2019 APM Winter Meeting Agenda Page 6 Liberty AB, Headhouse Tower Plenary Session VI Marriott Lessons for Leadership from High Profile Cases of Misbehavior

Total Page:16

File Type:pdf, Size:1020Kb

2019 APM Winter Meeting Agenda Page 6 Liberty AB, Headhouse Tower Plenary Session VI Marriott Lessons for Leadership from High Profile Cases of Misbehavior 2019 APM Meeting at Academic Internal Medicine Week 2019 April 14-16, 2019 Philadelphia Marriott Downtown and Pennsylvania Convention Center Philadelphia, PA AGENDA As of March 25, 2019 Sunday, April 14, 2019 6:30 a.m. to 7:00 p.m. Registration Headhouse Tower Foyer, Marriott 7:00 a.m. to 4:15 p.m. New Chairs and Emerging Leaders Program Sponsored by Grant Cooper Health Care 12:00 p.m. to 6:00 p.m. Research Pathways Directors Workshop Requires separate registration; for more information please visit the 2019 Research Pathways Directors Workshop website 5:00 p.m. to 6:00 p.m. Academic Internal Medicine Week 2019 Welcome Reception Exhibit Hall F (Level 100), PCC 6:30 p.m. to 8:30 p.m. APM Dinner Independence Ballroom I&II, Headhouse Tower Marriott Monday, April 15, 2019 7:00 a.m. to 4:00 p.m. Registration Headhouse Tower Foyer, Marriott 7:00 a.m. to 9:00 a.m. Breakfast Liberty C, Headhouse Tower Marriott 8:00 a.m. to 8:15 a.m. Welcome and Introduction Liberty AB, Headhouse Tower Marriott Nancy J. Brown, MD, Moderator APM President Chair, Department of Internal Medicine Vanderbilt University School of Medicine (1) 8:15 a.m. to 9:30 a.m. Plenary Session I Liberty AB, Headhouse Tower The Role of Academic Departments of Medicine within Expanding Marriott Healthcare Systems Mark Geraci, MD, Moderator Chair, Department of Internal Medicine Indiana University School of Medicine Victoria J. Fraser, MD Chair, Department of Internal Medicine Washington University in St. Louis School of Medicine Mark Gladwin, MD Chair; Director, Vascular Medicine Institute University of Pittsburgh School of Medicine Talmadge E. King, Jr., MD Dean and Vice Chancellor for Medical Affairs University of California, San Francisco School of Medicine Paul E. Klotman, MD President and CEO; Executive Dean Baylor College of Medicine Richard P. Shannon, MD Executive Vice President for Health Affairs University of Virginia School of Medicine Steve Shapiro, MD Executive Vice President, UPMC Chief Medical and Scientific Officer President, Health Services Division Distinguished Professor of Medicine University of Pittsburgh School of Medicine 9:30 a.m. to 9:45 a.m. Break 9:45 a.m. to 11:15 a.m. Concurrent Plenary Sessions Liberty AB, Headhouse Tower Plenary Session II Marriott The Career Development of Physician Scientists Mone Zaidi, MD, PhD, Moderator Professor, Department of Medicine Icahn School of Medicine at Mount Sinai Katrina Armstrong, MD Chair, Department of Medicine Harvard Medical School Massachusetts General Hospital (2) David Ginsburg, MD James V Neel Distinguished University Professor Internal Medicine & Human Genetics University of Michigan Medical School Mukesh Jain, MD Professor, Department of Medicine Case Western Reserve University School of Medicine Independence Ballroom I&II, Plenary Session III Headhouse Tower Marriott Technology and Innovation Nancy J. Brown, MD, Moderator Chair, Department of Internal Medicine Vanderbilt University School of Medicine Joshua Denny, MD, MS Associate Professor, Department of Internal Medicine Vanderbilt University School of Medicine William Tierney, MD Chair, Department of Population Health University of Texas at Austin Dell Medical School Robert M. Wachter, MD Chair, Department of Medicine University of California, San Francisco School of Medicine 11:15 a.m. to 11:30 a.m. Break 11:30 a.m. to 1:00 p.m. Plenary Session IV Liberty AB, Headhouse Tower Lessons Learned/Fail Fest Marriott Patricia W. Finn, MD, Moderator Chair, Department of Medicine University of Illinois College of Medicine D. Craig Brater, MD President and CEO Alliance for Academic Internal Medicine