A Nonhuman Primate Model of Human Radiation-induced Venocclusive Liver Disease and Hepatocyte Injury

Overview

Journal Int J Radiat Oncol Biol Phys

Specialties Oncology
Radiology

Date 2013 Dec 10

PMID 24315566

Citations 15

Authors

Govardhana Rao Yannam

Bing Han

Kentaro Setoyama

Toshiyuki Yamamoto

Ryotaro Ito

Jenna M Brooks

Jorge Guzman-Lepe

Csaba Galambos

Jason V Fong

Melvin Deutsch

Mubina A Quader

Kosho Yamanouchi

Rafi Kabarriti

Keyur Mehta

Alejandro Soto-Gutierrez

Jayanta Roy-Chowdhury

Joseph Locker

Michio Abe

Charles A Enke

Janina Baranowska-Kortylewicz

Timothy D Solberg

Chandan Guha

Ira J Fox

Affiliations

Soon will be listed here.

Abstract

Background: Human liver has an unusual sensitivity to radiation that limits its use in cancer therapy or in preconditioning for hepatocyte transplantation. Because the characteristic veno-occlusive lesions of radiation-induced liver disease do not occur in rodents, there has been no experimental model to investigate the limits of safe radiation therapy or explore the pathogenesis of hepatic veno-occlusive disease.

Methods And Materials: We performed a dose-escalation study in a primate, the cynomolgus monkey, using hypofractionated stereotactic body radiotherapy in 13 animals.

Results: At doses ≥40 Gy, animals developed a systemic syndrome resembling human radiation-induced liver disease, consisting of decreased albumin, elevated alkaline phosphatase, loss of appetite, ascites, and normal bilirubin. Higher radiation doses were lethal, causing severe disease that required euthanasia approximately 10 weeks after radiation. Even at lower doses in which radiation-induced liver disease was mild or nonexistent, latent and significant injury to hepatocytes was demonstrated by asialoglycoprotein-mediated functional imaging. These monkeys developed hepatic failure with encephalopathy when they received parenteral nutrition containing high concentrations of glucose. Histologically, livers showed central obstruction via an unusual intimal swelling that progressed to central fibrosis.

Conclusions: The cynomolgus monkey, as the first animal model of human veno-occlusive radiation-induced liver disease, provides a resource for characterizing the early changes and pathogenesis of venocclusion, for establishing nonlethal therapeutic dosages, and for examining experimental therapies to minimize radiation injury.

Citing Articles

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