Your search keyword '"Microphysiological system"' showing total 24 results

1. Cross-industrial applications of organotypic models

Author

Katarzyna S, Kopanska and Markus, Rimann

Subjects

Microphysiological system, 3D cell culture, Pharmacology, Human-relevant test system, Drug development, Biofabrication, General Medicine, Animal Testing Alternatives, 3Rs principle, Medical Laboratory Technology, Lab-On-A-Chip device, Lab-On-A-Chip Devices, Alternative method, Animals, Humans, Cross-sectoral collaboration, Cell Culture Techniques, Three Dimensional, Switzerland, 610.28: Biomedizin, Biomedizinische Technik

Abstract

Recent advances in microphysiological systems (MPS) promise a global paradigm shift in drug development, diagnostics, disease prevention, and therapy. The expectation is that these systems will model healthy and various diseased stages and disease progression to predict toxicity, immunogenicity, ADME profiles, and treatment efficacies. MPS will provide unprecedented human-like physiological properties of in vitro models, enabling their routine application in the pharma industry and thus reducing drug development costs by lowering the attrition rate of compounds. We showcased MPS application diversity across different industries during the TEDD Annual Meeting on 14th October 2021 in Wädenswil, Switzerland. The goal was to promote cross-sectoral collaboration of academia and industry to further pave the way for developing next-generation MPS based on 3D cell culture, organoid, and organ-on-chip technology and their widespread exploitation. To enable visionary projects and radical innovations, we covered multidisciplinary fields and connected different industry sectors, like pharma, medtech, biotech, cosmetics, diagnostics, fragrances, and food, with each other.

Published

2022

2. Establishment of a resazurin-based aortic valve tissue viability assay for dynamic culture in a microphysiological system

Author

Stephan Behrens, Florian Schmieder, Klaus Matschke, Anett Jannasch, Claudia Dittfeld, Sems-Malte Tugtekin, Frank Sonntag, M Winkelkotte, and Publica

Subjects

Aortic valve, resazurin reduction, Swine, Physiology, Pulsatile flow, Incubation period, dynamic tissue culture, chemistry.chemical_compound, Physiology (medical), Lactate dehydrogenase, Oxazines, medicine, Animals, Humans, Viability assay, microphysiological system, Tissue Survival, Chemistry, Endothelial Cells, Resazurin, Aortic Valve Stenosis, Hematology, In vitro, medicine.anatomical_structure, Xanthenes, Cell culture, Aortic Valve, tissue viability, Cardiology and Cardiovascular Medicine, human aortic valve, Biomedical engineering

Abstract

BACKGROUND/AIM: Tissue pathogenesis of aortic valve (AV) stenosis is research focus in cardiac surgery. Model limitations of conventional 2D culture of human or porcine valvular interstitial/endothelial cells (VIC/VECs) isolated from aortic valve tissues but also limited ability of (small) animal models to reflect human (patho)physiological situation in AV position raise the need to establish an in vitro setup using AV tissues. Resulting aim is to approximate (patho)physiological conditions in a dynamic pulsatile Microphysiological System (MPS) to culture human and porcine AV tissue with preservation of tissue viability but also defined ECM composition. MATERIALS/METHODS: A tissue incubation chamber (TIC) was designed to implement human or porcine tissues (3×5 mm2) in a dynamic pulsatile culture in conventional cell culture ambience in a MPS. Cell viability assays based on lactate dehydrogenase (LDH)-release or resazurin-conversion were tested for applicability in the system and applied for a culture period of 14 days with interval evaluation of tissue viability on every other day. Resazurin-assay setup was compared in static vs. dynamic culture using varying substance saturation settings (50–300μM), incubation times and tissue masses and was consequently adapted. RESULTS: Sterile dynamic culture of human and porcine AV tissue segments was established at a pulsatile flow rate range of 0.9–13.4μl/s. Implementation of tissues was realized by stitching the material in a thermoplastic polyurethane (TPU)-ring and insertion in the TIC-MPS-system. Culture volume of 2 ml caused LDH dilution not detectable in standard membrane integrity assay setup. Therefore, detection of resazurin-conversion of viable tissue was investigated. Optimal incubation time for viability conversion was determined at two hours at a saturated concentration of 300μM resazurin. Measurement in static conditions was shown to offer comparable results as dynamic condition but allowing optimal handling and TIC sterilization protocols for long term culture. Preliminary results revealed favourable porcine AV tissue viability over a 14 day period confirmed via resazurin-assay comparing statically cultured tissue counterparts. CONCLUSIONS: Human and porcine AV tissue can be dynamically cultured in a TIC-MPS with monitoring of tissue viability using an adapted resazurin-assay setup. Preliminary results reveal advantageous viability of porcine AV tissues after dynamic TIC-MPS culture compared to static control.