William J. Bremner, MD Chair, Department of Medicine University of Washington School of Medicine Talmadge King, MD Dean and Vice Chancellor for Medical Affairs University of California, San Francisco School of Medicine (3) Paul Klotman, MD President and CEO; Executive Dean Baylor College of Medicine Paul B. Rothman, MD Dean of the Medical Faculty CEO, Johns Hopkins Medicine Johns Hopkins School of Medicine 1:00 p.m. to 2:30 p.m. APM Annual Awards Lunch for Participants and Guests Liberty C, Headhouse Tower Marriott Nancy J. Brown, MD, Moderator APM President Chair, Department of Internal Medicine Vanderbilt University School of Medicine Presentation of the 2019 APM Robert H. Williams, MD Distinguished Chair of Medicine Award John M. Carethers, MD, Recipient Chair, Department of Internal Medicine University of Michigan Medical School 2:30 p.m. to 2:45 p.m. Break 2:45 p.m. to 3:45 p.m. AAIM Women Leaders Meeting Independence Ballroom III, Headhouse Tower Marriott 2:45 p.m. to 5:30 p.m. Open Networking Time 5:30 p.m. to 6:30 p.m. Poster Reception for Academic Internal Medicine Week 2019 Exhibit Hall F (Level 100), PCC 6:30 p.m. to 8:00 p.m. Reception for Participants and Guests to Honor Former APM Independence Ballroom III, Presidents and Past Recipients of the APM Robert H. Williams, MD, Headhouse Tower Marriott Distinguished Chair of Medicine Award, AAIM Diversity Award, and AAIM Special Recognition Award Tuesday, April 16, 2019 7:00 a.m. to 9:00 a.m. Breakfast Liberty C, Headhouse Tower Marriott (4) 7:30 a.m. to 9:30 a.m. Vice Chairs for Research Special Interest Group Session Liberty AB, Headhouse Tower Marriott 7:30 a.m. to 7:40 a.m. Welcome and Defining Purpose Liberty AB, Headhouse Tower Marriott Mone Zaidi, MD, PhD, MACP Professor, Department of Medicine Icahn School of Medicine at Mount Sinai Gregory Kirk, MD, PhD Vice Chair for Clinical and Translational Research Johns Hopkins University School of Medicine 7:40 a.m. to 8:05 a.m. Managing a Clinical Trials Portfolio in a Department of Medicine Liberty AB, Headhouse Tower Marriott Rodica Busui MD, PhD Associate Chair for Clinical Research University of Michigan Medical School Gregory Kirk, MD, PhD, Moderator Vice Chair for Clinical and Translational Research Johns Hopkins University School of Medicine 8:05 a.m. to 8:30 a.m. Ensuring Data Integrity in Biomedical Research Liberty AB, Headhouse Tower Marriott Stuart C. Ray, MD Vice Chair for Data Integrity and Analytics Johns Hopkins University School of Medicine Mone Zaidi, MD, PhD, Moderator Professor, Department of Medicine Icahn School of Medicine at Mount Sinai 8:30 a.m. to 9:00 a.m. Panel Discussion Liberty AB, Headhouse Tower Marriott Roy Zent, MD, PhD, Moderator Vice Chair for Research Vanderbilt University School of Medicine Rodica Busui MD, PhD Associate Chair for Clinical Research University of Michigan Medical School Gregory Kirk, MD, PhD (5) Vice Chair for Clinical and Translational Research Johns Hopkins University School of Medicine Brian O’Rourke, PhD Vice Chair for Basic Research Johns Hopkins University School of Medicine Stuart C. Ray, MD Vice Chair for Data Integrity and Analytics Johns Hopkins School of Medicine Mone Zaidi, MD, PhD, MACP Professor, Department of Medicine Icahn School of Medicine at Mount Sinai 9:00 a.m. to 9:30 a.m. Self-Organization Liberty AB, Headhouse Tower Marriott 8:30 a.m. to 9:30 a.m. Community Based Schools Special Interest Group Session Independence Ballroom I&II, Headhouse Tower Marriott 9:00 a.m. to 10:00 a.m. Discussion Tables • Compensation Models • Funds Flow 9:30 a.m. to 10:00 a.m. Break 10:00 a.m. to 11:30 a.m. Concurrent Plenary Sessions Independence Ballroom I&II, Plenary Session V Headhouse Tower Marriott Science and Translation: Navigating the Journey Mark Geraci, MD, Moderator Chair, Department of Internal Medicine Indiana University School of Medicine Jean Bennett, MD, PhD F.M. Kirby Professor of Ophthalmology Raymond and Ruth Perelman School of Medicine at the