International Harrington Prize Awarded to Dr. Owen Witte
CLEVELAND, March 19, 2025 /PRNewswire/ -- The twelfth annual Harrington Prize for Innovation in Medicine has been awarded to Owen N. Witte, MD, Distinguished University Professor and President's Chair in Developmental Immunology, David Geffen School of Medicine, University of California, Los Angeles. The award recognizes his foundational discoveries of targeted therapies that have transformed modern cancer treatment.
The Harrington Prize for Innovation in Medicine, established in 2014 by the Harrington Discovery Institute at University Hospitals and the American Society for Clinical Investigation (ASCI), honors physician-scientists who have moved science forward with achievements notable for innovation, creativity and potential for clinical application.
Dr. Witte is internationally known for his contributions to the understanding of human leukemias and immune disorders. His work revealed the critical role of enzymes called tyrosine kinases in human disease.
Dr. Witte discovered one of the first tyrosine kinases, the ABL oncoprotein, showing that its activity is responsible for causing chronic myeloid leukemia (CML)—a cancer of white blood cells. He predicted that drugs that inhibit the tyrosine kinase would have therapeutic benefit. Based on Dr. Witte's work, the drug imatinib, an inhibitor of tyrosine kinase ABL, was developed as frontline therapy. Imatinib increases the 8-year survival rate for CML from 6% to 87%.
Dr. Witte subsequently discovered Bruton's tyrosine kinase (BTK). He provided evidence that BTK's tyrosine kinase activity was important for both normal immune function (loss of BTK led to immunodeficiency disease) and white blood cell cancers—ultimately spurring the development of the BTK inhibitor drug ibrutinib, now used to treat several types of lymphomas and leukemias.
'It is a great honor to present Dr. Witte with the Harrington Prize for Innovation in Medicine. His transformative contributions to cancer research have not only reshaped our understanding of leukemia, lymphoma, and epithelial cancers but have also revolutionized targeted therapies, directly impacting countless lives. His seminal contributions to the development of ABL and BTK inhibitors exemplifies the scientific creativity and impact this award stands for,' said Anna Greka, MD, PhD, Professor of Medicine at Harvard Medical School, Physician at Mass General Brigham, Core Institute Member of the Broad Institute of MIT and Harvard, and 2024-2025 ASCI President.
'Dr. Witte's remarkable work serves as a powerful illustration of how basic discovery can inform the development of life-saving therapies. His groundbreaking work has bridged the gap between the laboratory bench and the clinical bedside, extending human life,' said Jonathan S. Stamler, President & Co-Founder, Harrington Discovery Institute, Robert S. and Sylvia K. Reitman Family Foundation Chair of Cardiovascular Innovation, Distinguished University Professor, and Professor of Medicine and of Biochemistry at University Hospitals and Case Western Reserve University.
A committee composed of members of the ASCI Council and the Harrington Discovery Institute Scientific Advisory Board reviewed nominations from leading academic medical centers from six countries before selecting the 2025 Harrington Prize recipient.
In addition to receiving the Prize's $20,000 honorarium, Dr. Witte will deliver the Harrington Prize Lecture at the 2025 AAP/ASCI/APSA Joint Meeting on April 25-27, and he will be a featured speaker at the 2025 Harrington Scientific Symposium May 21-22 and is invited to publish an essay in the Journal of Clinical Investigation.
The Harrington Prize has recognized outstanding and diverse innovations in medicine since 2014:
2014: Harry Dietz, MD, Johns Hopkins University, for his contributions to the understanding of the biology and treatment of Marfan syndrome, a disorder leading to deadly aneurysms in children and adults.
2015: Douglas R. Lowy, MD, The National Cancer Institute, in recognition of his discoveries that led to the development of the Human Papillomavirus vaccine to prevent cervical cancer.
2016: Jeffrey M. Friedman, MD, PhD, The Rockefeller University, for his discovery of leptin, which controls feeding behavior and is used to treat related clinical disorders.
2017: Jointly awarded to Daniel J. Drucker, MD, Mount Sinai Hospital, Canada, Joel F. Habener, MD, Massachusetts General Hospital, and Jens J. Holst, MD, DMSc, University of Copenhagen, Denmark, for their discovery of incretin hormones and for the translation of these findings into transformative therapies for major metabolic diseases such as diabetes.
2018: Helen H. Hobbs, MD, UT Southwestern Medical Center, for the discovery of the link between a gene mutation (PCSK9) and lower levels of LDL, which has improved the treatment of high cholesterol.