Published

2021

3. Human Organs-on-Chips for Virology

Author

Christine L. Mummery, Ana Maria Ortega-Prieto, Donald E. Ingber, Longlong Si, Alireza Mashaghi, Huaqi Tang, and Yasmine Abouleila

Subjects

Microbiology (medical), 2019-20 coronavirus outbreak, Coronavirus disease 2019 (COVID-19), viral infections, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Microfluidics, virus, Biology, Microbiology, Organ-on-a-chip, Article, 03 medical and health sciences, Organ Culture Techniques, Virology, Animals, Humans, microphysiological system, 030304 developmental biology, organ-on-a-chip, 0303 health sciences, 030306 microbiology, Infectious Diseases, Virus Diseases, Viruses, Neuroscience, Virus Physiological Phenomena

Abstract

While conventional in vitro culture systems and animal models have been used to study the pathogenesis of viral infections and to facilitate development of vaccines and therapeutics for viral diseases, models that can accurately recapitulate human responses to infection are still lacking. Human organ-on-a-chip (Organ Chip) microfluidic culture devices that recapitulate tissue–tissue interfaces, fluid flows, mechanical cues, and organ-level physiology have been developed to narrow the gap between in vitro experimental models and human pathophysiology. Here, we describe how recent developments in Organ Chips have enabled re-creation of complex pathophysiological features of human viral infections in vitro., Highlights Microfluidic Organ Chip culture devices are emerging alternatives to conventional in vitro and animal models due to their ability to replicate many structural and functional features of human physiology and disease states. Recent innovations demonstrate that Organ Chip technology is a promising strategy for virology studies where there have been successes in reproducing various viral disease phenotypes. Organ Chips have enabled investigation of many aspects of viral infection, including virus–host interactions, viral therapy-resistance evolution, and development of new antiviral therapeutics, as well as underlying pathogenesis. As Organ Chip-based assays provide accessibility to study virus-induced diseases in real time and at high resolution, they can open new avenues to uncover viral pathogenesis in a human-relevant environment and may eventually enable development of novel therapeutics and vaccines.

Published

2020

4. Engineering Organ-on-a-Chip to Accelerate Translational Research

Author

Jihoon Ko, Dohyun Park, Somin Lee, Burcu Gumuscu, and Noo Jeon

Subjects

organ-on-a-chip, biochemical stimuli, Control and Systems Engineering, Mechanical Engineering, in vitro cell culture, biophysical stimuli, microphysiological system, Electrical and Electronic Engineering, microfabrication

Abstract

We guide the use of organ-on-chip technology in tissue engineering applications. Organ-on-chip technology is a form of microengineered cell culture platform that elaborates the in-vivo like organ or tissue microenvironments. The organ-on-chip platform consists of microfluidic channels, cell culture chambers, and stimulus sources that emulate the in-vivo microenvironment. These platforms are typically engraved into an oxygen-permeable transparent material. Fabrication of these materials requires the use of microfabrication strategies, including soft lithography, 3D printing, and injection molding. Here we provide an overview of what is an organ-on-chip platform, where it can be used, what it is composed of, how it can be fabricated, and how it can be operated. In connection with this topic, we also introduce an overview of the recent applications, where different organs are modeled on the microscale using this technology.