University of Pennsylvania Carl June, MD, MS Richard W. Vague Professor in Immunotherapy Raymond and Ruth Perelman School of Medicine at the University of Pennsylvania 2019 APM Winter Meeting Agenda Page 6 Liberty AB, Headhouse Tower Plenary Session VI Marriott Lessons for Leadership from High Profile Cases of Misbehavior Fredric E. Wondisford, MD, Moderator Chair, Department of Medicine Rutgers Robert Wood Johnson Medical School Victoria J. Fraser, MD Chair, Department of Internal Medicine Washington University in St. Louis School of Medicine Anthony N. Hollenberg, MD Chair, Department of Internal Medicine Weill Cornell Medicine Patricia W. Finn, MD Chair, Department of Medicine University of Illinois College of Medicine Richard P. Shannon, MD Executive Vice President for Health Affairs University of Virginia School of Medicine Steve Shapiro, MD Executive Vice President, UPMC Chief Medical and Scientific Officer President, Health Services Division Distinguished Professor of Medicine University of Pittsburgh School of Medicine 11:30 a.m. to 12:00 p.m. Break 12:00 p.m. to 1:45 p.m. APM Presidential Address and Luncheon Liberty C, Headhouse Tower Marriott Nancy J. Brown, MD Chair, Department of Internal Medicine Vanderbilt University School of Medicine 1:45 p.m. to 2:00 p.m. Break (7) 2:00 p.m. to 3:30 p.m. Plenary Session VII Independence Ballroom I&II, Examination of Large Vertical Integrations Occurring within the Headhouse Tower Marriott Health Care Sector C. Seth Landefeld, MD, Co-Moderator Chair, Department of Medicine University of Alabama School of Medicine Gary Rosenthal, MD, Co-Moderator Tinsley R. Harrison Professor and Chair Department of Internal Medicine Wake Forest School of Medicine of Wake Forest Baptist Medical Center Steve Miller, MD Chief Clinical Officer Cigna and Express Scripts Lewis G. Sandy, MD Executive Vice President, Clinical Advancement UnitedHealth Group (8) .
Recommended publications
  • Renewed Momentum in Ocular Gene and Cell Therapy, Broadening Application to Chronic Diseases
    FEATURE Renewed momentum in ocular gene and cell therapy, broadening application to chronic diseases BY ROD MCNEIL Gene and cell therapies offer the prospect of ground-breaking new avenues for the treatment of diseases, reflected in a renewed explosion of interest and investment in retinal gene therapy. Rod McNeil reports recent clinical trial readouts across a diverse range of investigational ocular gene and cell therapy candidates. ene therapy is literally giving transfer clinical trials to date involving (VA) at 24 months in patients treated with sight to children who would subretinal and intravitreal delivery. The timrepigene emparvovec compared with otherwise not see,” said Dr majority of these studies use an adeno- untreated patients in the natural history GJean Bennett, delivering the associated virus (AAV) vector. study. At two years over 90% of patients “ treated with timrepigene emparvovec Charles L Schepens MD Lecture jointly with Prof Albert Maguire at the American Gene therapy for choroideremia maintained VA. In a subset of treated Academy of Ophthalmology 2019 Retina Investigational gene therapy timrepigene patients with moderate to severe VA loss, Subspecialty Day. Dr Bennett has developed emparvovec (BIIB111/AAV2-REP1, Biogen) 21% experienced a VA improvement of at gene transfer approaches to test treatment is an AAV2 vector administered by least 15 letters from baseline compared with strategies for retinal degenerative and subretinal injection being evaluated as a 1.0% of untreated patients. ocular neovascular diseases and her work treatment for choroideremia (CHM). Biogen led to the first approved gene therapy announced November 2019 completion GenSight Biologics targets novel product targeting a retinal disease of patient enrolment in the global phase gene therapies for LHON and worldwide.” 3 STAR clinical trial of 170 adult males retinitis pigmentosa patients Gene therapy has definitely arrived.
