Organ‐on‐a‐Chip Technology for Reproducing Multiorgan Physiology

Lee, Seung Hwan; Sung, Jong Hwan

doi:10.1002/adhm.201700419

Cited by 92 publications

(77 citation statements)

References 154 publications

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“…[272] Improved predictive capacity in future studies will require addition of other tissue-engineered organs, including the gut and intestine to model first-pass metabolism that regulates the concentration and chemical form of any drug that enters the bloodstream. [273] …”

Section: Disease Modeling With Engineered Human Musclementioning

confidence: 99%

In Vitro Tissue‐Engineered Skeletal Muscle Models for Studying Muscle Physiology and Disease

Prabhu

Wang

Bursac

2018

Adv Healthcare Materials

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Healthy skeletal muscle possesses the extraordinary ability to regenerate in response to small-scale injuries; however, this self-repair capacity becomes overwhelmed with aging, genetic myopathies, and large muscle loss. The failure of small animal models to accurately replicate human muscle disease, injury and to predict clinically-relevant drug responses has driven the development of high fidelity in vitro skeletal muscle models. Herein, the progress made and challenges ahead in engineering biomimetic human skeletal muscle tissues that can recapitulate muscle development, genetic diseases, regeneration, and drug response is discussed. Bioengineering approaches used to improve engineered muscle structure and function as well as the functionality of satellite cells to allow modeling muscle regeneration in vitro are also highlighted. Next, a historical overview on the generation of skeletal muscle cells and tissues from human pluripotent stem cells, and a discussion on the potential of these approaches to model and treat genetic diseases such as Duchenne muscular dystrophy, is provided. Finally, the need to integrate multiorgan microphysiological systems to generate improved drug discovery technologies with the potential to complement or supersede current preclinical animal models of muscle disease is described.

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Section: Disease Modeling With Engineered Human Musclementioning

confidence: 99%

In Vitro Tissue‐Engineered Skeletal Muscle Models for Studying Muscle Physiology and Disease

Prabhu

Wang

Bursac

2018

Adv Healthcare Materials

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“…Despite these advantages, the attrition rate of drugs continues to be high and the productivity of new drug development process has decreased, resulting in a reluctance to monetarily invest in drug research and development (Peck, Lendrem, Grant, Lendrem, & Isaacs, ). The performance of in vitro models is hindered by the reality that the human body consists of many organs that are functionally interconnected by vascular networks (S. H. Lee & Sung, ). The organs communicate through signal molecules that are transported by blood to other organs via vascular networks.…”

Section: Introductionmentioning

confidence: 99%

“…Conventional in vitro models for studying glucose metabolism have been limited to static, single‐organ systems. These models are limited in their ability to simulate the relationships between organs, and fail to provide disease models that are physiologically relevant (S. H. Lee & Sung, ). Coculturing and the transfer of media from cell to cell have been proposed as alternative methods, but they are not able to reproduce the time‐dependent dynamics of multiorgan interactions (Choi, Fukuda, Sakoda, & Sakai, ).…”

Section: Introductionmentioning

confidence: 99%

Construction of pancreas–muscle–liver microphysiological system (MPS) for reproducing glucose metabolism

Lee

Choi

et al. 2019

Biotech & Bioengineering

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Although in vitro models are widely accepted experimental platforms, their physiological relevance is often severely limited. The limitation of current in vitro models is strongly manifested in case of diseases where multiple organs are involved, such as diabetes and metabolic syndrome. Microphysiological systems (MPS), also known as organ-on-a-chip technology, enable a closer approximation of the human organs and tissues, by recreating the tissue microenvironment. Multiorgan MPS, also known as multiorgan-on-a-chip or body-on-a-chip, offer the possibility of reproducing interactions between organs by connecting different organ modules. Here, we designed a three-organ MPS consisting of pancreas, muscle, and liver, to recapitulate glucose metabolism and homeostasis by constructing a mathematical model of glucose metabolism, based on experimental measurement of glucose uptake by muscle cells and insulin secretion by pancreas cells. A mathematical model was used to modify the MPS to improve the physiological relevance, and by adding the liver model in the mathematical model, physiological realistic glucose and insulin profiles were obtained. Our study may provide a methodological framework for developing multiorgan MPS for recapitulating the complex interaction between multiple organs. K E Y W O R D Sglucose metabolism, mathematical model, multiorgan MPS, multiorgan-on-a-chip (MOC), pancreas-muscle-liver MPS

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“…On the contrary, in vitro culture systems offer the advantages of controlled manipulation of experimental conditions for dissecting tissue-to-tissue communication and of accessibility to measurements 2 . The most used in vitro models to study the cross talk between different tissues are based on no-contact co-culture systems, called transwell, where different cell types are cultured on the same dish sharing the same culture medium, but physically separated by a porous membrane.…”

Section: Introductionmentioning

confidence: 99%

“…Up to now, multiple tissues-on-chip have been developed 4,7 , although the application of these technologies to human primary cells is more limited 5,8,9 . Some studies have been performed to understand the interaction between different tissues in vitro, but mainly cell lines have been used so far, as recently reviewed 2,10 .…”

Section: Introductionmentioning

confidence: 99%

Cross‐talk of healthy and impaired human tissues for dissection of disease pathogenesis

Zoso

Zambon

Gagliano

et al. 2019

Biotechnology Progress

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Systemic diseases affect multiple tissues that interact with each other within a network difficult to explore at the body level. However, understanding the inter-dependences between tissues could be of high relevance for drug target identification, especially at the first stages of disease development.In vitro systems have the advantages of accessibility to measurements and precise controllability of culture conditions, but currently have limitations in mimicking human in vivo systemic tissue response.In this work, we present an in vitro model of cross-talk between an ex vivo culture of adipose tissue from an obese donor and a skeletal muscle in vitro model from a healthy donor. This is relevant to understand type 2 diabetes mellitus pathogenesis, as obesity is one of its main risk factors. The human adipose tissue biopsy was maintained as a three-dimensional culture for 48 hours. Its conditioned culture medium was used to stimulate a human skeletal muscle-on-chip, developed by differentiating primary cells of a patient's biopsy under topological cues and molecular selfregulation. This system has been characterized to demonstrate its ability to mimic important features of the normal skeletal muscle response in vivo. We then found that the conditioned medium from a diseased adipose tissue is able to perturb the normal insulin sensitivity of a healthy skeletal muscle, as reported in the early stages of diabetes onset.In perspective, this work represents an important step towards the development of technological platforms that allow to study and dissect the systemic interaction between unhealthy and healthy tissues in vitro.

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Organ‐on‐a‐Chip Technology for Reproducing Multiorgan Physiology

Cited by 92 publications

References 154 publications

In Vitro Tissue‐Engineered Skeletal Muscle Models for Studying Muscle Physiology and Disease

In Vitro Tissue‐Engineered Skeletal Muscle Models for Studying Muscle Physiology and Disease

Construction of pancreas–muscle–liver microphysiological system (MPS) for reproducing glucose metabolism

Cross‐talk of healthy and impaired human tissues for dissection of disease pathogenesis

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