Développement et validation de matériaux biomimétiques pour l'optimisation de la transplantation d'ilôts pancréatiques / Development and validation of biomimetic materials for optimization of islet transplantation

Schaschkow, Anaïs

23 September 2016

La transplantation d’îlots pancréatiques est une des thérapies proposées aux diabétiques de type 1. Cependant, la perte d’un nombre considérable d’îlots durant le processus est un frein à l’expansion de la thérapie (en culture : anoïkis et hypoxie ; lors de la greffe : réactions inflammatoires intenses déclenchées lors de l’infusion intra-portale). L’objectif de ce travail était de valider un biomatériau permettant d’optimiser la transplantation d’îlots. Nous avons pu démontrer l’efficacité du plasma réticulé sur la survie des îlots en culture via une diminution drastique de l’anoïkis. Nous avons également mis au point une technique de greffe intra-tissulaire à l’aide d’HPMC combinée à du plasma, permettant de reverser le diabète de manière semblable à la greffe hépatique. Ces travaux ont donc permis de valider l’importance d’un support de culture adapté, mais aussi du site receveur de la greffe et placé l’omentum comme site de choix pour ce type de greffe. / Pancreatic islet transplantation is one of the therapies proposed to type 1 diabetic patients. However, the considerable loss of islets during the process is an obstacle to the expansion of this therapy (culture: anoïkis and hypoxia; at graft time: intense inflammatory reactions triggered by intra-portal islet infusion). The objective of this work was to validate a biomaterial that can optimize islet transplantation. We were able to demonstrate the effectiveness of cross-linked plasma on the islet survival in culture through a drastic reduction of anoikis. We also design a new intra-tissular grafting technique using HPMC combined with plasma, which reversed diabetes in a manner similar to the liver. This work allowed validating the importance of an adapted culture support, but also the one of the recipient site. Also, this work placed the omentum as an excellent recipient site for this kind of transplant.

Diabète

Transplantation d’îlots

Biomatériaux

Site d’implantation

Diabetes

Islet transplantation

Biomaterials

Implantation site

616.4

617.95

Investigation of clinical utility of contrast-enhanced MRI in the diagnosis of ectopic pregnancy / 異所性妊娠の診断における造影MRIの有用性の検討

Nishio, Naoko

23 September 2020

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第22724号 / 医博第4642号 / 新制||医||1045(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 戸井 雅和, 教授 小川 修, 教授 黒田 知宏 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

ectopic pregnancy

MRI

contrast-enhanced MRI

implantation site

reading experience

490

Implantation-Site Dependent Differences in Engraftment and Function of Transplanted Pancreatic Islets

Lau, Joey

January 2008

<p>Transplanting pancreatic islets into the liver through the portal vein is currently the most common procedure in clinical islet transplantations for treating patients with brittle type 1 diabetes. However, most islet grafts fail within a 5-year period necessitating retransplantation. The vascular connections are disrupted at islet isolation and implanted islets depend on diffusion of oxygen and nutrients in the immediate posttransplantation period. Rapid and efficient revascularization is of utmost importance for the survival and long-term function of transplanted islets. </p><p>In this thesis, the influence of the implantation microenvironment for islet engraftment and function was studied. Islets were transplanted into the liver, the renal subcapsular site or the pancreas. Islets implanted into the liver contained fewer glucagon-positive cells than islets implanted to the kidney and endogenous islets. Intraportally transplanted islets responded with insulin and glucagon release to secretagogues, but only when stimulated through the hepatic artery. Thus, the intrahepatic grafts were selectively revascularized from the hepatic artery. The vascular density in human islets transplanted into the liver of athymic mice was markedly lower when compared to human islets grafted to the kidney. Islets implanted into their physiological environment, the pancreas, were markedly better revascularized. Insulin content, glucose-stimulated insulin release, (pro)insulin biosynthesis and glucose oxidation rate were markedly decreased in transplanted islets retrieved from the liver, both when compared to endogenous and transplanted islets retrieved from the pancreas. Only minor changes in metabolic functions were observed in islets implanted into the pancreas when compared to endogenous islets. </p><p>The present findings demonstrate that the microenvironment has a major impact on the engraftment of transplanted islets. Elucidating the beneficial factors that promote engraftment would improve the survival and long-term function of transplanted islets. Ultimately, islet transplantation may be provided to an increased number of patients with type 1 diabetes.</p>

Cell biology

Type 1 diabetes

pancreatic islets

human islets

islet transplantation

vascular engraftment

revascularization

implantation-site

microenvironment

vascular density

insulin release

(pro)insulin biosynthesis

glucose oxidation

Cellbiologi

Implantation-Site Dependent Differences in Engraftment and Function of Transplanted Pancreatic Islets

Lau, Joey

January 2008

Transplanting pancreatic islets into the liver through the portal vein is currently the most common procedure in clinical islet transplantations for treating patients with brittle type 1 diabetes. However, most islet grafts fail within a 5-year period necessitating retransplantation. The vascular connections are disrupted at islet isolation and implanted islets depend on diffusion of oxygen and nutrients in the immediate posttransplantation period. Rapid and efficient revascularization is of utmost importance for the survival and long-term function of transplanted islets. In this thesis, the influence of the implantation microenvironment for islet engraftment and function was studied. Islets were transplanted into the liver, the renal subcapsular site or the pancreas. Islets implanted into the liver contained fewer glucagon-positive cells than islets implanted to the kidney and endogenous islets. Intraportally transplanted islets responded with insulin and glucagon release to secretagogues, but only when stimulated through the hepatic artery. Thus, the intrahepatic grafts were selectively revascularized from the hepatic artery. The vascular density in human islets transplanted into the liver of athymic mice was markedly lower when compared to human islets grafted to the kidney. Islets implanted into their physiological environment, the pancreas, were markedly better revascularized. Insulin content, glucose-stimulated insulin release, (pro)insulin biosynthesis and glucose oxidation rate were markedly decreased in transplanted islets retrieved from the liver, both when compared to endogenous and transplanted islets retrieved from the pancreas. Only minor changes in metabolic functions were observed in islets implanted into the pancreas when compared to endogenous islets. The present findings demonstrate that the microenvironment has a major impact on the engraftment of transplanted islets. Elucidating the beneficial factors that promote engraftment would improve the survival and long-term function of transplanted islets. Ultimately, islet transplantation may be provided to an increased number of patients with type 1 diabetes.

Cell biology

Type 1 diabetes

pancreatic islets

human islets

islet transplantation

vascular engraftment

revascularization

implantation-site

microenvironment

vascular density

insulin release

(pro)insulin biosynthesis

glucose oxidation

Cellbiologi