OBJECTIVE: The aim was to measure changes in the numbers and size of ventricular myocytes in human hearts with marked ventricular hypertrophy and no clear signs of cardiac failure, to determine whether myocyte cellular hypertrophy is the only factor involved in the increase in cardiac mass. METHODS: Morphometric techniques were applied to estimate the number of myocyte nuclei per unit volume of myocardium which, in combination with the determination of the volume percent of myocytes, allowed the computation of the average myocyte cell volume per nucleus and total number of myocyte nuclei in the ventricles. Subsequently, the volume fraction of replacement fibrosis in the tissue was assessed and absolute component volumes in the ventricles obtained. RESULTS: Eight hypertrophied human hearts, weight 561(SD 68) g, were collected at necropsy from hypertensive patients who died from non-cardiac causes and were compared with eight normal hearts, weight 387(37) g, obtained from healthy individuals who also died from non-cardiac causes. With cardiac hypertrophy, left and right ventricular weight increased by 53% and 57%, whereas myocyte cell volume increased by 112% and 84%, respectively. The disproportion between the increase in ventricular weight and the increase in myocyte volume was due to a 30% and 16% loss in left and right ventricular myocytes following hypertensive hypertrophy. Myocyte loss also provoked a 319% and a 188% increase in the amount of replacement fibrosis in the left and right ventricular myocardium. These tissue and cellular processes resulted in an expansion in ventricular mass which exceeded the thickening of the wall so that an increase in cavitary volume occurred in both ventricles. CONCLUSIONS: Myocyte cellular hypertrophy is responsible for ventricular hypertrophy in hypertensive cardiomyopathy in its compensated stage. Myocyte loss precedes the impairment in ventricular pump function and may be implicated in the initiation of ventricular maladaptation.
OBJECTIVE: The aim was to measure changes in the numbers and size of ventricular myocytes in human hearts with marked ventricular hypertrophy and no clear signs of cardiac failure, to determine whether myocyte cellular hypertrophy is the only factor involved in the increase in cardiac mass. METHODS: Morphometric techniques were applied to estimate the number of myocyte nuclei per unit volume of myocardium which, in combination with the determination of the volume percent of myocytes, allowed the computation of the average myocyte cell volume per nucleus and total number of myocyte nuclei in the ventricles. Subsequently, the volume fraction of replacement fibrosis in the tissue was assessed and absolute component volumes in the ventricles obtained. RESULTS: Eight hypertrophiedhuman hearts, weight 561(SD 68) g, were collected at necropsy from hypertensivepatients who died from non-cardiac causes and were compared with eight normal hearts, weight 387(37) g, obtained from healthy individuals who also died from non-cardiac causes. With cardiac hypertrophy, left and right ventricular weight increased by 53% and 57%, whereas myocyte cell volume increased by 112% and 84%, respectively. The disproportion between the increase in ventricular weight and the increase in myocyte volume was due to a 30% and 16% loss in left and right ventricular myocytes following hypertensive hypertrophy. Myocyte loss also provoked a 319% and a 188% increase in the amount of replacement fibrosis in the left and right ventricular myocardium. These tissue and cellular processes resulted in an expansion in ventricular mass which exceeded the thickening of the wall so that an increase in cavitary volume occurred in both ventricles. CONCLUSIONS: Myocyte cellular hypertrophy is responsible for ventricular hypertrophy in hypertensive cardiomyopathy in its compensated stage. Myocyte loss precedes the impairment in ventricular pump function and may be implicated in the initiation of ventricular maladaptation.
Authors: Shulin Cao; Yasser Aboelkassem; Ariel Wang; Daniela Valdez-Jasso; Jeffrey J Saucerman; Jeffrey H Omens; Andrew D McCulloch Journal: Philos Trans A Math Phys Eng Sci Date: 2020-05-25 Impact factor: 4.226
Authors: Otavio R Coelho-Filho; Ravi V Shah; Richard Mitchell; Tomas G Neilan; Heitor Moreno; Bridget Simonson; Raymond Kwong; Anthony Rosenzweig; Saumya Das; Michael Jerosch-Herold Journal: Circulation Date: 2013-08-02 Impact factor: 29.690
Authors: Otavio R Coelho-Filho; François-Pierre Mongeon; Richard Mitchell; Heitor Moreno; Wilson Nadruz; Raymond Kwong; Michael Jerosch-Herold Journal: Circ Cardiovasc Imaging Date: 2012-11-15 Impact factor: 7.792