Hubbry Logo
Shaf KeshavjeeShaf KeshavjeeMain
Open search
Shaf Keshavjee
Community hub
Shaf Keshavjee
logo
8 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Shaf Keshavjee
Shaf Keshavjee
Shaf Keshavjee
View on Wikipedia
from Wikipedia

Shaf Keshavjee is a Canadian surgeon and the current surgeon-in-chief at University Health Network in Toronto, the director of the Toronto Lung Transplant Program, as well as a clinical scientist and professor with the University of Toronto.[1]

Key Information

His clinical practice in thoracic surgery and transplant surgery is based at the Toronto General Hospital, where he also leads a research team in lung transplantation studies. Keshavjee gained international recognition for the development of his lung preservation solution for donor lungs en route to transplantation; this solution is now the standard technique utilized by transplantation programs around the world. Further, he broke new ground with his research to the recondition and repair of injured human donor lungs, making them suitable for patient transplantation, using the Toronto XVIVO Lung Perfusion System. His work has allowed for an increase in the number of available donor lungs.[2]

Education and training

[edit]

In 1985, Keshavjee completed his medical degree at the University of Toronto.[3] He did a comprehensive surgical internship at the Mount Sinai Hospital in 1986. His Research Fellowship and Surgical Scientist Program in the Division of Thoracic Surgery were done at the University of Toronto and Toronto General Hospital in 1989. That same year he received his MSc in the Institute of Medical Science at the University of Toronto. [citation needed]

A few years later in 1993, Keshavjee became a Fellow in Thoracic Surgery at the Memorial Sloan-Kettering Cancer Centre in New York City. In 2012, he went to Harvard University, Harvard Kennedy School, and Cambridge University to obtain a degree in continuing education for Leadership for the 21st Century: Chaos, Conflict and Courage. In 1994, he joined the faculty at the University of Toronto.[3]

Current appointments

[edit]
  • 1994–Present: Director of Thoracic Surgery Research Laboratory, Toronto General Research Institute (TGRI) and University of Toronto (U of T)[4]
  • 1995–Present: Faculty in the Institute of Medical Sciences, School of Graduate Studies at the University of Toronto[5]
  • 1997–Present: Senior Scientist, Division of Experimental Therapeutics, UHN, TGRI[6]
  • 1997–Present: Director, Toronto Lung Transplant Program, Toronto General Hospital (TGH) and The Hospital for Sick Children[7]
  • 2002–Present: Professor of Surgery, Department of Surgery, U of T[4]
  • 2010–2023: Surgeon-in-Chief, Sprott Department of Surgery, UHN[4]
  • 2012–Present: Adjunct Scientist, Hospital for Sick Children Research Institute[8]
  • 2022–Present: Techna Scientific Director and Chief of Clinical Innovation at UHN [9]

Awards and recognition

[edit]

Boards and societies

[edit]

Keshavjee has served on the board of directors of the International Society for Heart and Lung Transplantation, the Canadian Society of Transplantation, and on the Governing Council of the American Association for Thoracic Surgery.[4]

Awards

[edit]

Over the course of his career, he has received many awards for his medical contributions. These have included:

  • The George Armstrong Peters Young Investigator Award
  • Canada's Top 40 Under 40 Award
  • The Colin Woolf Award for Excellence in Continuing Medical Education
  • The Lister Prize in Surgery

The Lister Prize in Surgery is the highest award for research achievement that one can obtain within the University of Toronto's Department of Surgery.

On February 6, 2013, Keshavjee was inducted into the Order of Ontario. He has also received two Queen's Jubilee medals in recognition for his work.[10][11]

On December 26, 2014, Keshavjee was made an officer of the Order of Canada.[12]

TED MED

[edit]

At TED MED 2010, Keshavjee gave a talk entitled Can a human lung breathe outside the body, in which he addressed the process of repairing organs outside the human body.[13]

Achievements

[edit]

At his Thoracic Surgery Research Laboratory, Kehavjee's research interests include lung transplantation, lung injury, and lung preservation. His current studies examine molecular diagnostics and gene therapy strategies for engineering organs for lung transplantation. The Lab's work explores the underlying mechanisms of ischemia-reperfusion injury and bronchiolitis obliterans – two areas that limit successful lung transplantation – and develops gene therapy strategies for either preventing or reversing them. Several areas within ischemia-reperfusion injury are examined, including the role of complement and cytokine-related lung injury and its relation to reperfusion. The work is done on cell culture models, rat single lung transplant models, and pig single lung transplant models.[14]

