmark contributions were made to the fields of vascular biology tumor biology and neurobiology e g between 1995 and 2008 the Department conducted breakthrough research on the role of vascular endothelial growth factor VEGF and placental growth factor PlGF in angiogenesis 55 56 57 cancer 58 and amyotrophic lateral sclerosis ALS 59 60 Academic Appointments Edit From 1981 to 2008 Desire Collen was Professor at the Faculty of Medicine of the KU Leuven in Belgium Between 1998 and 2002 he temporarily resigned to develop ThromboGenics but remained Extraordinary Professor Buitengewoon hoogleraar In 2008 he reached the age of mandatory retirement at Belgian Universities 1 Desire Collen was also Professor of Biochemistry and Medicine in the Department of Kenneth G Mann at the University of Vermont College of Medicine Burlington Vermont USA 1984 2005 Visiting Professor of Medicine in the group of Herman Chip Gold of Massachusetts General Hospital at Harvard School of Medicine Boston MA USA 1987 1994 Consultant in Medicine at the Massachusetts General Hospital Boston MA USA 1987 2005 and Visiting Professor at the Division of Surgery and Anaesthesia of Kevin Burnand at United Medical and Dental Schools of Guy s and St Thomas Hospitals London UK 1999 2002 1 Desire Collen was Director of the Center for Molecular and Vascular Biology at the Faculty of Medicine of the KU Leuven from 1994 to 2008 Division Head of the Protein Research Division of Leuven Research and Development vzw of the KU Leuven from 1976 to 1998 and Director of the Department for Transgene Technology and Gene Therapy of the Vlaams Instituut voor Biotechnologie VIB from 1994 to 2008 1 D Collen Research Foundation Edit On 2 July 1988 the D Collen Research Foundation was constituted by Desire Collen Roger Dillemans Roger Dillemans Rector of the KU Leuven Karel Tavernier General Manager of the KU Leuven Jacques Vander Eecken Chairman of Leuven Research and Development and Lawrence Fouraker former Dean of the Harvard Business School representing the Harvard Medical School 1 The mission of the Foundation was to canalize the major part of the income from the rt PA royalties towards the execution promotion and support of scientific research in general and biomedical and biotechnological research in particular by making available research grants research positions travel bursaries by organizing scientific congresses and symposia providing financial support for publications and all related activities that support the advancement of science With the support of the Foundation over 100 young researchers were able to obtain further specialisation abroad numerous congresses and symposia and two academic chairs were sponsored the 9th floor of the research building on the Gasthuisberg Research Campus and a guesthouse on the Groot Begijnhof campus were built with financial support of the Foundation These buildings housed for many years the Center for Thrombosis and Vascular Research and the VIB Department for Transgene Technology and Gene Therapy and their postdoctoral researchers respectively 1 In 2007 the D Collen Research Foundation was renamed to Life Sciences Research Partners vzw It continued the activities of the D Collen Research Foundation but also started to invest in life science companies such as Celyad Ogeda Amakem Bone Therapeutics and others Thromb X and ThromboGenics Edit In 1991 Desire Collen spun out Thromb X nv from the KU Leuven with an initial mission to develop staphylokinase as an equally effective but less expensive successor of rt PA With the foundation of ThromboGenics Ltd in Ireland in 1998 the Company expanded its R amp D scope to include various cardiovascular oncology and ophthalmology programs in licensed from the KU Leuven and the Vlaams Instituut voor Biotechnologie Flemish Institute for Biotechnologie VIB Collen was CEO and Chairman of ThromboGenics from 1998 to 2008 In 2008 Patrick De Haes succeeded him as CEO Following a successful IPO in 2006 on the basis of the expanded R amp D portfolio the company nevertheless narrowed its scope to the clinical development of ocriplasmin a truncated form of plasmin for ophthalmology indications culminating in the completion of a pivotal phase III program in 2010 61 62 Following FDA approval ThromboGenics launched ocriplasmin marketed as Jetrea in the US on 14 January 2013 for the treatment of symptomatic vitreomacular adhesion VMA 63 Three months later the European Commission approved