    [Show full text]
  • Stem Cells Set Their Sights on Retinitis Pigmentosa
    INSIGHT elife.elifesciences.org OPHTHALMOLOGY Stem cells set their sights on retinitis pigmentosa Skin cells from a patient with a form of inherited blindness have been reprogrammed into retinal cells and successfully transplanted into mice. JEANNETTE L BENNICELLI AND JEAN BENNETT loss to identify the genetic mutations leading Related research article Tucker BA, to their blindness; the Iowa team also generate induced pluripotent stem cells (iPSCs) from these Mullins RF, Streb LM, Anfinson K, Eyestone individuals to create patient-specific models of ME, Kaalberg E, Riker MJ, Drack AV, Braun disease. Now, in eLife, Stone and co-workers— TA, Stone EM. 2013. Patient-specific including Budd Tucker as first author—report that iPSC-derived photoreceptor precursor they have used stem cell technology to create a personalized model of a recessive form of retinitis cells as a means to investigate retinitis pigmentosa, and that they have also successfully pigmentosa. eLife 2:e00824. doi: 10.7554/ transplanted the cells into mice (Tucker et al., eLife.00824 2013). These results are an important step toward Image Photoreceptors derived from human autologous transplantation, the regeneration of tissues damaged by disease using stem cells stem cells can colonize a mouse retina derived from the patient’s own cells (Figure 1). (arrow) In addition to benefiting basic research, these findings represent a means to develop specific understanding of, and treatment for, a range of genetic conditions—in particular, the large set of nherited blindness encompasses a wide highly idiosyncratic syndromes that constitute spectrum of pathologies that can be caused inherited blindness. Iby mutations in more than 220 genes.
    [Show full text]
  • Scheie Vision Department of Opthalmology
    summer 2018 scheie vision Department of Opthalmology Like Watching a Miracle: From Landmark Gene Therapy to the Stage of America’s Got Talent IN THIS ISSUE A MESSAGE FROM THE CHAIR Dear Friends, VISION Penn Medicine’s Department of Ophthalmology, Scheie Eye Institute, is dedicated to cutting edge research, 02 Like Watching a Miracle providing the highest quality of care in Philadelphia and around the world, and training the next generation 04 Landmark FDA Approval of ophthalmologists. Our faculty and staff strive to cultivate an environment of continued learning and 08 Studying Individual Photoreceptors mentoring, where young minds with great potential grow and thrive. Our alumni go on to lead impactful 10 Intraocular Bleeding from careers, maintaining relationships with peers and mentors and returning to the Annual Alumni Meeting Blood Clot Meds? each spring. This event is always a reminder of the outstanding accomplishments of Scheie’s alumni, 11 New Options for Dry Eye students, staff, and faculty, and their daily commitment to improving the lives of patients and colleagues. This issue of Scheie Vision covers the people behind SCHEIE COMMUNITY Scheie’s advances and mission of excellence. We 13 Beautiful Inside and Out feature Lang Lourng Ung, an ophthalmic technician who brings inspirational resilience and passion to working with patients; Sonul Mehta, MD, who travels 15 Faces of Scheie around the world to provide ophthalmic care in underserved communities; Jessica Morgan, PhD, whose 19 Eye Care Across the World research on photoreceptor function has tremendous implications for the diagnosis and treatment of retinal 20 Remembering Walker Kirby disease; and Jean Bennett, MD, PhD, and Al Maguire, MD, who have demonstrated unwavering commitment for over 25 years to making it possible for blind 21 144th Anniversary Weekend children to see.
