Preceding Heart Failure
Findings Could Lead to New Medications
That Halt or Reverse the Condition
A Johns Hopkins undergraduate student from Baltimore
County has contributed to new research showing that
electrical changes in the heart leading to heart failure
can occur long before a patient exhibits any clinical
symptoms. The initial changes can then spur a second,
later phase of changes that cause lethal heart rhythm
disturbances known as arrhythmias.
The study by Samuel Hahn, 21, a senior biomedical engineering major from Lutherville, Md.; and Fadi G. Akar, Ph.D., a research assistant professor at the Johns Hopkins School of Medicine, was the first to describe the time-course and nature of electrical abnormalities occurring during the development of heart failure. A manuscript of their work has been submitted to a peer-reviewed scientific journal. The two conducted their research in the laboratory of Gordon F. Tomaselli, professor of medicine and vice chair for research in the Department of Medicine.
"By the time most patients are diagnosed with heart failure, it's too late to really improve their condition," Akar said. "By defining the early electrical changes, we hope to identify new targets for therapy that can either reverse or, at the very least, hinder the progression of the vicious cycle of events that ultimately leads to death."
During heart failure, the pumping action of the heart becomes inadequate, resulting in a back pressure of blood along with congestion of the lungs and liver. Nearly 5 million Americans suffer from heart failure and more than 250,000 die annually from the condition, Hahn said. The incidence and prevalence of the disease continue to increase with the aging of the U.S. population.
"Despite remarkable improvements in medical therapy,
the prognosis of patients with heart failure remains very
poor, with almost 20 percent of patients dying within one
year of initial diagnosis, and over 80 percent within
eight years," Hahn said. "Of the deaths in patients with
heart failure, up to 50 percent are sudden and unexpected,
and the result of lethal arrhythmias."
For their study, Hahn and Akar isolated small samples of heart tissue about the size of large postage stamps from dogs in various stages of heart failure. Next, using a technique called optical mapping, they stained the tissue samples with voltage- or calcium-sensitive dyes, and shined a green light on the samples to excite the photosensitive dyes. The excited photosensitive dyes emitted light in different amounts depending upon the cellular voltage or calcium levels in the individual tissue samples. The emitted light was then collected by a sensitive optical detection system, converted to current and stored on a computer for analysis.
Hahn and Akar were able to demonstrate that electrical disturbances occurred in two distinct phases relative to mechanical abnormalities. The early changes involved a delay in the timing of electrical recovery of the heart muscle following each beat, whereas the later changes involved the loss of electrical synchrony among various regions of the heart. The early electrical changes likely contributed to mechanical abnormalities of the heart, and the later changes were a consequence of the compromised mechanical function. The scientists found that both the early and late changes in the electrical properties were required to cause a lethal arrhythmia.
"Sam was instrumental in analyzing the data, and helping perform the experiments," said Akar, noting that their procedure was a two-person job: one to ensure the health of the heart tissue being studied, and a second to ensure the performance of all experimental protocols and the proper acquisition of data by the computer.
"He's been a huge mentor for me," Hahn said of Akar.
"Being an undergraduate, you still have to have direction.
He's given me guidance, freedom and credit."
Tomaselli also praised Hahn for his persistence and devotion to the project.
"I am often hesitant to take on undergraduate students, particularly during the most rigorous parts of their programs, but I made an exception for Sam, and I am glad that I did," said Tomaselli. "Sam is the type of student who has the attributes to become a leader in biomedical research."
Hahn's work was supported through the Johns Hopkins Provost's Undergraduate Research Awards program. After graduating in May, he plans to attend medical school. "I hope to primarily be a clinical physician," he said, "but I definitely would love to have the freedom to pursue questions in medicine that I may have through research."
On March 10, Steven Knapp, university provost and senior vice president for academic affairs, will host the 12th annual Provost's Undergraduate Research Awards ceremony, which honors the 45 winners who conducted their projects in the summer and fall of 2004. Since 1993, about 40 students each year have received PURA grants of up to $3,000 to conduct original research, some results of which have been published in professional journals. The awards, funded through a donation from the Hodson Trust, are an important part of the university's commitment to research opportunities for undergraduates.
The Johns Hopkins University is recognized as the country's first graduate research university, and has been in recent years the leader among the nation's research universities in winning federal research and development grants. The opportunity to be involved in important research is one of the distinguishing characteristics of an undergraduate education at Johns Hopkins.
The Provost's Undergraduate Research Awards program provides one of these research opportunities, open to students in each of the university's four schools with full-time undergraduates: the Krieger School of Arts and Sciences, the Whiting School of Engineering, the Peabody Conservatory and the School of Nursing.
Color photos of the researchers are available; contact Phil Sneiderman.
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