Lung preservation

[edit]

Keshavjee and his research team have developed a technique of lung preservation that can improve lung function after its transplantation. The solution is made from low-potassium dextran and is used in the Ex Vivo.[citation needed]

The LPD solution is applied in both the Toronto lung transplant program and in clinical programs around the world.[15]

Gene therapy in lung transplantation

[edit]

Keshavjee's research team focuses its main efforts on the role of gene therapy in lung transplantation. They are currently developing techniques for genetically modifying the donor lung so it can withstand stress during the transplant process. Ultimately, these techniques would be used to address both ischemia-reperfusion injury and obliterative bronchiolitis.

Keshavjee's work has demonstrated that immunosuppression related to transplantation leads to an altered expression of the transgene, and immunosuppression will lead to the prolonged-expression of the transgene. To this effect, he and his team have proved that gene therapy will help recipients recover from lung transplantation surgery without a significant immune system response.

When addressing obliterative bronchiolitis in a rat tracheal transplant model of fibrous airway obliteration related to transplantation, Keshavjee's research showed that the adenoviral IL-10 gene transfection was able to prevent the development of bronchiolitis obliterans. This was the first time that a gene therapy strategy was able to treat this condition; a significant breakthrough as this condition affects over 50% of lung transplant recipients. The team is currently studying the effect of the IL-10 transfection on ischemia-reperfusion therapy, as well as mechanisms of cell death and the genes controlling the process.[16]

Toronto Lung Transplant Program

[edit]

Keshavjee currently serves as the director of the Toronto Lung Transplant Program, a University of Toronto program that spans across UHN and the Hospital for Sick Children. It began in 1983, and expanded to pediatric lung transplantation surgeries in 1995. Located in the Toronto General Hospital, it has gained international recognition for performing several remarkable firsts, including: First successful single-lung transplant, first successful double lung transplant, first pediatric lung transplant, first pediatric lung transplant with mismatched blood types, first to use an EXVIVO outside of the body, and the first to use the Novalung ventilator to provide more time for those awaiting transplantation.[17]

As a result of Keshavjee's breakthroughs, there have been steady increases in the number of transplants and the survival rate. While the one-year survival rate for lung transplant recipients is 85% and almost 30% for over 10 years, the TLTP has 22 patients who have survived 20 or more years after receiving their donor lungs.[18]

A gene-therapy trial will begin next year.[19]

Toronto Ex Vivo Lung Perfusion System (EVLP)

[edit]

Donor lungs are placed in ice, with one tube attached to the pulmonary artery and another sewn to a vein used for training blood out of the lung. The lung is then moved onto a steel platform atop the device and hooked to a circuit with a ventilator and heart-lung mimicking machine that pumps the preservation solution into them. As they are brought up to body temperature, they are healed with an anti-inflammatory solution (developed by Keshavjee). Eventually, the lungs begin to inflate and deflate as they breathe on their own. For several hours, the lungs are monitored for functionality with blood gases, x-rays, bronchoscopies, resistance to the flow of fluid, and whether they are becoming less stiff. If the tests are deemed successful for function, they may go ahead and perform the transplantation.[20]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Shaf Keshavjee