Published

2022

5. IP-10 (CXCL10) Can Trigger Emergence of Dormant Breast Cancer Cells in a Metastatic Liver Microenvironment

Author

Amanda M. Clark, Haley L. Heusey, Linda G. Griffith, Douglas. A. Lauffenburger, and Alan Wells

Subjects

tumor dormancy, Cancer Research, Inflammation, tumor emergence, IP-10, CXCR3, Metastasis, Breast cancer, breast cancer dormancy, medicine, metastasis, CXCL10, microphysiological system, skin and connective tissue diseases, RC254-282, Original Research, organ-on-a-chip, business.industry, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Cancer, medicine.disease, Metastatic breast cancer, Oncology, Cancer research, medicine.symptom, business, Ex vivo

Abstract

Metastatic breast cancer remains a largely incurable and fatal disease with liver involvement bearing the worst prognosis. The danger is compounded by a subset of disseminated tumor cells that may lie dormant for years to decades before re-emerging as clinically detectable metastases. Pathophysiological signals can drive these tumor cells to emerge. Prior studies indicated CXCR3 ligands as being the predominant signals synergistically and significantly unregulated during inflammation in the gut-liver axis. Of the CXCR3 ligands, IP-10 (CXCL10) was the most abundant, correlated significantly with shortened survival of human breast cancer patients with metastatic disease and was highest in those with triple negative (TNBC) disease. Using a complex ex vivo all-human liver microphysiological (MPS) model of dormant-emergent metastatic progression, CXCR3 ligands were found to be elevated in actively growing populations of metastatic TNBC breast cancer cells whereas they remained similar to the tumor-free hepatic niche in those with dormant breast cancer cells. Subsequent stimulation of dormant breast cancer cells in the ex vivo metastatic liver MPS model with IP-10 triggered their emergence in a dose-dependent manner. Emergence was indicated to occur indirectly possibly via activation of the resident liver cells in the surrounding metastatic microenvironment, as stimulation of breast cancer cells with exogenous IP-10 did not significantly change their migratory, invasive or proliferative behavior. The findings reveal that IP-10 is capable of triggering the emergence of dormant breast cancer cells within the liver metastatic niche and identifies the IP-10/CXCR3 as a candidate targetable pathway for rational approaches aimed at maintaining dormancy.

Published

2021

6. A microphysiological system combining electrospun fibers and electrical stimulation for the maturation of highly anisotropic cardiac tissue

Author

Jesús Ordoño, Adrián López-Canosa, Soledad Pérez-Amodio, Eduardo Yanac-Huertas, Elisabeth Engel, Romen Rodriguez-Trujillo, Josep Samitier, Oscar Castaño, Universitat Politècnica de Catalunya. Departament de Ciència i Enginyeria de Materials, and Universitat Politècnica de Catalunya. IMEM-BRT- Innovation in Materials and Molecular Engineering - Biomaterials for Regenerative Therapies

Subjects

Microphysiological system, Key genes, Computer science, 0206 medical engineering, Microfluidics, Biomedical Engineering, Nanofibers, Electrònica en cardiologia, Bioengineering, Stimulation, 02 engineering and technology, Cardiac tissue engineering, Biochemistry, Biomaterials, Heart-on-a-chip, Mice, Tissue engineering, Animals, Humans, Myocytes, Cardiac, Electronics in cardiology, Electrospinning, Tissue Engineering, Drug discovery, Neonatal mouse, General Medicine, Human physiology, In vitro models, 021001 nanoscience & nanotechnology, Biocompatible material, 020601 biomedical engineering, Electric Stimulation, Enginyeria biomèdica::Electrònica biomèdica::Electrònica en cardiologia [Àrees temàtiques de la UPC], Anisotropy, 0210 nano-technology, Biotechnology, Biomedical engineering

Abstract

The creation of cardiac tissue models for preclinical testing is still a non-solved problem in drug discovery, due to the limitations related to the in vitro replication of cardiac tissue complexity. Among these limitations, the difficulty of mimicking the functional properties of the myocardium due to the immaturity of the used cells hampers the obtention of reliable results that could be translated into human patients. In vivo models are the current gold standard to test new treatments, although it is widely acknowledged that the used animals are unable to fully recapitulate human physiology, which often leads to failures during clinical trials. In the present work, we present a microfluidic platform that aims to provide a range of signaling cues to immature cardiac cells to drive them towards an adult phenotype. The device combines topographical electrospun nanofibers with electrical stimulation in a microfabricated system. We validated our platform using a co-culture of neonatal mouse cardiomyocytes and cardiac fibroblasts, showing that it allows us to control the degree of anisotropy of the cardiac tissue inside the microdevice in a cost-effective way. Moreover, a 3D computational model of the electrical field was created and validated to demonstrate that our platform is able to closely match the distribution obtained with the gold standard (planar electrode technology) using inexpensive rod-shaped biocompatible stainless-steel electrodes. The functionality of the electrical stimulation was shown to induce a higher expression of the tight junction protein Cx-43, as well as the upregulation of several key genes involved in conductive and structural cardiac properties. These results validate our platform as a powerful tool for the tissue engineering community due to its low cost, high imaging compatibility, versatility, and high-throughput configuration capabilities.