ocriplasmin 64 a decision that paved the way for Alcon to launch the product under licence of ThromboGenics Disappointed by the in his opinion inadequate strategic and commercial governance of the company Collen stepped down as Chairman and member of the board in December 2013 65 Fund Edit In May 2015 Desire Collen through the private foundation Desire Collen Stichting and the non profit organisation Life Sciences Research Partners founded Fund of which he was Chairman until 2019 and is the Honorary Chairman since 2019 Fund will invest in innovative life sciences companies seeking series A or B financing and with a Proof of Concept in therapeutics diagnostics or medical devices 11 Fund aims at realizing an attractive financial return for its investors as well as a societal return Fund wants to contribute in a sustainable way to the improvement of the eco system for biotech companies Therefore its major geographical focus will be Belgium Fund had raised over 200 Million euro of financing commitments The intended investment size per company will be between 5 and 15 million euro spread over different milestones Awards and honours EditDesire Collen was awarded the Belgian Francqui Prize in Biological and Medical Sciences in 1984 He received the Louis Jeantet Prize for Medicine Fondation L Jeantet Geneva Switzerland in 1986 the Bristol Myers Squibb Award for Cardiovascular Research New York NY USA jointly with Mark Verstraete in 1994 the Interbrew Baillet Latour Health Prize Belgium jointly with Peter Carmeliet in 2005 the Harvard Leadership Prize by the Harvard Club of Belgium in 2007 the Insead Innovator Prize in 2009 the Robert P Grant Medal from the International Society for Thrombosis and Haemostasis in 2011 the Lifetime Achievement Award of Belcham New York NY USA in 2013 and the Lifetime Achievement Award of Scrip London UK in 2013 He became Ereburger Honorary Citizen of his native town Sint Truiden Belgium in 2013 and Alumnus of the Year 2014 of Alfagen KU Leuven In 2013 his majesty King Albert II of Belgium awarded him the hereditary nobility status personal title of Baron In addition he received honorary doctorates from Erasmus University Rotterdam The Netherlands in 1988 Free University of Brussels VUB Brussels Belgium in 1994 University of Notre Dame Notre Dame IN USA in 1995 and Universite de la Mediterranee Marseille France in 1999 Books EditCollen s memoires in Dutch Een hart voor onderzoek en ondernemen were published in 2009 by VandenBroele ISBN 978 90 496 0056 3 Desire Collen biotechpionier in Dutch was published in 2018 by LannooCampus ISBN 978 94 014 5353 0 References Edit a b c d e f g h i Huybrechts Paul Van Wijck Frieda 2020 Desire Collen Biotech Pioneer Google Books ISBN 978 1 64999 608 4 Huybrechts Paul Van Wijck Frieda 2018 Desire Collen Biotechpionier Belgium LannooCampus ISBN 978 94 014 5353 0 a b c Delude C Clot Busters Discovery of thrombolitic therapy for treating heart attack and stroke Breakthrough in Bioscience FASEB 2004 6 a b c Lijnen R Retirement of Desire Collen J Thromb Haemost 2009 Jan 7 1 2 3 doi 10 1111 j 1538 7836 2008 03194 x PMID 18983506 Current contents 31 Aug 1992 p 3 The top 100 Living Contributors to Biotechnology http www goldenrice org PDFs Top 100 pdf Boyack KW Klavans R Sorensen AA Ioannidis JP A list of highly influential biomedical researchers 1996 2011 Eur J Clin Invest 2013 Dec 43 12 1339 65 doi 10 1111 eci 12171 Epub 2013 Oct 21 PMID 24134636 LSRP Life Science Research Partners FDA Approves Ocriplasmin for Vitreomacular Adhesions Medscape Medical News 18 October 2012 http www medscape com viewarticle 772845 Prospero Ponce CM Stevenson W Gelman R Agarwal DR Christoforidis JB Ocriplasmin who is the best candidate Clin Ophthalmol 2016 Mar 17 10 485 95 doi 10 2147 OPTH S97947 eCollection 2016 Review PMID 27051270 PMC 4803238 a b Fund Impacting Life Sciences http fundplus be Collen D Vandereycken G De Maeyer L Influence of hydrostatic pressure on the reversible polymerization of fibrin monomers Nature 1970 Nov 14 228 5272 669 71 PMID 5529056 Lord ST Henschen Edman A Birger Blomback 7 May 1926 2 October 2008 J Thromb Haemost 2009 May 7 5 908 9 doi 10 1111 j 1538 7836 2009 03320 x Epub 2009 Feb 13 PMID 19220733 PMC 2965830 Wiman B Collen D Molecular mechanism of physiological fibrinolysis Nature 1978 272 549 50 Collen D Wiman B Fast acting plasmin inhibitor in human plasma Blood 1978 51 563 9 Review Collen D Wiman B The fast acting plasmin