Madison P Wang scite author profile

Madison P Wang

2Publications

5Citation Statements Received

71Citation Statements Given

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Wayne State University

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Membrane stabilizer Poloxamer 188 improves yield of primary isolated rat cardiomyocytes without impairing function

2020

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Intact cardiomyocytes are used to investigate cardiac contractility and evaluate the efficacy of new therapeutic compounds. Primary enzymatic isolation of adult rodent cardiomyocytes has limitations, including low cardiomyocyte survival, which is likely due to ischemic conditions and/or membrane damage. The addition of Poloxamer 188 (P188) has been used to reduce ischemia‐ and membrane‐related damage in ischemia–reperfusion and muscular dystrophy studies. P188 stabilizes membranes, reducing cell death. Cardiomyocytes were isolated from rats, under three conditions: (1) using standard isolation solutions, (2) with P188 added during cannulation (ischemic event), and (3) with P188 added during cannulation, enzymatic digestion, and trituration. Cell survival was assessed by quantifying the number of rod‐shaped versus contracted cells on the day of isolation and up to 3 days post‐isolation. Adding P188 only during cannulation yielded improved survival on the day of isolation. Little difference in survival was seen among the three conditions in the days post‐isolation. Cardiomyocyte function was assessed by measuring calcium transients and unloaded sarcomere lengths for up to 2 days post‐isolation. P188 did not consistently alter calcium handling or sarcomere shortening in the isolated cardiomyocytes. We conclude that the addition of P188 to the cannulation (e.g., wash) of the isolated heart may improve initial survival of cardiomyocytes upon primary enzymatic isolation.

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Abstract 446: Exploring the Myosin-dependence of Mechanical Control of Relaxation

Bukowski

Matus

Dlugas

et al. 2020

Circulation Research

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Impaired relaxation is a prevalent form of diastolic dysfunction, present in nearly all cases of heart failure and in many asymptomatic adults. To date, there are no accepted treatments for impaired relaxation, despite its biochemical control by calcium reuptake, thin filament deactivation, and crossbridge kinetics. Mechanical modification of relaxation was previously theorized to occur through afterload; we, however, have recently shown that relaxation was actually modified by the strain rate of myocardial lengthening. We termed this Mechanical Control of Relaxation, or the sensitivity of the relaxation rate to the strain rate. The mechanisms underlying Mechanical Control of Relaxation are unknown, but computational models and our preliminary data suggest a dependence on myosin detachment. The objective of this study was to evaluate whether myosin was a modifying factor of Mechanical Control of Relaxation. Intact cardiac trabeculae and cardiomyocytes were obtained from rats (Sprague Dawley both treated and untreated with propylthiouracil, Spontaneously Hypertensive, and Wistar Kyoto strains) and underwent load-clamp studies. Mechanical Control of Relaxation could be improved by reducing preload (length) 5%, increasing the sensitivity of the relaxation rate to strain rate by 28±16%. Treatment with 400μM Omecamtiv Mecarbil, a myosin-ATPase specific drug, induced similar increases. Myosin isoform differences were also studied. Collagenase treatment of intact trabeculae increased Mechanical Control by 21±3%; intact myocyte studies show no collagen-dependence. These data provide evidence that the properties of myosin’s response to strain rate are major factors that modify Mechanical Control of myocardial Relaxation.

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Madison P Wang

Membrane stabilizer Poloxamer 188 improves yield of primary isolated rat cardiomyocytes without impairing function

Abstract 446: Exploring the Myosin-dependence of Mechanical Control of Relaxation

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