Congestive heart failure is the final common pathway of diverse etiologies that result in impaired systolic and diastolic function, deleterious activation of neurohumoral pathways, and high morbidity and mortality. Many studies published in 1995 significantly added to our understanding of the pathophysiologies of heart failure at the cellular level. Because a common accompaniment to all forms of low output heart failure are hypertrophy and contractile dysfunction of the cardiomyocyte, applications of the techniques of molecular and cell biology to animal models that demonstrate this phenomenon are providing new insights into the mechanisms responsible for this important clinical problem. In the past year, critical information was derived from animal models that mimic human cardiac hypertrophy and failure. Likewise, genetically engineered mice in which a gene product of interest is overexpressed or eliminated provided critical information, in particular regarding the roles of phospholamban and beta-adrenergic receptor kinase 1 in mediating the contractile responses of the heart to beta-adrenergic stimulation. Furthermore, study of human myocardial tissue from patients with end-stage cardiomyopathy continues to provide insight into the diverse etiologies of heart failure. The recent applications of the techniques of molecular and cell biology to this clinical problem are likely to accelerate our understanding of the complex mechanisms responsible for this syndrome.