inhibitor of human plasma The Prix Servier Lecture 1978 In Progress in Chemical Fibrinolysis and Thrombolysis Vol 4 Ed J F Davidson Churchill Livingstone Edinburg 1979 11 19 Collen D On the regulation and control of fibrinolysis Edward Kowalski Memorial Lecture Thromb Haemost 1980 43 77 89 Review Rijken DC and Collen D Purification and characterization of the plasminogen activator secreted by human melanoma cells in culture J Biol Chem 1981 256 7035 41 Collen D Rijken DC Van Damme J Billiau A Purification of human tissue type plasminogen activator in centigram quantities from human melanoma cell culture fluid and its conditioning for use in vivo Thromb Haemost 1982 48 294 6 Matsuo O Rijken DC Collen D Thrombolysis by human tissue plasminogen activator and urokinase in rabbits with experimental pulmonary embolus Nature 1981 291 590 1 Collen DJ Rijken DC Matsuo OM Plasminogen activator and pharmaceutical composition having thrombolytic activity US 4752603 http www google com patents US4752603 Pennica D et al Cloning and expression of human tissue type plasminogen activator cDNA in E coli Nature 1983 Jan 20 301 5897 214 21 Bergmann SR Fox KA Ter Pogossian MM Sobel BE Collen D Clot selective coronary thrombolysis with tissue type plasminogen activator Science 1983 220 1181 3 Van de Werf F et al Coronary thrombolysis with intravenously administered human tissue type plasminogen activator produced by recombinant DNA technology Circulation 1984 69 605 10 Gold HK et al Coronary thrombolysis with recombinant human tissue type plasminogen activator Circulation 1984 70 700 7 Weimar W Stibbe J van Seyen AJ Billiau A De Somer P Collen D Specific lysis of an iliofemoral thrombus by administration of extrinsic tissue type plasminogen activator Lancet 1981 2 1018 20 Van de Werf F et al Coronary thrombolysis with tissue type plasminogen activator in patients with evolving myocardial infarction N Engl J Med 1984 310 609 13 Collen D et al Coronary thrombolysis with recombinant human tissue type plasminogen activator a prospective randomized placebo controlled trial Circulation 1984 Dec 70 1012 7 The Thrombolysis in Myocardial Infarction TIMI trial Phase I findings TIMI Study Group N Engl J Med 1985 312 932 6 Sheehan FH et al The effect of intravenous thrombolytic therapy on left ventricular function a report on tissue type plasminogen activator and streptokinase from the Thrombolysis in Myocardial Infarction TIMI Phase I trial Circulation 1987 75 817 29 Chesebro JH et al Thrombolysis in Myocardial Infarction TIMI Trial Phase I A comparison between intravenous tissue plasminogen activator and intravenous streptokinase Clinical findings through hospital discharge Circulation 1987 76 142 54 Mueller HS Rao AK Forman SA Thrombolysis in myocardial infarction TIMI comparative studies of coronary reperfusion and systemic fibrinogenolysis with two forms of recombinant tissue type plasminogen activator J Am Coll Cardiol 1987 10 479 90 Verstraete M et al Double blind randomised trial of intravenous tissue type plasminogen activator versus placebo in acute myocardial infarction Lancet 1985 2 965 9 Verstraete M et al Randomised trial of intravenous recombinant tissue type plasminogen activator versus intravenous streptokinase in acute myocardial infarction Report from the European Cooperative Study Group for Recombinant Tissue type Plasminogen Activator Lancet 1985 1 842 7 Boffey Philip M Times Special To the New York 13 November 1987 U S TO BACK GENE ENGINEERED DRUG FOR CLOTTING The New York Times ISSN 0362 4331 Retrieved 3 March 2023 Genentech Press Release Licensing of Activase Marks New Era in Treating Heart Attacks 13 November 1987 https www gene com media press releases 4271 1987 11 13 licensing of activase marks new era in t Marx J L Which clot dissolving drug is best Science 1988 242 1505 6 Collen D Coronary thrombolysis streptokinase or recombinant tissue type plasminogen activator Ann Intern Med 1990 112 529 38 Sobel BE Collen D After ISIS 3 Lancet 1992 339 1225 6 Sobel BE Collen D Questions unresolved by the Third International Study of Infarct Survival Am J Cardiol 1992 70 385 9 An international randomized trial comparing four thrombolytic strategies for acute myocardial infarction The GUSTO investigators N Engl J Med 1993 329 673 82 The effects of tissue plasminogen activator streptokinase or both on coronary artery patency ventricular function and survival after acute myocardial infarction The GUSTO