Exploring Insulin Production Following Alveolar Islet Transplantation (AIT).

Hien Lau,Wojciech Kielan,Sven Stieglitz,Maya Karine Labbé,Piotr Frelkiewicz,Jonathan Robert Todd Lakey,Shiri Li,Michael Alexander,Veria Khosrawipour,Tanja Khosrawipour

doi:10.3390/ijms221910185

Abstract

Recent studies have demonstrated the feasibility of islet implantation into the alveoli. However, until today, there are no data on islet behavior and morphology at their transplant site. This study is the first to investigate islet distribution as well insulin production at the implant site. Using an ex vivo postmortem swine model, porcine pancreatic islets were isolated and aerosolized into the lung using an endoscopic spray-catheter. Lung tissue was explanted and bronchial airways were surgically isolated and connected to a perfusor. Correct implantation was confirmed via histology. The purpose of using this new lung perfusion model was to measure static as well as dynamic insulin excretions following glucose stimulation. Alveolar islet implantation was confirmed after aerosolization. Over 82% of islets were correctly implanted into the intra-alveolar space. The medium contact area to the alveolar surface was estimated at 60 +/− 3% of the total islet surface. The new constructed lung perfusion model was technically feasible. Following static glucose stimulation, insulin secretion was detected, and dynamic glucose stimulation revealed a biphasic insulin secretion capacity during perfusion. Our data indicate that islets secrete insulin following implantation into the alveoli and display an adapted response to dynamic changes in glucose. These preliminary results are encouraging and mark a first step toward endoscopically assisted islet implantation in the lung.

Highlights

Type I diabetes mellitus (T1DM) is an autoimmune disorder characterized by the destruction of β-cells of pancreatic Langerhans islets
A variety of secondary diseases can emerge as a result of disrupted insulin secretions and imbalanced glycemic control
The limited availability of quality human islets has encouraged attempts to perform islet xenotransplantation [3,4], which requires the use of non-human xenogeneic pancreatic islets donors

Summary

Introduction

The scientific community has focused on tackling a wide range of challenges when attempting xenograft transplantations in a new host. Some of these challenges include possible interactions with the host’s immune system, endurance and longevity of the graft at its implantation site, vascular supply, and complications during and following transplantations. The risk of disease transfer from the graft must be considered, including porcine endogenous retrovirus in the case of swine grafts [9]. This becomes an even greater issue with higher levels of immune suppression

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