Parya Jafari scite author profile

Organ‐on‐chip (OOC) platforms have attracted attentions of pharmaceutical companies as powerful tools for screening of existing drugs and development of new drug candidates. OOCs have primarily used human cell lines or primary cells to develop biomimetic tissue models. However, the ability of human stem cells in unlimited self‐renewal and differentiation into multiple lineages has made them attractive for OOCs. The microfluidic technology has enabled precise control of stem cell differentiation using soluble factors, biophysical cues, and electromagnetic signals. This study discusses different tissue‐ and organ‐on‐chip platforms (i.e., skin, brain, blood–brain barrier, bone marrow, heart, liver, lung, tumor, and vascular), with an emphasis on the critical role of stem cells in the synthesis of complex tissues. This study further recaps the design, fabrication, high‐throughput performance, and improved functionality of stem‐cell‐based OOCs, technical challenges, obstacles against implementing their potential applications, and future perspectives related to different experimental platforms.

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Skin Diseases Modeling using Combined Tissue Engineering and Microfluidic Technologies

Mohammadi

Araghi

Beydaghi

et al. 2016

Adv Healthcare Materials

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In recent years, both tissue engineering and microfluidics have significantly contributed in engineering of in vitro skin substitutes to test the penetration of chemicals or to replace damaged skins. Organ-on-chip platforms have been recently inspired by the integration of microfluidics and biomaterials in order to develop physiologically relevant disease models. However, the application of organ-on-chip on the development of skin disease models is still limited and needs to be further developed. The impact of tissue engineering, biomaterials and microfluidic platforms on the development of skin grafts and biomimetic in vitro skin models is reviewed. The integration of tissue engineering and microfluidics for the development of biomimetic skin-on-chip platforms is further discussed, not only to improve the performance of present skin models, but also for the development of novel skin disease platforms for drug screening processes.

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Microfluidic-Based Multi-Organ Platforms for Drug Discovery

et al. 2016

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Development of predictive multi-organ models before implementing costly clinical trials is central for screening the toxicity, efficacy, and side effects of new therapeutic agents. Despite significant efforts that have been recently made to develop biomimetic in vitro tissue models, the clinical application of such platforms is still far from reality. Recent advances in physiologically-based pharmacokinetic and pharmacodynamic (PBPK-PD) modeling, micro- and nanotechnology, and in silico modeling have enabled single- and multi-organ platforms for investigation of new chemical agents and tissue-tissue interactions. This review provides an overview of the principles of designing microfluidic-based organ-on-chip models for drug testing and highlights current state-of-the-art in developing predictive multi-organ models for studying the cross-talk of interconnected organs. We further discuss the challenges associated with establishing a predictive body-on-chip (BOC) model such as the scaling, cell types, the common medium, and principles of the study design for characterizing the interaction of drugs with multiple targets.

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In-vivo lung biomechanical modeling for effective tumor motion tracking in external beam radiation therapy

Jafari

Dempsey

Hoover

et al. 2021

Computers in Biology and Medicine

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A Composite Material Based Neural Network for Tissue Mechanical Properties Estimation Toward Stage Assessment of Infarction

Dempsey

Jafari²,

Samani

2020

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Organ‐On‐Chip Platforms: Skin Diseases Modeling using Combined Tissue Engineering and Microfluidic Technologies (Adv. Healthcare Mater. 19/2016)

Mohammadi

Araghi

Beydaghi

et al. 2016

Adv Healthcare Materials

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Incorporating Pathology-Induced Heterogeneities in a Patient-Specific Biomechanical Model of the Lung for Accurate Tumor Motion Estimation

Jafari

Hoover

Yaremko

et al. 2019

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4D-CT Hyper-Elastography Using a Biomechanical Model

Miranda

Jafari²,

Dempsey

et al. 2020

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Parya Jafari

Controlling Differentiation of Stem Cells for Developing Personalized Organ‐on‐Chip Platforms

Skin Diseases Modeling using Combined Tissue Engineering and Microfluidic Technologies

Microfluidic-Based Multi-Organ Platforms for Drug Discovery

In-vivo lung biomechanical modeling for effective tumor motion tracking in external beam radiation therapy

A Composite Material Based Neural Network for Tissue Mechanical Properties Estimation Toward Stage Assessment of Infarction

Organ‐On‐Chip Platforms: Skin Diseases Modeling using Combined Tissue Engineering and Microfluidic Technologies (Adv. Healthcare Mater. 19/2016)

Incorporating Pathology-Induced Heterogeneities in a Patient-Specific Biomechanical Model of the Lung for Accurate Tumor Motion Estimation

4D-CT Hyper-Elastography Using a Biomechanical Model

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