How do we continue to make giant leaps in medicine? What new treatment or approach will allow us to make the greatest gains for patients, in the most effective and efficient ways possible? Where will the next breakthrough come from? These are questions that academics, clinicians, hospital CEOs and medical school deans are constantly asking as we seek to meet the challenges of modern healthcare.
People and technology have a clear role in the answer, but there is another critical factor that is often overlooked: space, and the spontaneity and ideas generated when scientists and clinicians have the ability to work side-by-side.
A great example of this came up during a recent panel discussion at our SINAInnovations conference. Eric M. Genden, MD, and Chief of the Division of Head and Neck Oncology, discussed his experience on a recent case in which a patient had distant metastatic disease that he and his team could not get to surgically. While working on the case, he happened to bump into Ross Cagan, PhD and Associate Dean of the Graduate School of Biomedical Sciences. Through their conversation, Dr. Cagan suggested getting a biopsy of the tumor, sequencing it, dropping it into fruit flies, and crossing it with 150 different types of chemotherapeutic agents to see what kills the tumor. Over their chance meeting and a cup of coffee, they mapped out a targeted solution to treat the patient.
It’s been reported that James Eagan Holmes, more infamously known as the movie-theatre gunman who killed 12 people during a midnight showing of Batman in Aurora, Colorado, sent a text to a classmate asking whether she knew what “dysphoric mania” was. (It is a bipolar condition that in its extremes, can include mania and paranoid delusions.) Did he have it?
Similarly we wonder whether a near-death accident in childhood, one that was marked by severe head trauma, affected Jeffrey T. Johnson, a.k.a. the Empire State Building gunman, so deeply that it influenced his decision to kill his former boss on his way into the office. Is that possible?
So often we focus on the mental conditions and environmental stressors that may have influenced the perpetrators of horrendous violence. Likewise, in the immediate aftermath of a horrific event—be it violence, an accident, or a devastating natural disaster—the media reports on the nightmares, sleeplessness, anxiety, and other classic sequelae experienced by the trauma survivors. Too rarely, though, do we explore the mental and emotional recovery of trauma survivors, and that of the family, friends, and colleagues who were affected by a victim’s death or lifelong disabilities.
Barbara Murphy, MD, MB, BAO, BCh, FRCPI, a renowned transplant immunology researcher, has been named the Chair of the Samuel F. Bronfman Department of Medicine at Mount Sinai School of Medicine. The appointment makes Dr. Murphy the first female chair of Medicine of an academic medical center in New York City. She has been the acting chair of the Department of Medicine, the largest department at Mount Sinai, since June, and Chief of its Division of Nephrology since 2004.
“For the past eight years, Dr. Murphy has demonstrated incredible leadership in the Division of Nephrology and helped elevate Mount Sinai’s already renowned transplant programs to a new level,” said Dennis S. Charney, MD, Anne and Joel Ehrenkranz Dean, Mount Sinai School of Medicine, and Executive Vice President for Academic Affairs, The Mount Sinai Medical Center. “Her innovative approach to patient care, research, and education will undoubtedly extend the reach of Mount Sinai’s Department of Medicine as one of the finest in the nation.”
Mount Sinai School of Medicine recently unveiled its new supercomputer that is helping researchers unlock the intricate mechanisms that lead to human diseases, and hasten the discovery of treatments for them. The computer, named Minerva, after the Roman goddess of wisdom and medicine, was custom-built by Patricia Kovatch, the school’s first Associate Dean for Scientific Computing.
Minerva provides 64 million hours of computation per year. It has 7,680 processing cores, a peak speed of 70,000 gigaflops, and 30 terabytes of random access memory, making it one of the nation’s highest-performing computers in academic medicine.
“With its tremendous strength and speed, Minerva enables scientists to analyze and manipulate large data sets by running longer, more complex simulations,” says Ms. Kovatch. “This state-of-the-art technology will empower Mount Sinai’s researchers to expand the boundaries of their scholarly inquiry.” The computer’s ability to provide researchers with real-time computation of advanced molecular models and a quick analysis of genomic patterns will help Mount Sinai usher in a new era of personalized and precision medicine. Eric Schadt, PhD, Director of the Institute for Genomics and Multiscale Biology, and his researchers have been using Minerva extensively in their work.