Abstract P3069: The Impact Of Lymphatic Vasculature Post-Cardiac Transplantation On Allograft Function, Fibrotic Remodeling, And Lymphatic Drainage

Abstract

Lymphatic drainage inherently modulates cardiac function by maintaining the immune response and tissue-fluid homeostasis. During cardiac transplantation, the lymphatic collecting vessels are severed at the time of donor heart excision and not surgically reconstructed in the recipient. We hypothesize severed cardiac lymphatics contribute to transplant rejection and reduced cardiac function by influencing myocardial edema and immune cell transit. Methods: A heterotopic abdominal heart transplant (HAHT) rodent model permitted the immunologic evaluation of transplant rejection as supported in past literature. Echocardiography confirmed allograft survival via active contraction, while histologic quantification of lymphatic vessels and fibrosis were obtained for native and transplanted rodent hearts (n=3). Lymphatic drainage was assessed via intramyocardial injection of fluorescein isothiocyanate (FITC)-dextran. Results: Electrocardiographic impulses detected during the echocardiograms revealed additional QRS complexes attributed to contractions of the transplanted hearts. Histologic analysis of fibrosis in rodent allografts at an early timepoint exhibited increases in total tissue accumulation (1.48 – 5.15 fold) and significant increases in various focal regions (left ventricle, ***p < 0.001; interventricular septum, ****p < 0.0001) compared to the native hearts. Furthermore, large amounts of cellular infiltrate and marginal increases in cardiac diameter (1.10 – 1.42 fold) were observed in the transplants. While the scarcity of immunofluorescence signal for lymphatic markers has caused cardiac lymphatic quantification to be inconclusive, evaluation of lymphatic transport revealed fluctuating time-dependent circulating FITC levels (0.002 - 0.010 mg/mL; *p < 0.05) suggesting multi-teared compartmental release properties between the microcirculatory system, lymphatic system, and cardiac tissue. Conclusion: The HAHT rodent model provides a promising modality to assess both lymphatic transport and transplant rejection. Moreover, these studies will progress understanding of transplant rejection’s pathological intricacies and provide the groundwork for lymphangiogenic-based therapeutic intervention.