2019: Carl H. June, MD, University of Pennsylvania, for advancing the clinical application of CAR T therapy for cancer treatment, and for his sustained contributions to the field of cellular immunology.
2020: Stuart H. Orkin, MD, Harvard University, for breakthrough discoveries on red blood cells that offer new treatments for patients with sickle cell disease and beta-thalassemia, which are among the most common genetic disorders.
2021: Warren J. Leonard, MD, and John J. O'Shea, MD, NIH, for their respective contributions to the field of immunology, from fundamental discovery to therapeutic impact.
2022: James E. Crowe Jr., MD, Vanderbilt University, and Michel C. Nussenzweig, MD, PhD, The Rockefeller University, for their groundbreaking work, which has elucidated fundamental principles of the human immune response and enabled the use of human antibodies to treat COVID-19.
2023: Jean Bennett, MD, PhD, University of Pennsylvania, and Albert M. Maguire, MD, University of Pennsylvania, for their groundbreaking translational research to restore sight in inherited genetic diseases.
2024: Arlene H. Sharpe, MD, PhD, Harvard Medical School, for her breakthrough discoveries in immune regulation, which have led to new cancer therapies that act by boosting the immune response to cancer.
Hashtags
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
Yahoo
16 hours ago
- Yahoo
First Lung Organoid with Organ-Specific Blood Vessels
Advanced lab-grown tissues help show how special lung cells develop, shedding light on rare ACDMPV disease and suggesting potential ways to repair damage from viral infections such as COVID-19 CINCINNATI, June 30, 2025 /PRNewswire/ -- A team of experts at Cincinnati Children's reports another powerful step forward in organoid medicine: success at making human lung tissue that can produce its own blood vessels. Their findings, published in the same month as a similar success involving liver organoids, reflect a new wave of advanced lab-grown tissues that can be used immediately in many research applications while moving ever closer to serving as living tissues that can directly repair damaged organs. Details were posted online June 30, 2025, in the journal Cell. "Prior to our study, the development of lung organoids with organotypic vasculature had not been achieved," says co-corresponding author Mingxia Gu, MD, PhD. "Notably, this method also could be applied to other organ systems such as intestine and colon." Gu, now at UCLA, was a member of the Center for Stem Cell and Organoid Medicine (CuSTOM) and Division of Pulmonary Biology at Cincinnati Children's while this research was conducted. Co-first and co-corresponding author Yifei Miao, PhD, (now at the Chinese Academy of Sciences, Beijing) also was with Cincinnati Children's for this work. Co-corresponding author Minzhe Guo, PhD, remains with Cincinnati Children's along with several co-authors involved in this study. Overcoming a major challenge Researchers have been working for years to grow organoids -- sometimes called "organs in a dish." Creating organoids involves converting mature human cells (such as blood or tissue cells) back into fetal-like stem cells that can be coaxed into growing a wide range of other tissue types. Unlike disconnected human cells kept alive in a dish, these are growing, developing mini-organs that form into seed-sized spheres that mimic the unique functions of full-sized organs. Intestines that absorb and secrete. Stomachs that produce digestive acids. Hearts that pulse. Brain tissues with firing nerve cells and so on. Cincinnati Children's has been a leader in organoid development since 2010 when experts here produced the world's first functional intestinal organoid grown from induced pluripotent stem cells (iPSCs). More recently, the challenge has been learning how to grow organoid tissues that can connect with the rest of the body to integrate nerve connections, blood vessels, bile ducts, immune systems and more. During pregnancy, these differing tissue types naturally find each other as the fetus matures and becomes more complex. Organoid developers seek to re-produce these steps in the laboratory, which eventually may allow people to receive custom-grown tissues that could patch damage or boost disrupted functions. Simpler forms of organoids have already begun transforming medical research, allowing many scientists to use living human tissue models to study disease while reducing current reliance on animal models to develop new medicines. But without the ability to make internal blood vessels, the tiny seeds lack the ability to grow into larger, more useful tissues. How the team solved the vascular riddle The new study thoroughly recounts the results of many experiments the team conducted to demonstrate success at inducing blood vessel formation. The work spanned four years and involved more than 20 people at Cincinnati Children's plus collaborations with experts at several other organizations. "The challenge in vascularizing endodermal organs, particularly the lung, stems from different signaling requirements for lung epithelial versus vascular differentiation," says Miao. "Our success in this endeavor is attributable