TRIM Enhances Angiogenesis in Dystrophic Muscle 140 Days Post Treatment

Abstract

Background: Duchenne Muscular Dystrophy (DMD) causes limb muscle dysfunction and impaired mobility while promoting ischemia in effected muscles. For treatment, we developed a novel biomaterial, Time Release Ion Matrix (TRIM), that promotes angiogenesis and enhances muscle structure and function in dystrophic (D2. mdx) mice at 14- and 70-days post injection (dpi). Whether TRIM remains effective at 140 dpi is unknown. Hypothesis: At 140 dpi in D2. mdx mice TRIM will: 1) enhance isometric force and myofiber cross-sectional area (CSA) of the tibialis anterior (TA) muscle; and 2) stimulate angiogenic growth factors and increase vascularity. Methods: The right and left TA of adult male D2. mdx mice (male, n=7-8, age 7 months) were injected with saline alone (control) or 250 μg of TRIM suspended in saline. At 140 dpi, the left TA muscle was isolated for in situ muscle force measurements and histological analysis; the right TA was frozen for biochemical analysis. Muscle cross-sections were immunostained for laminin (myofiber borders), DAPI (nuclei), and CD31 (endothelial cells). Vascular endothelial growth factor (VEGF) ELISA and immunoblots were performed on muscle homogenates. Results: No difference in peak isometric force was recorded between groups at 140 dpi (means ± SE: TRIM, 65.4 ± 2.7g; Saline, 62.7 ± 1.5g; P= 0.34). TRIM enhanced the relative frequency of myofibers >1000 μm2 by 27% vs. saline (TRIM, 56 ± 2%; Saline, 44 ± 3%; P= 0.006). DAPI staining revealed a 36% increase in central nuclei indicating myofiber regeneration (TRIM, 30.0 ± 1.7%; Saline, 22.0% ± 2.5; P=0.02). Microvessel area (CD31 staining, μm2) was 2.5-fold greater in treated TA’s (TRIM, 131 ± 12 μm2; Saline, 53 ± 6 μm2, P=0.0001). In muscle homogenates, TRIM had no effect on [VEGF] (TRIM, 102 ± 5%; Saline, 100 ± 4%; P= 0.79), while STAT3 activation was greater (TRIM, 129 ± 11%; Saline, 100 ± 7%; P= 0.04). Conclusion: At 140 days following injection of TRIM into the TA muscle of dystrophic mice, peak isometric force was unchanged while myofiber CSA was enhanced. Furthermore, TRIM promotes angiogenic growth factors and muscle vascularity, which should promote the ability to sustain physical activity. University of Missouri Coulter Biomedical Accelerator (SSS), American Physiological Society SURF (AGN), Texas A&M Department of Kinesiology and Sport Management (ABM). This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.