Photoacoustic imaging of angiogenesis in a subcutaneous islet transplant site in a murine model

Wei Shi; Rena Pawlick; Antonio Bruni; Yasmin Rafiei; Andrew R. Pepper; Boris Gala-Lopez; Min Choi; Andrew Malcolm; Roger J. Zemp; A. M.James Shapiro

doi:10.1117/1.JBO.21.6.066003

Photoacoustic imaging of angiogenesis in a subcutaneous islet transplant site in a murine model

Wei Shi, Rena Pawlick, Antonio Bruni, Yasmin Rafiei, Andrew R. Pepper, Boris Gala-Lopez, Min Choi, Andrew Malcolm, Roger J. Zemp, A. M.James Shapiro

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5 Citas (Scopus)

Resumen

Islet transplantation (IT) is an established clinical therapy for select patients with type-1 diabetes. Clinically, the hepatic portal vein serves as the site for IT. Despite numerous advances in clinical IT, limitations remain, including early islet cell loss posttransplant, procedural complications, and the inability to effectively monitor islet grafts. Hence, alternative sites for IT are currently being explored, with the subcutaneous space as one potential option. When left unmodified, the subcutaneous space routinely fails to promote successful islet engraftment. However, when employing the previously developed subcutaneous "deviceless" technique, a favorable microenvironment for islet survival and function is established. In this technique, an angiocatheter was temporarily implanted subcutaneously, which facilitated angiogenesis to promote subsequent islet engraftment. This technique has been employed in preclinical animal models, providing a sufficient means to develop techniques to monitor functional aspects of the graft such as angiogenesis. Here, we utilize photoacoustic imaging to track angiogenesis during the priming of the subcutaneous site by the implanted catheter at 1 to 4 weeks postcatheter. Quantitative analysis on vessel densities shows gradual growth of vasculature in the implant position. These results demonstrate the ability to track angiogenesis, thus facilitating a means to optimize and assess the pretransplant microenvironment.

Idioma original	English
Número de artículo	066003
Publicación	Journal of Biomedical Optics
Volumen	21
N.º	6
DOI	https://doi.org/10.1117/1.JBO.21.6.066003
Estado	Published - jun. 1 2016
Publicado de forma externa	Sí

Nota bibliográfica

Funding Information:
Dr. A.M. James Shapiro is supported through a Senior Clinical Scholarship from Alberta Innovates Healthcare Solutions, AIHS CRIO Team Award #201201154 and holds a Canada Research Chair in Transplantation Surgery and Regenerative Medicine funded through the Government of Canada. Dr. Roger J. Zemp is supported through a Prostate Cancer Canada Movember Discovery Grant, NSERC (355544-2008, 375340-2009, and STPGP 396444), the Canadian Cancer Society (CCS 2011-700718), the Canada Foundation for Innovation, Leaders Opportunity Fund (18472), and the Alberta Advanced Education & Technology, Small Equipment Grants Program (URSI09007SEG). Wei Shi is supported through the Alberta Innovates Technology Futures Postdoctoral Fellowship Program. Antonio Bruni is supported through scholarships from the University of Alberta, the Alberta Diabetes Institute, and the Alberta Diabetes Foundation. Dr. Andrew R. Pepper is supported primarily through an AIHS Postdoctoral Fellowship and a Fellowship from the Juvenile Diabetes Research Foundation Canadian Clinical Trials Network. Dr. Boris Gala-Lopez is supported by an AIHS Clinician Fellowship. Min Choi is supported through a Queen Elizabeth II Scholarship.

Publisher Copyright:
© 2016 The Authors. Published by SPIE under a Creative Commons Attribution 3.0 Unported License. Distribution or reproduction of this work in whole or in part requires full attribution of the original publication, including its DOI.