to our unique differentiation method." In essence, the team grew iPSCs from multiple cell types then found the right moment to introduce them to each other. The resulting cell signals helped flip a developmental switch so that progenitor cells that could have become either blood vessels or the outer walls of the lung wound up becoming blood vessels. In achieving this vital step, the team: Produced lung organoids that include respiratory bronchial epithelial cells (RAS cells), a human cell type not previously reported in conventional lung organoid models. Pinned down the developmental moments when a rudimentary gut tube begins to send some cells to form the lungs while sending other cells to form the stomach and intestine. While the basic steps of this transformation have been studied in animals, it had not been possible to study this stage of development in humans without killing fetuses. Demonstrated that the rare disease ACDMPV occurs when cell signaling "crosstalk" gets disrupted during this early blood vessel formation stage. Within days of birth, infants born with Alveolar Capillary Dysplasia with Misalignment of Pulmonary Veins (ACDMPV) struggle to breathe because their lungs' air sacs (alveoli) and blood vessels are malformed. Nearly all infants with this condition die within the first month of life, according to the National Organization for Rare Disorders. Revealed key functional information about the cells involved in gas exchange inside the human lung. Their learnings help explain the damage within tiny blood capillaries that occurs in the lungs in response to injuries. These new clues offer fresh ideas for developing ways to protect and potentially restore affected lung tissues. What's Next? Cincinnati Children's has filed patent applications related to the methods developed here to produce organoids with blood vessel formation capabilities and the CuSTOM team is moving to further develop this technology. "We look forward to continuing to learn more about the fundamental biology involved in organ formation and applying those discoveries to improving outcomes across a wide range of difficult human diseases and conditions," says Aaron Zorn, PhD, co-director of CuSTOM and director of the Division of Developmental Biology. In addition to publishing these findings in Cell, co-authors plan to present their work at the Keystone conference in Kyoto, Japan (iPSCs: Progress, Opportunities, and Challenges) in January 2026. About the study Cincinnati Children's co-equal first authors were Miao, Nicole Pek, BS, and Cheng Tan, MD. Contributing co-authors from Cincinnati Children's were Cheng Jiang, MS, Zhiyun Yu, PhD, Kentaro Iwasawa, MD, PhD, Min Shi, MD, PhD, Daniel Kechele, PhD, Nambirajan Sundaram, PhD, Victor Pastrana-Gomez, MSTP student, Debora Sinner, PhD, Cheng-Lun Na, PhD, Keishi Kishimoto, PhD, Jason Tchieu, PhD, Jeffrey Whitsett, MD, Kyle McCracken, MD, PhD, Michael Helmrath, MD, James Wells, PhD, Takanori Takebe, MD, PhD, and Aaron Zorn, PhD. Contributing co-authors included experts from Harvard Medical School, Icahn School of Medicine at Mount Sinai, Sophia Children's Hospital (The Netherlands), Boston University This research also was supported by the Discover Together Biobank, the Bio-Imaging and Analysis Facility, and the Integrated Pathology Research Core at Cincinnati Children's and the University of Cincinnati Proteomics Laboratory. Funding sources for this work included: the National Institutes of Health (R01HL166283, DK128799-01, N01-75N92020C00005 and R01HL095993); an Endowed Scholar Award from the Cincinnati Children's Research Foundation; the American Heart Association (1013861 and 906513); the Falk Transformational Awards Program; and the Brigham Research Institute. Learn more about working with CuSTOM Learn how donors can support ongoing organoid research at Cincinnati Children's View original content to download multimedia: SOURCE Cincinnati Children's Hospital Medical Center Error in retrieving data Sign in to access your portfolio Error in retrieving data Error in retrieving data Error in retrieving data Error in retrieving data
Associated Press
20 hours ago
- Associated Press
MiRus Siegel™ TAVR US Early Feasibility Study (EFS) 30 Day Results Presented at NY Valves Meeting
ATLANTA, July 2, 2025 /PRNewswire/ -- The MiRus Siegel™ Valve was featured in three podium presentations at the NY Valves meeting last week. Pradeep K. Yadav MD, Piedmont Heart Institute, Atlanta and Raj R. Makkar MD, Cedars Sinai Heart Institute, Los Angeles presented patient case studies and the 30 day results of US Early Feasibility Study (EFS). In the US EFS, 15 patients with severe, symptomatic aortic stenosis (AS) were treated at Piedmont, Cedars Sinai, Stanford, Mayo Clinic and Naples. At 30 days, there were no deaths, strokes or re-hospitalizations. No patients had vascular complications, PVL (> moderate) or required a permanent pacemaker. Core lab echocardiographic data demonstrated a mean gradient of 6.3 mmHg, and valve area of 2.8 cm2 . The Siegel valve represents several firsts in TAVR: 8 French delivery sheath allowing less invasive procedures and broader patient access, particularly for women; the only Nickel-free THV allowing treatment of the 20% of Americans suffering from Nickel allergies; precise delivery due to lack of foreshortening and intrinsic commissural alignment; dry porcine pericardial leaflets with anti-calcification treatment and with the valve pre-mounted on the balloon. 