Published

2020

7. Human in vitro vascularized micro-organ and micro-tumor models are reproducible organ-on-a-chip platforms for studies of anticancer drugs

Author

Courtney Sakolish, Christopher C.W. Hughes, R. Hugh F. Bender, Ivan Rusyn, Zunwei Chen, Yizhong Liu, and Duc T. T. Phan

Subjects

0301 basic medicine, Drug, Microphysiological system, Angiogenesis, media_common.quotation_subject, Cell Culture Techniques, Antineoplastic Agents, Bioengineering, Toxicology, Organ-on-a-chip, Article, Dose-Response Relationship, 03 medical and health sciences, 0302 clinical medicine, Organ Culture Techniques, Endothelial cell, In vivo, Neoplasms, Lab-On-A-Chip Devices, Human Umbilical Vein Endothelial Cells, Tissue chip, Humans, Neovascularization, media_common, Cancer, Pathologic, Drug safety evaluation, Dose-Response Relationship, Drug, Neovascularization, Pathologic, Chemistry, Endothelial Cells, Reproducibility of Results, Pharmacology and Pharmaceutical Sciences, Microfluidic Analytical Techniques, HCT116 Cells, In vitro, 5.9 Resources and infrastructure (treatment development), Cell biology, Endothelial stem cell, 030104 developmental biology, Cell culture, 5.1 Pharmaceuticals, Development of treatments and therapeutic interventions, 030217 neurology & neurosurgery, Function (biology)

Abstract

Angiogenesis is a complex process that is required for development and tissue regeneration and it may be affected by many pathological conditions. Chemicals and drugs can impact formation and maintenance of the vascular networks; these effects may be both desirable (e.g., anti-cancer drugs) or unwanted (e.g., side effects of drugs). A number of in vivo and in vitro models exist for studies of angiogenesis and endothelial cell function, including organ-on-a-chip microphysiological systems. An arrayed organ-on-a-chip platform on a 96-well plate footprint that incorporates perfused microvessels, with and without tumors, was recently developed and it was shown that survival of the surrounding tissue was dependent on delivery of nutrients through the vessels. Here we describe a technology transfer of this complex microphysiological model between laboratories and demonstrate that reproducibility and robustness of these tissue chip-enabled experiments depend primarily on the source of the endothelial cells. The model was highly reproducible between laboratories and was used to demonstrate the advantages of the perfusable vascular networks for drug safety evaluation. As a proof-of-concept, we tested Fluorouracil (1-1,000 μM), Vincristine (1-1,000 nM), and Sorafenib (0.1-100 μM), in the perfusable and non-perfusable micro-organs, and in a colon cancer-containing micro-tumor model. Tissue chip experiments were compared to the traditional monolayer cultures of endothelial or tumor cells. These studies showed that human in vitro vascularized micro-organ and micro-tumor models are reproducible organ-on-a-chip platforms for studies of anticancer drugs. The data from the 3D models confirmed advantages of the physiological environment as compared to 2D cell cultures. We demonstrated how these models can be translated into practice by verifying that the endothelial cell source and passage are critical elements for establishing a perfusable model.

Published

2020

8. Modular Microphysiological System for Modeling of Biologic Barrier Function

Author

Matthew Ishahak, Jordan Hill, Quratulain Amin, Laura Wubker, Adiel Hernandez, Alla Mitrofanova, Alexis Sloan, Alessia Fornoni, and Ashutosh Agarwal

Subjects

0301 basic medicine, Histology, Materials science, lcsh:Biotechnology, Microfluidics, glomerulus-on-chip, microfluidic, Biomedical Engineering, Bioengineering, Nanotechnology, 02 engineering and technology, 03 medical and health sciences, chemistry.chemical_compound, lcsh:TP248.13-248.65, Kidney injury, microphysiological system, Barrier function, Original Research, lung-on-chip, Polydimethylsiloxane, business.industry, Bioengineering and Biotechnology, Human physiology, Modular design, 021001 nanoscience & nanotechnology, 030104 developmental biology, chemistry, Glomerular Filtration Barrier, organ-on-chip, 0210 nano-technology, business, Biotechnology, Microfabrication