View on Grokipedia
from Grokipedia
Shafique (Shaf) Keshavjee is a Canadian thoracic surgeon, researcher, and innovator best known for revolutionizing through the development of lung (EVLP) technology and preservation solutions that have dramatically increased the availability and success of donor lungs worldwide. Born in 1961 in to South African parents, Keshavjee emigrated with his family to in the 1970s, where he completed his medical degree with honors at the in 1985, followed by residencies in , , and thoracic surgery at the same institution, as well as fellowships at and the . Early in his career, Keshavjee joined the team, witnessing the world's first successful single transplant in 1983 and assisting in the first double transplant in 1986, establishing him as a leader in the nascent field of thoracic . He earned an MSc for developing a novel preservation solution, low potassium dextran (LPD), in 1989, which became the global standard for protecting donor during transport and has generated a billion-dollar industry while improving transplant outcomes. As Director of the Lung Transplant Program since 1996, Keshavjee has overseen the utilization of up to 40% of donated —far exceeding the global average of 15%—through innovative protocols that repair marginal donor organs. Keshavjee's research, conducted at the Latner Thoracic Research Laboratories which he directs, focuses on the molecular mechanisms of injury, repair, and preservation, including the integration of , stem cells, and CRISPR-Cas9 editing to enhance organ viability. His breakthrough EVLP system, introduced in 2008, allows for the assessment and rehabilitation of donor s outside the body, enabling safe transplantation of previously unusable organs with the program reaching its 1000th EVLP case in 2025 and training surgeons across , , and the . With over 550 peer-reviewed publications, Keshavjee has advanced the field globally, establishing bioengineering centers that service more than 30 transplant programs and pioneering technologies like drone delivery for organs, including the first successful drone-transported in 2021. In leadership roles, Keshavjee serves as Surgeon-in-Chief of the Sprott Department of and Chief of at (UHN), as well as Professor of Thoracic at the . He was elected the 102nd President of the American Association for Thoracic in 2022 and has held positions on the boards of the International Society for Heart and Lung Transplantation and the Canadian Society of Transplantation. His contributions have earned him the Officer of the , Member of the , the 2020 ’s , UHN Inventor of the Year, and the F.N.G. Starr for lifetime achievement from the Canadian Medical Association, among numerous other honors including honorary doctorates, lifetime achievement awards, and in 2025 election as a of .

Early Life and Education

Early Life

Shaf Keshavjee was born in 1961 in , , to parents of South African origin who had emigrated to in the late 1950s. His father, Mohamed Keshavjee, was a businessman, and his mother worked at an airline; the family prospered enough to build their dream home in during this period. Growing up in until the age of 12, Keshavjee enjoyed a comfortable childhood filled with safaris and fond memories, while attending British-run schools that provided a strong educational foundation. From an early age, Keshavjee displayed a natural curiosity about biology and the workings of the human body, influenced by family discussions and environmental factors in Kenya. He was particularly inspired by articles linking cancer to immune system failures, which sparked his interest in medicine and surgery. An aptitude test during his childhood further reinforced this path, suggesting a career as a surgeon due to his precision and spatial skills. In the early 1970s, amid political and economic turmoil in Kenya—including deteriorating educational quality—the family immigrated to Toronto, Canada, in 1973, when Keshavjee was 12 years old, seeking better opportunities and to remain together. This move marked a significant transition, paving the way for his later pursuit of medical studies in Toronto.

Education and Training

Shaf Keshavjee earned his Doctor of Medicine (MD) degree with honors from the University of Toronto in 1985. He pursued advanced studies, completing a Master of Science (MSc) in experimental surgery from the University of Toronto in 1989, with his thesis focusing on innovations in organ preservation. Keshavjee then completed residencies in general surgery (1986–1991), followed by cardiac and thoracic surgery as part of the cardiothoracic residency (1991–1993), at the University of Toronto. To further specialize, he undertook fellowships in airway surgery at Harvard University and in heart-lung transplantation at the University of London.

Professional Career

Early Career Milestones

Following the completion of his advanced training in thoracic surgery, including a fellowship at Memorial Sloan-Kettering Cancer Center in 1993, Shaf Keshavjee joined the as an of in the Division of Thoracic Surgery in 1994. This appointment marked his entry into academic thoracic surgery at , where his educational background in general, cardiac, and thoracic surgery from the University of Toronto enabled his integration into the faculty focused on complex transplant procedures. As a surgical resident at , Keshavjee was involved in pioneering transplant cases, including participation in the world's first successful double-lung transplant performed in under the leadership of Joel Cooper. This early exposure to innovative transplant surgery at the institution laid the groundwork for his subsequent clinical contributions in the late and early 1990s, during which the Toronto Lung Transplant Program expanded its single- and double-lung procedures amid high early postoperative risks. In 1994, Keshavjee assumed initial research leadership roles at , becoming Director of the Thoracic Surgery Research Laboratory at the Toronto General , with a focus on transplant and advanced surgical techniques to address ischemia-reperfusion injury and allograft rejection. His work emphasized immunological mechanisms in allografts, including studies on roles in airway obliteration models. During the 1990s, Keshavjee established key collaborations with international researchers, culminating in foundational publications on donor optimization; notably, his 1992 study demonstrated the superiority of low-potassium solutions over traditional Euro-Collins for extended hypothermic preservation, reducing and improving posttransplant function in models. This research, stemming from his 1989 MSc on preservation solutions, represented an early milestone in enhancing donor viability and set the stage for clinical adoption.