'This is the first TAVR to have no foreshortening during implantation and along with small vascular access, makes it very user friendly and should also lead to fewer pacemakers and vascular complications' commented Pradeep K. Yadav, MD. 'The lack of nickel is also very appealing – we were able to treat a patient with severe nickel and cobalt allergy.' The combination of low delivery system profile and excellent hemodynamics is made feasible by the unique properties of the Rhenium alloys pioneered by MiRus including high yield strength, fatigue resistance and minimal recoil. 'The gradients and valve areas with the Siegel valve are outstanding' stated Raj R. Makkar, MD. 'Valve placement is very precise and allows us to protect the conduction system – one of our patients was quite elderly with pre-existing conduction system injury and we were able to replace his valve without having to place a permanent pacemaker.' About MiRus, LLC. MiRus is a life sciences company headquartered in Marietta, Georgia that has developed and is commercializing proprietary novel biomaterials, implants and procedural solutions for the treatment of spine, orthopaedic and structural heart disease. Inspired by the pioneering material science of NASA for rocket engines, MiRus has created Rhenium based medical alloys that are transforming medicine by making surgeries less invasive and implants safer and more durable. Find out more information about MiRus at Statements made in this press release that look forward in time or that express beliefs, expectations or hopes regarding future occurrences or anticipated outcomes are forward-looking statements. A number of risks and uncertainties such as risks associated with product development and commercialization efforts, expected timing or results of any clinical trials, ultimate clinical outcome and perceived or actual advantages of the Company's products, market and physician acceptance of the products, intellectual property protection, and competitive offerings could cause actual events to adversely differ from the expectations indicated in these forward looking statements. The Siegel TAVR system is an investigational device and not FDA approved. * MiRus® , Siegel™ are all trademarks of MiRus, LLC. Contact: Pam Cowart VP of Clinical Affairs [email protected] 770-861-4804 View original content to download multimedia: SOURCE MiRus
Yahoo
2 days ago
- Yahoo
Medline named Prime Vendor by Wachusett Healthcare
East Coast provider of skilled nursing and rehabilitative services taps into Medline's supply chain and clinical portfolio NORTHFIELD Ill., July 1, 2025 /PRNewswire/ -- Medline today announced a new Prime Vendor agreement with skilled nursing and rehabilitative services provider Wachusett Healthcare. As part of the agreement, Wachusett Healthcare's facilities will choose from Medline's extensive portfolio of medical products and supplies, including Medline's skin health products. The East Coast-based organization will also receive accompanying skin health guidelines, educational programs and evidence-based online training courses for continuing education in skin and wound care via Medline University, as well as in-servicing through Medline's team of clinicians and skin health specialists. "At Wachusett Healthcare, we are always striving to enhance the quality of care and operational excellence across our facilities. Our partnership with Medline represents a strategic alignment with a leader in healthcare supply chain solutions," said Steven Vera, Chief Executive Officer, Wachusett Healthcare. "It will allow us to streamline our procurement process, ensure consistent access to high-quality products, and ultimately support our staff in delivering exceptional care to our residents." Said Brendon Anderson, corporate accounts director for Medline Long-Term Care: "Wachusett Healthcare is committed to providing a safe and compassionate care environment. We will support them in their commitment by ensuring a consistent supply of high-quality medical products that positively impacts Wachusett's care delivery needs. We are honored to be their Prime Vendor." Learn how Medline works with long-term care providers to improve clinical, financial and operational outcomes at About MedlineMedline is the largest provider of medical-surgical products and supply chain solutions serving all points of care. Through its broad product portfolio, resilient supply chain and leading clinical solutions, Medline helps healthcare providers improve their clinical, financial and operational outcomes. Headquartered in Northfield, Illinois, the company employs more than 43,000 people worldwide and operates in more than 100 countries and territories. To learn more about how Medline makes healthcare run better, visit FacebookTwitterLinkedInYouTube View original content to download multimedia: SOURCE Medline Industries, LP Sign in to access your portfolio