    [Show full text]
  • Novel Adeno-Associated Viral Vectors for Retinal Gene Therapy
    Gene Therapy (2012) 19, 162–168 & 2012 Macmillan Publishers Limited All rights reserved 0969-7128/12 www.nature.com/gt REVIEW Novel adeno-associated viral vectors for retinal gene therapy This article has been corrected since Advance Online Publication and an erratum is also printed in this issue LH Vandenberghe1 and A Auricchio2,3 Vectors derived from adeno-associated virus (AAV) are currently the most promising vehicles for therapeutic gene delivery to the retina. Recently, subretinal administration of AAV2 has been demonstrated to be safe and effective in patients with a rare form of inherited childhood blindness, suggesting that AAV-mediated retinal gene therapy may be successfully extended to other blinding conditions. This is further supported by the great versatility of AAV as a vector platform as there are a large number of AAV variants and many of these have unique transduction characteristics useful for targeting different cell types in the retina including glia, epithelium and many types of neurons. Naturally occurring, rationally designed or in vitro evolved AAV vectors are currently being utilized to transduce several different cell types in the retina and to treat a variety of animal models of retinal disease. The continuous and creative development of AAV vectors provides opportunities to overcome existing challenges in retinal gene therapy such as efficient transfer of genes exceeding AAV’s cargo capacity, or the targeting of specific cells within the retina or transduction of photoreceptors following routinely used intravitreal
    [Show full text]
  • A Nonhuman Primate Model of Achromatopsia
    The Journal of Clinical Investigation COMMENTARY Blinded by the light: a nonhuman primate model of achromatopsia Katherine E. Uyhazi and Jean Bennett Center for Advanced Retinal and Ocular Therapeutics, F.M. Kirby Center for Molecular Ophthalmology, Scheie Eye Institute, University of Pennsylvania, Philadelphia, Pennsylvania, USA. sitely light-sensitive rod photoreceptors for both night- and daytime vision. How- Achromatopsia is an inherited retinal degeneration characterized by the ever, rods are specialized to function well loss of cone photoreceptor function. In this issue of the JCI, Moshiri et in dimly lit conditions, but are too sensitive al. characterize a naturally occurring model of the disease in the rhesus to work efficiently in bright light, resulting macaque caused by homozygous mutations in the phototransduction in glare. Rods also have low spatial resolu- enzyme PDE6C. Using retinal imaging, and electrophysiologic and tion, leading to decreased acuity. biochemical methods, the authors report a clinical phenotype nearly There are currently six known caus- identical to the human condition. These findings represent the first genetic ative genes of achromatopsia, almost all of nonhuman primate model of an inherited retinal disease, and provide an which are components of the phototrans- ideal testing ground for the development of novel gene replacement, gene duction cascade in cone photoreceptors editing, and cell replacement therapies for cone dystrophies. (3). Approximately 75% of affected individ- uals have mutations in cyclic nucleotide- gated channel beta 3 or alpha 3 (CNGB3 or CNGA3), while the remainder of cases are caused by mutations in the remaining four Color blindness vivors, one of whom was a heterozygous genes (GNAT2, PDE6C, PDE6H, or ATF6) On the remote South Pacific island of carrier of the disease (2).
