Researchers at the University of Maryland School of Medicine in Baltimore and the University of Colorado School of Medicine in Denver have identified a common genetic variation that could help determine whether a person with heart failure would benefit from beta-blockers.
The findings are significant because it often takes several months to determine if a specific betaa-blocker is working for a patient. Time is of the essence because one in five patients with heart failure will die within a year of diagnosis.
The findings are published in the Proceedings of the National Academy of Sciences ( PNAS ).
In a study that compared an investigational beta-blocker to a placebo, researchers found a 38 percent reduction in the death rate among patients who took the beta-blocker and who also had two copies of a genetic variant called arginine ( Arg-389 ). In addition, these patients had a 34 percent reduction in another benchmark, the combined number of hospitalizations and deaths. People with another genetic variant, glycine ( Gly-389 ), had no response to the drug compared to the placebo.
" For the first time, we have a genetic test that will help guide us to the best treatment for individual patients with heart failure and provide what has been called personal medicine," says the study's principal investigator, Stephen B. Liggett, at the University of Maryland School of Medicine." This personalized therapy, based on genes, gives us an opportunity to tailor therapy in a way that we really were never able to do before," says Liggett.
The genetic variance occurs in the beta-1 adrenergic receptor, which is the target for beta-blockers. People either have the Arg variant or the Gly variant. Liggett says the type of variant does not predispose a person to develop heart failure. Beta-blockers reduce demand on the heart, slow the heart rate and prevent irregular heartbeat. They block receptors in the heart that normally respond to adrenalin and cause the heart to pump stronger. In heart failure, the heart's impaired pumping function causes adrenalin to make the heart work harder. Beta-blockers allow the heart to get some relief from the overactive pumping, develop a normal cellular structure and shrink in size.
Despite their usefulness, beta-blockers and other heart failure drugs present a treatment challenge, because their effect on a given patient is somewhat unpredictable. " It has been difficult to explain the variability of response to treatment, even among patients with similar ages and other characteristics. This is especially the case with beta-blockers, one of the cornerstones in the treatment of heart failure," says Michael Bristow, at the University of Colorado School of Medicine and one of the study's authors. " We hypothesized that the variability in response to beta-blockers was due to important functional genetic variation in the beta-1 receptor, and this indeed appears to be the case."
The researchers' conclusions are based in part on a retrospective look at data from a placebo-controlled study of the drug Bucindolol, during which 1,040 heart failure patients were followed for up to four years. The study volunteers also consented to participate in a genetic sub-study which involved an analysis of their DNA, a process called genotyping. The researchers looked at four parameters: whether the patients had the real drug or the placebo, and whether they had the Arg-389 receptor or the Gly-389 receptor.
In addition, the researchers examined normal donor hearts as well as hearts removed from patients who were receiving heart transplants and discovered that, compared to Gly-389, hearts with two copies of the Arg gene had a greater response to an adrenaline-like compound called Isoproterenol as well as Bucindolol and several other drugs.
The researchers also looked at the genetic variants and the response to the beta-blocker in black patients compared to whites, and found that genetics and not race determined who benefited best from the drug. " We believe it is inappropriate to use a race-based prescribing approach, because within any given ethnic or racial population there is a genetic variability with that group. Therefore, some people will have the response gene and some will not," says Liggett.
Heart failure affects nearly five million Americans, according to the Heart Failure Society of America. Less than 50 percent of patients live past five years after their initial diagnosis and less than 25 percent are alive at 10 years. The risks of heart failure include high blood pressure, a prior myocardial infarction, abnormal heart valves and diabetes. In addition, a large number of patients have a form of heart failure called idiopathic cardiomyopathy, where no predisposing factor can be identified.
Heart failure develops when the heart is not able to pump enough blood to meet the body's needs. The heart compensates for this loss in pumping capacity by growing larger, increasing muscle mass and pumping faster to increase the heart's output. These changes typically occur over a long period of time, masking the problem. Eventually, the heart and the body cannot keep up with the demands, and the person begins to experience the fatigue and breathing problems that often are the first signs of the disease.
Source: University of Maryland Medical Center, 2006
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