Current Appointments and Leadership Roles

Shaf Keshavjee serves as Chief of Innovation at (UHN), a role he assumed in 2022 following his tenure as Surgeon-in-Chief from 2010 to 2022, where he leads initiatives to integrate advanced technologies into clinical practice across the network. In this capacity, he co-directs the AI Hub at UHN, emphasizing applications of artificial intelligence in transplantation and surgical outcomes to enhance organ assessment and patient care. Keshavjee served as Director of the Toronto Lung Transplant Program from 1997 to 2025, overseeing one of the world's largest and most innovative centers and guiding clinical operations, research integration, and multidisciplinary teams at until Marcelo Cypel succeeded him in February 2025. He holds the position of Senior Scientist at the Toronto General Hospital Research Institute (TGHRI) and directs the Latner Thoracic Research Laboratories, where he spearheads translational studies on lung preservation and regenerative therapies. Keshavjee is a of Thoracic and , as well as Vice Chair for in the Department of at the University of Toronto's Temerty Faculty of Medicine, roles that enable him to mentor emerging surgeon-scientists and foster interdisciplinary collaborations in thoracic medicine. Additionally, he occupies the Donald K. Jackson Chair in Lung Transplant Research, supporting his ongoing contributions to advancing transplant methodologies. He chairs various transplant committees at UHN and serves on international surgical boards, including membership on the American Association for Thoracic Surgery's Heart-Lung Transplantation Clinical Practice Standards Committee, influencing policy and standards in the field.

Scientific Contributions

Lung Preservation Techniques

Shaf Keshavjee developed low-potassium dextran (LPD) as part of his 1989 MSc thesis, which his team at the validated and implemented clinically in the late 1990s, commercially known as Perfadex, specifically designed for pulmonary grafts. This extracellular-type solution, composed of low-potassium dextran-40 with added glucose, tromethamine buffers, and antioxidants, minimizes endothelial swelling, maintains , and mitigates , thereby reducing IRI compared to intracellular solutions like Euro-Collins. The key innovation of the LPD solution lies in its ability to extend safe cold static preservation beyond traditional limits, enabling ischemic times of over 12 hours while preserving function. Experimental studies prior to clinical adoption demonstrated that LPD allowed for 24-hour preservation in animal models with minimal functional impairment, attributed to its low content preventing cellular and its component supporting microcirculatory stability. Clinically, Keshavjee's group implemented LPD in the Lung Transplant Program starting in April , reporting average ischemic times of approximately 5.8 hours without compromising outcomes. This extension facilitates longer-distance procurement, broadening the donor pool geographically.91016-2) Validation through prospective clinical trials in the early confirmed LPD's superiority in human . In a study comparing 46 LPD-preserved lungs to 48 Euro-Collins-preserved lungs, the incidence of severe PGD (defined as PaO₂/FiO₂ <150 mm Hg within 72 hours) was significantly reduced to 10.9% with LPD versus 20.8% with Euro-Collins (P=0.044). Additionally, early post-transplant oxygenation was improved, with mean PaO₂/FiO₂ ratios of 370 ± 133 mm Hg for LPD versus 310 ± 134 mm Hg for Euro-Collins (P=0.017), alongside shorter intensive care unit stays and fewer ventilator days. These results established LPD as a more effective agent for reducing IRI and enhancing immediate graft performance. The global impact of Keshavjee's LPD solution has been profound, establishing it as the standard for static cold lung preservation worldwide. Adopted by over 90% of lung transplant centers, Perfadex has been used in more than 40,000 procedures, consistently demonstrating lower PGD rates and better early outcomes across diverse populations. By improving preservation quality during transport, it has indirectly expanded access to viable donor lungs, though further enhancements like integration with ex vivo lung perfusion continue to build on this foundation.

