The Sheep as a Large Animal Model for the Investigation and Treatment of Human Disorders

Banstola, Ashik; Reynolds, John N. J.

doi:10.3390/biology11091251

Cited by 43 publications

(27 citation statements)

References 179 publications

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“…Hence, standardized models of long nerve gap injury in large animals are necessary to evaluate tolerability and efficacy of new treatment strategies for severe nerve injuries [ 6 ]. In this sense, sheep are proposed as an optimal large animal model, since they have similarities in general body and neural structures to humans [ 37 , 38 ], and particularly peripheral nerve dimensions and structure similar to humans [ 20 , 39 , 40 , 41 ]. Moreover, their calm nature, compared to other large animals used as experimental models, such as pigs, enables easier postoperative management and clinical testing [ 18 , 42 ].…”

Section: Discussionmentioning

confidence: 99%

Repair of Long Nerve Defects with a New Decellularized Nerve Graft in Rats and in Sheep

Contreras

Traserra

Bolívar

et al. 2022

Cells

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Decellularized nerve allografts (DC) are an alternative to autografts (AG) for repairing severe peripheral nerve injuries. We have assessed a new DC provided by VERIGRAFT. The decellularization procedure completely removed cellularity while preserving the extracellular matrix. We first assessed the DC in a 15 mm gap in the sciatic nerve of rats, showing slightly delayed but effective regeneration. Then, we assayed the DC in a 70 mm gap in the peroneal nerve of sheep compared with AG. Evaluation of nerve regeneration and functional recovery was performed by clinical, electrophysiology and ultrasound tests. No significant differences were found in functional recovery between groups of sheep. Histology showed a preserved fascicular structure in the AG while in the DC grafts regenerated axons were grouped in small units. In conclusion, the DC was permissive for axonal regeneration and allowed to repair a 70 mm long gap in the sheep nerve.

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Section: Discussionmentioning

confidence: 99%

Repair of Long Nerve Defects with a New Decellularized Nerve Graft in Rats and in Sheep

Contreras

Traserra

Bolívar

et al. 2022

Cells

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“…In addition, with the growing number of potential targeted genes and pathogenesis of human diseases that have been discovered, using gene editing technology to explore functions of the genome, realizing genetic improvement in reproduction traits, and overcoming species differences to simulate human diseases accurately still need further research. Moreover, models of large animals for human diseases have already been developed well in species like sheep ( Banstola and Reynolds, 2022 ), monkeys ( Khampang et al, 2021 ), and horses ( Metrangolo et al, 2021 ) that covered genetic diseases like Batten disease ( Karageorgos et al, 2011 ) and Gaucher disease ( Kawabata et al, 2021 ), hypophyseal dysfunction ( Koch and Betts, 2007 ), joint problems ( Harman et al, 2021 ), and cutaneous wounds ( Rogers, 2016b ). Although the system of a species can differ from another, the ways of creating transgenic pig may provide new directions for other large animal models.…”

Section: Discussionmentioning

confidence: 99%

Application of the transgenic pig model in biomedical research: A review

Wei

Zhang²,

Li³

et al. 2022

Front. Cell Dev. Biol.

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The large animal model has gradually become an essential part of preclinical research studies, relating to exploring the disease pathological mechanism, genic function, pharmacy, and other subjects. Although the mouse model has already been widely accepted in clinical experiments, the need for finding an animal model with high similarity compared with a human model is urgent due to the different body functions and systems between mice and humans. The pig is an optimal choice for replacement. Therefore, enhancing the production of pigs used for models is an important part of the large animal model as well. Transgenic pigs show superiority in pig model creation because of the progress in genetic engineering. Successful cases of transgenic pig models occur in the clinical field of metabolic diseases, neurodegenerative diseases, and genetic diseases. In addition, the choice of pig breed influences the effort and efficiency of reproduction, and the mini pig has relative obvious advantages in pig model production. Indeed, pig models in these diseases provide great value in studies of their causes and treatments, especially at the genetic level. This review briefly outlines the method used to create transgenic pigs and species of producing transgenic pigs and provides an overview of their applications on different diseases and limitations for present pig model developments.

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“…22,23 Sheep, as a largeanimal model, shares hemodynamic flow parameters with similar anatomy to the human body and is a standard preclinical model for the testing of the efficacy and safety of new drug formulations and vaccines. 24 Nonhuman primates share biological, clinical, and behavioral (cognitive and societal) features with humans; thus, they are the most vital animal model. 25,26 However, due to the vast amount of similarities, animal welfare considerations within experimentation are the highest in this model.…”

Section: Key Pointsmentioning

confidence: 99%

“…Swine models provide a better understanding of human disease models and are an optimal model for xenotransplantation and surgical training as their organs are of similar size to human organs 22,23 . Sheep, as a large‐animal model, shares hemodynamic flow parameters with similar anatomy to the human body and is a standard preclinical model for the testing of the efficacy and safety of new drug formulations and vaccines 24 . Nonhuman primates share biological, clinical, and behavioral (cognitive and societal) features with humans; thus, they are the most vital animal model 25,26 .…”

Section: Introductionmentioning

confidence: 99%

Organ‐on‐a‐chip technologies for biomedical research and drug development: A focus on the vasculature

2023

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Current biomedical models fail to replicate the complexity of human biology.Consequently, almost 90% of drug candidates fail during clinical trials after decades of research and billions of investments in drug development. Despite their physiological similarities, animal models often misrepresent human responses, and instead, trigger ethical and societal debates regarding their use. The overall aim across regulatory entities worldwide is to replace, reduce, and refine the use of animal experimentation, a concept known as the Three Rs principle. In response, researchers develop experimental alternatives to improve the biological relevance of in vitro models through interdisciplinary approaches. This article highlights the emerging organ-on-a-chip technologies, also known as microphysiological systems, with a focus on models of the vasculature. The cardiovascular system transports all necessary substances, including drugs, throughout the body while in charge of thermal regulation and communication between other organ systems. In addition, we discuss the benefits, limitations, and challenges in the widespread use of new biomedical models. Coupled with patient-derived induced pluripotent stem cells, organon-a-chip technologies are the future of drug discovery, development, and personalized medicine. K E Y W O R D Sbiomedical, microphysiological systems, models, organ-on-a-chip, vasculatureThis is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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The Sheep as a Large Animal Model for the Investigation and Treatment of Human Disorders

Cited by 43 publications

References 179 publications

Repair of Long Nerve Defects with a New Decellularized Nerve Graft in Rats and in Sheep

Repair of Long Nerve Defects with a New Decellularized Nerve Graft in Rats and in Sheep

Application of the transgenic pig model in biomedical research: A review

Organ‐on‐a‐chip technologies for biomedical research and drug development: A focus on the vasculature

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