    [Show full text]
  • Reprogramming the Retina: Next Generation Strategies of Retinal Neuroprotection and Gene Therapy Vector Potency Assessment
    University of Pennsylvania ScholarlyCommons Publicly Accessible Penn Dissertations 2018 Reprogramming The Retina: Next Generation Strategies Of Retinal Neuroprotection And Gene Therapy Vector Potency Assessment Devin Scott Mcdougald University of Pennsylvania, [email protected] Follow this and additional works at: https://repository.upenn.edu/edissertations Part of the Genetics Commons, Molecular Biology Commons, and the Virology Commons Recommended Citation Mcdougald, Devin Scott, "Reprogramming The Retina: Next Generation Strategies Of Retinal Neuroprotection And Gene Therapy Vector Potency Assessment" (2018). Publicly Accessible Penn Dissertations. 3158. https://repository.upenn.edu/edissertations/3158 This paper is posted at ScholarlyCommons. https://repository.upenn.edu/edissertations/3158 For more information, please contact [email protected]. Reprogramming The Retina: Next Generation Strategies Of Retinal Neuroprotection And Gene Therapy Vector Potency Assessment Abstract Mutations within over 250 known genes are associated with inherited retinal degeneration. Clinical success following gene replacement therapy for Leber’s congenital amaurosis type 2 establishes a platform for the development of downstream treatments targeting other forms of inherited and acquired ocular disease. Unfortunately, several challenges relevant to complex disease pathology and limitations of current gene transfer technologies impede the development of gene replacement for each specific form of retinal degeneration. Here we describe gene augmentation strategies mediated by recombinant AAV vectors that impede retinal degeneration in pre-clinical models of acquired and inherited vision loss. We demonstrate distinct neuroprotective effects upon retinal ganglion cell survival and function in experimental optic neuritis following AAV-mediated gene augmentation. Gene transfer of the antioxidant transcription factor, NRF2, improves RGC survival while overexpression of the pro-survival and anti- inflammatory protein, SIRT1, promotes preservation of visual function.
    [Show full text]
  • Adeno-Associated Virus 8-Mediated Gene Therapy for Choroideremia: Preclinical Studies in in Vitro Ind in Vivo Models
    University of Pennsylvania ScholarlyCommons Publicly Accessible Penn Dissertations 2015 Adeno-Associated Virus 8-Mediated Gene Therapy for Choroideremia: Preclinical Studies in in Vitro ind in Vivo Models Aaron Daniel Black University of Pennsylvania, [email protected] Follow this and additional works at: https://repository.upenn.edu/edissertations Part of the Genetics Commons, Ophthalmology Commons, and the Virology Commons Recommended Citation Black, Aaron Daniel, "Adeno-Associated Virus 8-Mediated Gene Therapy for Choroideremia: Preclinical Studies in in Vitro ind in Vivo Models" (2015). Publicly Accessible Penn Dissertations. 1014. https://repository.upenn.edu/edissertations/1014 This paper is posted at ScholarlyCommons. https://repository.upenn.edu/edissertations/1014 For more information, please contact [email protected]. Adeno-Associated Virus 8-Mediated Gene Therapy for Choroideremia: Preclinical Studies in in Vitro ind in Vivo Models Abstract Choroideremia (CHM) is a slowly progressive X-linked retinal degeneration that results ultimately in total blindness due to loss of photoreceptors, retinal pigment epithelium, and choroid. CHM, the gene implicated in choroideremia, encodes Rab escort protein-1 (REP-1), which is involved in the post- translational activation via prenylation of Rab proteins. We evaluated AAV8.CBA.hCHM, a human CHM encoding recombinant adeno-associated virus serotype 8 (rAAV8) vector, which targets retinal cells efficiently, for therapeutic effect and safety in vitro and in vivo in a murine model of CHM. In vitro studies assayed the ability of the vector to produce functional REP-1 protein in established cell lines and in CHM patient derived primary fibroblasts. Assays included Western blots, immunofluorescent labeling, and a REP-1 functional assay which measured the ability of exogenous REP-1 to prenylate Rab proteins.