Ex Vivo Lung Perfusion System

The Toronto Ex Vivo Lung Perfusion (EVLP) system was developed by and Marcelo Cypel in the late 2000s, marking a pivotal advancement in lung transplantation by enabling the assessment and rehabilitation of marginal donor lungs outside the body. First introduced clinically at in 2008, the system addressed the critical shortage of viable donor lungs, where only about 15-20% of potential organs are typically utilized due to injury or other risks. Building briefly on prior lung preservation techniques, EVLP shifted focus to active, dynamic reconditioning rather than passive storage.30034-6/pdf) Technically, the Toronto EVLP system utilizes normothermic perfusion via a dedicated organ console, maintaining lungs at body temperature (37°C) in a sterile environment to simulate physiological conditions. Donor lungs are connected to the circuit, where they are simultaneously ventilated with a protective strategy (tidal volume 6-8 mL/kg, positive end-expiratory pressure 5-10 cm H₂O) and perfused with an acellular solution, such as Steen Solution, at a flow rate increasing from 1.5 to 3.5 L/min. This process facilitates functional evaluation through metrics like partial pressure of oxygen to fraction of inspired oxygen ratio (>350 mm Hg), pulmonary (<500 dyn·s·cm⁻⁵), and compliance (>80% of predicted), while allowing therapeutic interventions to repair damage, including reducing via controlled ventilation and nutrient/oxygen delivery to reverse ischemia-reperfusion . The procedure typically lasts 4-6 hours, enabling real-time monitoring and decision-making on transplant suitability. The system was commercialized as the XVIVO Perfusion System (XPS) by XVIVO Perfusion Inc., receiving full U.S. Premarket Approval (PMA) in April 2019, following earlier humanitarian device exemption in 2014. Its widespread adoption has significantly expanded the donor pool, with EVLP enabling 20-30% more transplants from extended criteria donors by rehabilitating lungs previously deemed unsuitable. By 2025, over 1,000 EVLP procedures had been performed at alone, contributing to thousands more globally across five continents. Long-term clinical outcomes demonstrate the system's efficacy, with studies showing equivalent 5-year survival rates (approximately 60-70%) and freedom from chronic allograft dysfunction compared to transplants using ideal donor lungs. For instance, in a cohort of over 500 EVLP-treated lungs, primary graft dysfunction rates at 72 hours were similar (15-20%) to standard criteria lungs, with no increase in mortality or rejection. This has led to a 30% rise in annual lung transplants at adopting centers, underscoring EVLP's role in improving access and equity in transplantation.00738-X/abstract)

Gene Therapy in Lung Transplantation

Shaf Keshavjee has been a pioneer in applying to since the early 2000s, focusing on strategies to mitigate immune rejection and enhance graft viability by targeting inflammation at the molecular level. His research emphasizes delivery of therapeutic genes during to modify donor organs prior to implantation, aiming to reduce acute rejection and the reliance on lifelong . This approach builds on preclinical models demonstrating that genetic interventions can suppress post-transplant inflammatory responses, complementing organ preservation techniques for overall improved outcomes. A cornerstone of Keshavjee's work involves the use of viral vectors to deliver the interleukin-10 (IL-10) gene, an anti-inflammatory cytokine that dampens immune activation and ischemia-reperfusion injury in transplanted . Early studies utilized adenoviral vectors (AdhIL-10) delivered , showing sustained IL-10 expression for up to 30 days, reduced proinflammatory cytokines, and preserved function in rodent and porcine models of transplantation. In a landmark 2009 study, Keshavjee's team applied AdhIL-10 to injured human donor rejected for clinical use during at ; the treatment significantly improved oxygenation, , and overall , rendering previously unsuitable potentially viable for transplantation without adverse effects. Subsequent large-animal survival models confirmed the safety of this method, with transduced exhibiting lower acute rejection scores and better 14-day post-transplant function compared to controls. To address limitations of transient expression, Keshavjee's group explored lentiviral and (AAV) vectors for longer-term IL-10 delivery. Lentiviral IL-10 reduced chronic lung allograft dysfunction markers, such as and airway obliteration, in heterotopic tracheal transplant models over 15 months. vectors, noted for their low and sustained expression, have been tested in preclinical settings to achieve similar with minimal vector-related . These efforts culminated in human applications demonstrating feasibility and safety, though full clinical transplantation of gene-modified lungs remains in preclinical optimization as of 2025.32544-8) Keshavjee's innovations extend to next-generation editing tools like CRISPR-Cas9 for precise IL-10 upregulation and (MHC) modification, potentially enabling personalized therapies against chronic allograft rejection. In 2023 ex vivo human studies, CRISPR activation of endogenous IL-10 genes during attenuated inflammatory responses without off-target effects, paving the way for phase I safety trials. Ongoing research at as of 2025 investigates combined gene editing with extended ex vivo to further minimize needs and address chronic dysfunction, holding promise for broader adoption in transplant protocols.

