The zebrafish (Danio rerio) possesses various attractive features including rapid development, ease of genetic manipulation and low cost of maintenance, and has become a popular animal model for the study of cardiovascular diseases and for the screening of drugs with therapeutic or adverse effects. Herein, we demonstrate a novel application of pseudo-dynamic three-dimensional (3D) cardiac imaging for precise determination of the cardiac function of zebrafish. With this technique, we particularly determined individual important parameters of the cardiac function of zebrafish larvae (including ventricular stroke volume, ejection fraction, cardiac output, heart rate, diastolic filling function and ventricular mass). We compared critically the cardiac parameters obtained with our approach with those derived with conventional 2D approximation termed “fit-to-ellipse”, and show that our 3D approach is superior in several respects. To demonstrate potential applications of our approach to pharmaceutical development, we evaluated specifically the inotropic and chronotropic response of the heart of zebrafish subject to pharmacological interventions of epinephrine, esmolol and doxazosin. Our results show that zebrafish exhibited pharmacological responses to these cardioactive drugs in a way similar to human beings do. We revealed also an impaired cardiac function of a zebrafish model of cardiomyopathy induced by a treatment of doxorubicin. Given the growing interest in the application of zebrafish in both basic and applied biomedical research, we anticipate that our approach should have widespread applications in not only pharmaceutical development but also studies of cardiac development, pathophysiology or therapies targeting human heart diseases.