    [Show full text]
  • 52 N O V E M B E R 2 0
    Retinal alfred t. kamajian t. alfred 52 november 2012 From inherited retinal dystrophies to AMD, the pace of gene therapy is picking up, spurred on by recent success with Leber congenital amaurosis. An update on current research and insights Gene Therapyfrom leaders in the field. BY ANNIE STUART, CONTRIBUTING WRITER fter a few false starts in early gene therapy clinical That’s a far cry from evaluating gene therapy for liver trials in the 1990s, the dramatic success of the Leber disease, for example, where it’s not possible to make direct congenital amaurosis (LCA) trials has spurred re- observations. A newed interest and a great deal of development in the field at large. Although research is progressing in uveitis, Retinal Rewards glaucoma, and cornea, the most promising results in oph- The retina is a desirable target for gene therapy, largely thalmology thus far have emerged with retinal disorders. because it is an essential, irreplaceable part of the central As with so many areas of study, the eye offers a unique nervous system, said Richard A. Lewis, MD, professor of opportunity for gene therapy. “Because of its size, the eye ophthalmology and molecular and human genetics at Bay- requires relatively small doses to achieve a therapeutic ef- lor College of Medicine in Houston. “You can change some fect,” said J. Timothy Stout, MD, PhD, MBA, genetic re- things about the anterior segment of the eye—repair cor- searcher and professor of ophthalmology at Oregon Health neal damage, do transplants, or remove cataracts—but you & Science University in Portland. This was particularly can’t replace the retina.” advantageous at the very earliest stages of eye gene therapy, From inherited retinal dystrophies to AMD, gene therapy he said, when making large amounts of gene vectors was no offers promise for the clinician in two primary ways: “There easy task.
    [Show full text]
  • The Evolution of Retinal Gene Therapy: from DNA to FDA
    COVER STORY The Evolution of Retinal Gene Therapy: From DNA to FDA BY JEAN BENNETT, MD, PHD; AND ALBERT M. MAGUIRE, MD The Gertrude D. Pyron Award was created by the Retina Research Foundation to recognize outstanding vision scientists whose work contributes to knowledge about vitreoretinal disease. At the American Society of Retina Specialists 2011 Annual Meeting, the Pyron Award recipients were Jean Bennett, MD, PhD, and Albert M. Maguire, MD, whose pioneering work with retinal gene therapy is ongoing at the University of Pennsylvania and the Children’s Hospital of Philadelphia. The husband-and-wife team shared the privilege of delivering the Gertrude D. Pyron Award Lecture, titled “The Evolution of Retinal Gene Therapy: From DNA to FDA.” Highlights of the award lecture are summarized in the following article. JEAN BENNETT, MD, PHD I had the opportunity of working with the senior author There is currently no US Food and Drug of the report, W. French Anderson, MD, a few years before Administration (FDA)-approved gene therapy product that publication. Later, Al and I discussed whether it in the United States. However, genetic research contin- would it be possible to use gene therapy to treat a retinal ues to grow. It may be that early successes in ocular disease. In 1990 we performed the first retinal gene trans- gene therapy may lead the way for all sorts of gene ther- fer in vivo in a large animal.5 Although we were pleased apies and to more widespread research in the field. with the results of this study, we found that the trans- Decades of scientific developments have led to the ferred reporter gene stayed active for only about 2 weeks.
    [Show full text]
  • Research Funding Provided by Choroideremia Research Foundation Curechm.Org
    Research Funding provided by Choroideremia Research Foundation CureCHM.org Funded Researcher Name Institution Project Title USD $ Miguel Seabra, MD, PhD, Professor, CEDOC, Chronic 2002 Nova Medical School, University of Lisbon, Portugal Choroideremia Research Lab Supplies 1,500 Diseases Research Center Miguel Seabra, MD, PhD, Professor, CEDOC, Chronic 2003 Nova Medical School, University of Lisbon, Portugal Development of CHM Mouse Model 14,500 Diseases Research Center Miguel Seabra, MD, PhD, Professor, CEDOC, Chronic 2004 Nova Medical School, University of Lisbon, Portugal Generation of CHM Viral Vector, pt. 1 20,550 Diseases Research Center 2005 Kirill Alexandrov, PhD Max Planck Institute, Germany Forced Expression of REP2 to the Retina 13,000 Miguel Seabra, MD, PhD, Professor, CEDOC, Chronic 2005 Nova Medical School, University of Lisbon, Portugal Generation of CHM Viral Vector, pt. 2 50,000 Diseases Research Center Miguel Seabra, MD, PhD, Professor, CEDOC, Chronic 2006 Nova Medical School, University of Lisbon, Portugal Preclinical Gene Therapy Study Year 1 80,460 Diseases Research Center Miguel Seabra, MD, PhD, Professor, CEDOC, Chronic 2007 Nova Medical School, University of Lisbon, Portugal Preclinical Gene Therapy Study Year 2 69,880 Diseases Research Center Jean Bennett, MD, PhD, F.M. Kirby Professor of Scheie Eye Institute, Perelman School of Medicine, Mouse Study Testing for Three Viral Vector 2010 100,000 Ophthalmology University of Pennsylvania, Philadelphia, PA Candidates Jean Bennett, MD, PhD, F.M. Kirby Professor of Scheie Eye Institute, Perelman School of Medicine, Alternative In-Vitro Assay to Evaluate Three Viral 2011 75,000 Ophthalmology University of Pennsylvania, Philadelphia, PA Vector Candidates Miguel Seabra, MD, PhD, Professor, CEDOC, Chronic 2011 Nova Medical School, University of Lisbon, Portugal Pre-Clinical Gene Therapy Study Year 3 90,000 Diseases Research Center Jean Bennett, MD, PhD, F.M.