Toronto Lung Transplant Program

Program Development

Under Shaf Keshavjee's leadership as Director since 1996, the Toronto Lung Transplant Program at , part of the (UHN), has built upon the institution's pioneering legacy in , which began with the world's first successful single-lung transplant in 1983. Keshavjee's directorship has focused on enhancing operational efficiency and expanding capacity within this established high-volume center, which had already performed over 500 transplants by 2003. The program experienced significant growth in transplant volume during Keshavjee's tenure, increasing from approximately 20-30 procedures annually in the early 2000s to more than 170 per year by , establishing it as the world's largest transplant program. This expansion was driven by strategic enhancements in donor management and logistical infrastructure at UHN, enabling the program to serve a population of over 14 million in while maintaining low rates around 3%. A key aspect of the program's development was the integration of lung (EVLP) into routine clinical practice, beginning with the world's first clinical application in 2008 and becoming standard by around 2010. This innovation allowed for the assessment and rehabilitation of marginal donor , and Keshavjee oversaw the creation of multidisciplinary protocols to ensure safe implementation across surgical, , and critical care teams. By 2019, EVLP had facilitated 24.6% of the program's transplants, contributing to sustained volume growth. Major milestones under Keshavjee's direction include reaching the 1,000th transplant in 2010, the 2,000th in 2018, and the 3,000th in 2023, with cumulative totals exceeding 3,400 by 2025. Additionally, the program developed standardized protocols for donor lung selection, incorporating EVLP criteria to optimize acceptance rates and reduce waitlist mortality, which has been integral to its operational evolution.

Clinical Impact and Milestones

The Lung Transplant Program has achieved one-year rates of approximately 80-84% for recipients, comparable to or slightly above international averages of around 80%, largely attributable to the integration of lung (EVLP) and protocols that enhance graft function and reduce early complications. These outcomes reflect the program's emphasis on marginal donor lung rehabilitation, enabling safer transplantation and contributing to extended graft , with five-year rates exceeding 60% in EVLP-treated cases compared to standard benchmarks. Key milestones underscore the program's pioneering role, including the first clinical use of EVLP in 2008, which revolutionized donor assessment and utilization. More recently, the program set records for the highest annual transplant volume in , performing over 200 procedures in 2023 and reaching a cumulative total of 3,000 transplants by that year, demonstrating scalable excellence in high-volume care. The program's broader impact extends globally through the training of over 500 international surgeons via fellowships and specialized academies, fostering worldwide adoption of advanced techniques. Additionally, data from approximately 1,000 EVLP cases have informed organ allocation policies, influencing national and international guidelines to prioritize extended-criteria donors and improve equity in distribution. Recent developments include the incorporation of AI-driven tools for donor-recipient matching starting in 2024, which has optimized organ selection through on compatibility and outcomes.

Awards and Recognitions

Professional Affiliations

Shaf Keshavjee is a Fellow of the Royal College of Physicians and Surgeons of (FRCSC) and the (FACS). He was elected as a of in 2025, recognizing his contributions to thoracic and transplantation . In leadership roles within professional societies, Keshavjee served as the 102nd President of the American Association for Thoracic Surgery from 2022 to 2023, following prior service as Treasurer and a member of its . He has also held positions on the of the International Society for Heart and Lung Transplantation. Keshavjee maintains board memberships with the Canadian Society of Transplantation and the Organ Donation and Transplantation Alliance of , contributing to national efforts in and transplantation policy. His advisory roles extend to global transplant networks, where he provides expertise on organ preservation and transplantation standards.