ASJC Scopus Subject Areas

Electronic, Optical and Magnetic Materials
Biomaterials
Atomic and Molecular Physics, and Optics
Biomedical Engineering

PubMed: MeSH publication types

Journal Article
Research Support, Non-U.S. Gov't

ODS de las Naciones Unidas

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title = "Photoacoustic imaging of angiogenesis in a subcutaneous islet transplant site in a murine model",

abstract = "Islet transplantation (IT) is an established clinical therapy for select patients with type-1 diabetes. Clinically, the hepatic portal vein serves as the site for IT. Despite numerous advances in clinical IT, limitations remain, including early islet cell loss posttransplant, procedural complications, and the inability to effectively monitor islet grafts. Hence, alternative sites for IT are currently being explored, with the subcutaneous space as one potential option. When left unmodified, the subcutaneous space routinely fails to promote successful islet engraftment. However, when employing the previously developed subcutaneous {"}deviceless{"} technique, a favorable microenvironment for islet survival and function is established. In this technique, an angiocatheter was temporarily implanted subcutaneously, which facilitated angiogenesis to promote subsequent islet engraftment. This technique has been employed in preclinical animal models, providing a sufficient means to develop techniques to monitor functional aspects of the graft such as angiogenesis. Here, we utilize photoacoustic imaging to track angiogenesis during the priming of the subcutaneous site by the implanted catheter at 1 to 4 weeks postcatheter. Quantitative analysis on vessel densities shows gradual growth of vasculature in the implant position. These results demonstrate the ability to track angiogenesis, thus facilitating a means to optimize and assess the pretransplant microenvironment.",

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AU - Zemp, Roger J.

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N2 - Islet transplantation (IT) is an established clinical therapy for select patients with type-1 diabetes. Clinically, the hepatic portal vein serves as the site for IT. Despite numerous advances in clinical IT, limitations remain, including early islet cell loss posttransplant, procedural complications, and the inability to effectively monitor islet grafts. Hence, alternative sites for IT are currently being explored, with the subcutaneous space as one potential option. When left unmodified, the subcutaneous space routinely fails to promote successful islet engraftment. However, when employing the previously developed subcutaneous "deviceless" technique, a favorable microenvironment for islet survival and function is established. In this technique, an angiocatheter was temporarily implanted subcutaneously, which facilitated angiogenesis to promote subsequent islet engraftment. This technique has been employed in preclinical animal models, providing a sufficient means to develop techniques to monitor functional aspects of the graft such as angiogenesis. Here, we utilize photoacoustic imaging to track angiogenesis during the priming of the subcutaneous site by the implanted catheter at 1 to 4 weeks postcatheter. Quantitative analysis on vessel densities shows gradual growth of vasculature in the implant position. These results demonstrate the ability to track angiogenesis, thus facilitating a means to optimize and assess the pretransplant microenvironment.

AB - Islet transplantation (IT) is an established clinical therapy for select patients with type-1 diabetes. Clinically, the hepatic portal vein serves as the site for IT. Despite numerous advances in clinical IT, limitations remain, including early islet cell loss posttransplant, procedural complications, and the inability to effectively monitor islet grafts. Hence, alternative sites for IT are currently being explored, with the subcutaneous space as one potential option. When left unmodified, the subcutaneous space routinely fails to promote successful islet engraftment. However, when employing the previously developed subcutaneous "deviceless" technique, a favorable microenvironment for islet survival and function is established. In this technique, an angiocatheter was temporarily implanted subcutaneously, which facilitated angiogenesis to promote subsequent islet engraftment. This technique has been employed in preclinical animal models, providing a sufficient means to develop techniques to monitor functional aspects of the graft such as angiogenesis. Here, we utilize photoacoustic imaging to track angiogenesis during the priming of the subcutaneous site by the implanted catheter at 1 to 4 weeks postcatheter. Quantitative analysis on vessel densities shows gradual growth of vasculature in the implant position. These results demonstrate the ability to track angiogenesis, thus facilitating a means to optimize and assess the pretransplant microenvironment.

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Photoacoustic imaging of angiogenesis in a subcutaneous islet transplant site in a murine model

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ASJC Scopus Subject Areas

PubMed: MeSH publication types

ODS de las Naciones Unidas

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