    [Show full text]
  • Genes As Medicine Film Guide Educator Materials
    Genes as Medicine Film Guide Educator Materials OVERVIEW Gene therapy—the delivery of corrective genes into cells to treat a genetic disease—is an idea that was on scientists’ minds as early as the 1960s. It took more than 35 years, however, to accumulate the knowledge and tools necessary to make gene therapy in humans a success. The HHMI short film Genes as Medicine tells the story of Drs. Jean Bennett, Albert Maguire, and their colleagues’ decades-long effort to develop a gene therapy for a childhood disease called Leber congenital amaurosis (LCA). KEY CONCEPTS A. Some inherited diseases are caused by mutations in single genes. These mutations result in proteins that malfunction or, in some cases, no protein being produced, which cause the disease phenotypes. B. For an individual to have a recessive genetic disease, they must have a disease-causing mutation in each copy (or allele) of a gene. If an individual has one allele with the mutation and one allele without it (in other words, they are heterozygous), they may have no disease symptoms. C. Gene therapy is an experimental technique that adds corrective copies of mutated genes to a patient’s cells. D. Many biotechnology applications take advantage of naturally occurring processes. For example, in developing some gene therapies, scientists take advantage of viruses’ ability to add genes to cells. E. Most medical discoveries, including gene therapy, can take decades to move from the lab to new treatments available to people who need them. F. Before most new medical treatments can be made available to patients, they must first be shown to work in animal models and then be shown to work in people taking part in clinical trials.
    [Show full text]
  • Gene Therapy ‘Cure’ for Blindness Wanes
    NEWS Gene therapy ‘cure’ for blindness wanes Two independent academic groups at the received different doses of vector, 6 showed degeneration was prevented,” says Robin Ali University of Pennsylvania (UPenn) in some improved retinal sensitivity for up to of the UCL Institute of Ophthalmology who Philadelphia and University College London’s three years before decline set in. But compari- led the UK study. (UCL) Institute of Ophthalmology reported son is difficult, even within the same trial, as The UPenn study tested patients ages 16 or long-term results for a gene therapy of Leber’s patients had different levels of blindness and older who had had more than a decade of dis- congenital amaurosis (LCA), a rare form of were treated with different doses, scientists ease progression. “We still don’t know if treat- inherited childhood blindness. Both trials, caution. ing children earlier will provide a longer run testing a single eye in each patient, found that With retinal gene therapy’s longevity now for the therapy,” says Da Cruz. According to efficacy diminished after three or more years, under scrutiny, doubts spilled over to the most Ali, earlier intervention with a more efficient sounding a cautious note amid the technol- advanced LCA treatment, developed by Spark vector to restore RPE65 levels is more likely to ogy’s rapturous renaissance (N. Engl. J. Med. Therapeutics. The Philadelphia-based bio- achieve a sustained benefit. 372, 1887–1897, 2015; N. Engl. J. Med. 372, tech is running a phase 3 trial of SPK-RPE65, The question of age will be addressed 1920–1926, 2015).
    [Show full text]