Major Awards and Honors

Shaf Keshavjee was appointed an Officer of the on November 20, 2014, recognizing his innovative contributions to thoracic surgery, particularly in and preservation techniques. He received the in 2013 for his leadership in advancing and in the province. Additionally, Keshavjee has been awarded two Queen Elizabeth II Medals in acknowledgment of his distinguished service to in the field of medicine. In recognition of his lifetime achievements, Keshavjee received the F.N.G. Starr Award from the Canadian Medical Association in 2021, the organization's highest honor for a physician demonstrating outstanding and inspiring contributions to the profession. He was also presented with the Lifetime Achievement Award from the Canadian Society of Transplantation, honoring his transformative impact on practices across the country. Earlier in his career, Keshavjee earned Canada's Top Award in 2000, celebrating his emerging and in thoracic . In 2011, he was awarded the Lister Prize in by the University of 's Department of Surgery, its most prestigious research honor, for his groundbreaking work in lung preservation and transplantation. Keshavjee shared the University Health Network's Inventor of the Year Award in 2018 with Dr. Marcelo Cypel for developing the Lung Perfusion System, a pivotal advancement in evaluating and repairing donor lungs. Keshavjee received the Governor General's Innovation Award in 2020 for his pioneering role in creating the Toronto Ex Vivo Lung Perfusion System, which has expanded access to viable donor lungs worldwide. In 2024, he was awarded the Medawar Prize by The Transplantation Society, the highest distinction for outstanding contributions to transplantation science. He has been conferred honorary Doctor of Science degrees from several universities, including Ryerson University (now Toronto Metropolitan University) and Queen's University, in tribute to his scholarly and clinical excellence. In 2025, Keshavjee was elected a Fellow of the Royal Society of Canada, joining the nation's most distinguished scholars for his profound influence on medical science and thoracic surgery.

Public Engagements

Shaf Keshavjee has actively engaged in public outreach to raise awareness about advancements in and . In 2010, he delivered a TEDMED talk titled "Can a human breathe outside the human body?", where he demonstrated the ex vivo (EVLP) technology by unveiling a functioning donor on stage, explaining its potential to repair and utilize otherwise unusable organs for transplant. The presentation, aimed at a general audience, has garnered over 100,000 views on , highlighting the life-saving impact of such innovations. Keshavjee has featured prominently in media interviews throughout the 2010s and into the 2020s, discussing transplant innovations and patient stories. He appeared on CBC Radio's The Current in 2017 to describe the groundbreaking case of a patient who survived six days without lungs while awaiting a transplant, emphasizing the urgency and creativity in critical care. In 2013, he spoke to CBC News about the challenges of lung transplants on the 30th anniversary of the program's first success, noting the organ's fragility and the need for improved preservation techniques. He has also been profiled in The New York Times in 2024, where he explained the role of perfusion machines in keeping organs viable outside the body, potentially expanding the donor pool. Through public lectures, Keshavjee has advocated for greater organ donation awareness globally and in Canada. He delivered a keynote on "The Future of Transplantation" at the 2021 National Donor Management Summit, addressing strategies to optimize organ recovery and utilization from donors. In Canada, as a leader in the Toronto Lung Transplant Program, he has promoted increasing donor registry participation to address the shortage of viable lungs, contributing to national efforts by organizations like the Canadian Society of Transplantation, where he has served on the board. In recent years, as Chief of Innovation at (UHN), Keshavjee has extended his public engagements to discussions on . In 2024, he co-led UHN's AI Hub initiatives, featured in articles exploring AI's role in enhancing diagnostic efficiency and transplant outcomes. He contributed to a 2025 INKspire piece on AI's current applications in , emphasizing collaborative advancements for patient care. Additionally, in April 2025, he co-presented on and AI for assessing donor lungs at a event, bridging innovation with practical transplant improvements.