Angiographic Investigators N Engl J Med 1993 329 1615 22 Sobel BE and Collen D Controversy and clarification preliminary results of the GUSTO trial In Coronary thrombolysis in perspective Eds BE Sobel and D Collen Marcel Dekker Inc New York N Y 1993 p 303 316 Keeley EC Boura JA Grines CL Primary angioplasty versus intravenous thrombolytic therapy for acute myocardial infarction a quantitative review of 23 randomised trials Lancet 2003 361 13 20 Review Van de Werf FJ Topol EJ Sobel BE The impact of fibrinolytic therapy for ST segment elevation acute myocardial infarction J Thromb Haemost 2009 7 14 20 Tissue plasminogen activator for acute ischemic stroke The National Institute of Neurological Disorders and Stroke rt PA Stroke Study Group N Engl J Med 1995 333 1581 7 Albers GW Amarenco P Easton JD Sacco RL Teal P American College of Chest Physicians Antithrombotic and thrombolytic therapy for ischemic stroke American College of Chest Physicians Evidence Based Clinical Practice Guidelines 8thEdition Chest 2008 133 630S 69S Wan S Quinlan DJ Agnelli G Eikelboom JW Thrombolysis compared with heparin for the initial treatment of pulmonary embolism a meta analysis of the randomized controlled trials Circulation 2004 110 744 9 Dong B Jirong Y Liu G Wang Q Wu T Thrombolytic therapy for pulmonary embolism Cochrane Database Syst Rev 2006 2 CD004437 Review Watson LI Armon MP Thrombolysis for acute deep vein thrombosis Cochrane Database Syst Rev 18 4 CD002783 Review Bruen KJ Ballard JR Morris SE Cochran A Edelman LS Saffle JR Reduction of the incidence of amputation in frostbite injury with thrombolytic therapy Arch Surg 2007 142 546 51 Lijnen HR Van Hoef B De Cock F Okada K Ueshima S Matsuo O Collen D On the mechanism of fibrin specific plasminogen activation by staphylokinase J Biol Chem 1991 266 11826 32 Collen D Van de Werf F Coronary thrombolysis with recombinant staphylokinase in patients with evolving myocardial infarction Circulation 1993 87 1850 3 Vanderschueren S et al A randomized trial of recombinant staphylokinase versus alteplase for coronary artery patency in acute myocardial infarction The STAR Trial Group Circulation 1995 92 2044 9 Carmeliet P et al Abnormal blood vessel development and lethality in embryos lacking a single VEGF allele Nature 1996 380 435 9 Carmeliet P et al Targeted deficiency or cytosolic truncation of the VE cadherin gene in mice impairs VEGFmediated endothelial survival and angiogenesis Cell 1999 98 147 57 Carmeliet P et al Synergism between vascular endothelial growth factor and placental growth factor contributes to angiogenesis and plasma extravasation in pathological conditions Nat Med 2001 7 575 83 Fischer C Jonckx B Mazzone M Zacchigna S Loges S Pattarini L Chorianopoulos E Liesenborghs L Koch M De Mol M Autiero M Wyns S Plaisance S Moons L van Rooijen N Giacca M Stassen JM Dewerchin M Collen D Carmeliet P Anti PlGF inhibits growth of VEGF R inhibitor resistant tumors without affecting healthy vessels Cell 2007 Nov 2 131 3 463 75 Oosthuyse B et al Deletion of the hypoxia response element in the vascular endothelial growth factor promoter causes motor neuron degeneration Nat Genet 2001 28 131 8 Lambrechts D et al VEGF is a modifier of amyotrophic lateral sclerosis in mice and humans and protects motoneurons against ischemic death Nat Genet 2003 34 383 94 Stalmans P Benz MS Gandorfer A Kampik A Girach A Pakola S Haller JA MIVI TRUST Study Group Enzymatic vitreolysis with ocriplasmin for vitreomacular traction and macular holes N Engl J Med 2012 Aug 16 367 7 606 15 doi 10 1056 NEJMoa1110823 PMID 22894573 Varma R Haller JA Kaiser PK Improvement in Patient Reported Visual Function After Ocriplasmin for Vitreomacular Adhesion Results of the Microplasmin for Intravitreous Injection Traction Release Without Surgical Treatment MIVI TRUST Trials JAMA Ophthalmol 2015 Sep 133 9 997 1004 doi 10 1001 jamaophthalmol 2015 1746 PMID 26068086 Drug Approval Package Jetrea ocriplasmin BLA 125422 www accessdata fda gov Jetrea European Medicines Agency ThromboGenics Founder Prof Desire Collen Retiring as Chairman ThromboGenics Press Release 6 December 2013 http www thrombogenics com sites default files upload news THR 13 30DesireChairmanfinal pdfExternal links EditOfficial website in Dutch and English Retrieved from https en wikipedia org w index php title Desire Collen amp oldid 1142607268, wikipedia, wiki, book, books, library,

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