References

  1. https://www.uhnresearch.ca/researcher/shaf-keshavjee
  2. https://www.cma.ca/get-involved/awards/fng-starr-award/dr-shaf-keshavjee
  3. https://www.jtcvs.org/article/S0022-5223(22)01165-5/fulltext
  4. https://www.aats.org/resources/1041
  5. https://surgery.utoronto.ca/faculty/shafique-keshavjee
  6. https://surgery.utoronto.ca/ShafKeshavjeeRSC
  7. https://www.uhn.ca/corporate/News/UHN_Podcasts/Behind_the_Breakthrough/Documents/BTB-S4E10-Keshavjee-Transcript.pdf
  8. https://ismailimail.blog/2017/11/26/dr-shaf-keshavjee-organs-by-design/
  9. https://www.dotscanada.com/about-us/doctor-bios/dr-shaf-keshavjee/
  10. https://www.ctsnet.org/home/skeshavjee
  11. https://www.blood.ca/en/blood/recognition-programs/national-awards-program/dr-shaf-keshavjee
  12. https://pubmed.ncbi.nlm.nih.gov/1370970/
  13. https://www.uhnresearch.ca/news/unlocking-future-ai-0
  14. https://traferox.com/staff/shaf-keshavjee-md/
  15. https://magazine.utoronto.ca/people/alumni-donors/u-of-t-graduates-in-science-and-math/
  16. https://www.instagram.com/p/DFiUIQmztkx/?hl=en
  17. https://www.uhnresearch.ca/news/royal-society-elects-new-scholars
  18. https://www.aats.org/about-the-aats/committees/heart-lung-transplantation-clinical-practice-standards-committee
  19. https://www.xvivogroup.com/perfadex-history/
  20. https://www.xvivogroup.com/products-services/perfadex-plus/
  21. https://www.uhnresearch.ca/news/uhn-inventors-year-0
  22. https://www.nejm.org/doi/full/10.1056/NEJMoa1014597
  23. https://pmc.ncbi.nlm.nih.gov/articles/PMC5599284/
  24. https://www.accessdata.fda.gov/scripts/cdrh/cfdocs/cfpma/pma.cfm?id=P180014
  25. https://www.xvivogroup.com/pressreleases/xvivo-has-received-market-approval-pma-from-the-fda-for-steen-solution-and-xps/
  26. https://pmc.ncbi.nlm.nih.gov/articles/PMC4241040/
  27. https://jamanetwork.com/journals/jamasurgery/fullarticle/2752280
  28. https://pubmed.ncbi.nlm.nih.gov/16918334/
  29. https://www.jhltonline.org/article/S1053-2498(24)00036-6/fulltext
  30. https://pubmed.ncbi.nlm.nih.gov/28052693/
  31. https://pubmed.ncbi.nlm.nih.gov/20368171/
  32. https://pubmed.ncbi.nlm.nih.gov/38310996/
  33. https://pubmed.ncbi.nlm.nih.gov/37315746/
  34. https://www.uhn.ca/Transplant/Lung_Transplant_Program
  35. https://www.sciencedirect.com/science/article/pii/S0022522303020129
  36. https://www.jtcvs.org/article/S0022-5223%2818%2931013-4/fulltext
  37. https://www.sciencedirect.com/science/article/pii/S0022522322009059
  38. https://www.uhn.ca/Transplant/Lung_Transplant_Program/Documents/TLTP-World-First-Infographic.pdf
  39. https://pmc.ncbi.nlm.nih.gov/articles/PMC8662477/
  40. https://pubmed.ncbi.nlm.nih.gov/37073734/
  41. https://www.uhn.ca/Transplant/Lung_Transplant_Program/Pages/fellowship.aspx
  42. https://www.uhn.ca/Transplant/Research/AI-transplant
  43. https://www.nature.com/articles/s41467-023-40468-7
  44. https://www.organdonationalliance.org/profile/shafique-keshavjee/
  45. https://www.gg.ca/en/honours/recipients/146-12316
  46. https://ismailimail.blog/2013/03/01/dr-shaf-keshavjee-named-to-ontarios-highest-honour/
  47. https://www.uhn.ca/Transplant/Lung_Transplant_Program/Pages/research.aspx
  48. https://uhnfoundation.ca/stories/drs-shaf-keshavjee-and-marcelo-cypel-named-joint-winners-of-uhn-inventor-of-the-year/
  49. https://uhnfoundation.ca/stories/dr-%25E2%2580%25AFshaf%25E2%2580%25AFkeshavjee%25E2%2580%25AFawarded-governor-generals-award/
  50. https://tts.org/110-tts/about/tts-awards-grants/520-tts-medawar-prize
  51. https://www.tedmed.com/talk/can-a-human-lung-breathe-outside-the-human-body/
  52. https://www.youtube.com/watch?v=T2EmuyHoMAI
  53. https://www.cbc.ca/radio/asithappens/as-it-happens-wednesday-edition-1.3951725/breathing-feels-brand-new-ontario-woman-lives-six-days-without-lungs-1.3951728
  54. https://www.cbc.ca/news/health/lung-transplant-patient-45-remembered-30-years-on-1.2417196
  55. https://www.nytimes.com/2024/04/02/health/organ-transplants-perfusion.html
  56. https://www.organdonationalliance.org/events/national-donor-management-summit/2021-national-donor-management-summit-recordings/
  57. https://inkspire.org/post/ai-in-health-care-where-are-we-now/
  58. https://www.youtube.com/watch?v=TlaZxhuFaac
Add your contribution
Related Hubs
User Avatar
No comments yet.