Abstract

Microphysiological systems, also known as organs-on-chips, are microfluidic devices designed to model human physiology in vitro. Polydimethylsiloxane (PDMS) is the most widely used material for organs-on-chips due to established microfabrication methods, and properties that make it suitable for biological applications such as low cytotoxicity, optical transparency, gas permeability. However, absorption of small molecules and leaching of uncrosslinked oligomers might hinder the adoption of PDMS-based organs-on-chips for drug discovery assays. Here, we have engineered a modular, PDMS-free microphysiological system that is capable of recapitulating biologic barrier functions commonly demonstrated in PDMS-based devices. Our microphysiological system is comprised of a microfluidic chip to house cell cultures and pneumatic microfluidic pumps to drive flow with programmable pressure and shear stress. The modular architecture and programmable pumps enabled us to model multiple in vivo microenvironments. First, we demonstrate the ability to generate cyclic strain on the culture membrane and establish a model of the alveolar air-liquid interface. Next, we utilized three-dimensional finite element analysis modeling to characterize the fluid dynamics within the device and develop a model of the pressure-driven filtration that occurs at the glomerular filtration barrier. Finally, we demonstrate that our model can be used to recapitulate sphingolipid induced kidney injury. Together, our results demonstrate that a multifunctional and modular microphysiological system can be deployed without the use of PDMS. Further, the bio-inert plastic used in our microfluidic device is amenable to various established, high-throughput manufacturing techniques, such as injection molding. As a result, the development plastic organs-on-chips provides an avenue to meet the increasing demand for organ-on-chip technology.

Published

2020

9. Organoids and Microphysiological Systems: New Tools for Ophthalmic Drug Discovery

Author

Jing Bai and Chunming Wang

Subjects

0301 basic medicine, Pharmacology, organ-on-a-chip, congenital, hereditary, and neonatal diseases and abnormalities, 3D tissue constructs, Computer science, Mini Review, organoid, lcsh:RM1-950, Organ-on-a-chip, ocular, 03 medical and health sciences, Ocular physiology, Ocular tissue, lcsh:Therapeutics. Pharmacology, 030104 developmental biology, 0302 clinical medicine, Drug development, 030220 oncology & carcinogenesis, Ophthalmic drug, Organoid, Pharmacology (medical), microphysiological system, Neuroscience

Abstract

Organoids are adept at preserving the inherent complexity of a given cellular environment and when integrated with engineered micro-physiological systems (MPS) present distinct advantages for simulating a precisely controlled geometrical, physical, and biochemical micro-environment. This then allows for real-time monitoring of cell-cell interactions. As a result, the two aforementioned technologies hold significant promise and potential in studying ocular physiology and diseases by replicating specific eye tissue microstructures in vitro. This miniaturized review begins with defining the science behind organoids/MPS and subsequently introducing methods for generating organoids and engineering MPS. Furthermore, we will discuss the current state of organoids and MPS models in retina, cornea surrogates, and other ocular tissue, in regards to physiological/disease conditions. Finally, future prospective on organoid/MPS will be covered here. Organoids and MPS technologies closely recapture the in vivo microenvironment and thusly will continue to provide new understandings in organ functions and novel approaches to drug development.

Published

2020

10. Microphysiological Engineering of Immune Responses in Intestinal Inflammation

Author

So Youn Min, Woojung Shin, Hyun-Jung Kim, and Yoko M. Ambrosini

Subjects

Microphysiological system, Organoid, 0301 basic medicine, Immunology, Gut inflammation-on-a-chip, Review Article, Inflammatory bowel disease, 03 medical and health sciences, 0302 clinical medicine, Immune system, Intestinal inflammation, medicine, Immunology and Allergy, Microbiome, Immune response, Close contact, business.industry, medicine.disease, Crosstalk (biology), 030104 developmental biology, Infectious Diseases, Intestinal Microbiome, Co-culture, business, Neuroscience, Homeostasis, 030215 immunology

Abstract

The epithelial barrier in the gastrointestinal (GI) tract is a protective interface that endures constant exposure to the external environment while maintaining its close contact with the local immune system. Growing evidence has suggested that the intercellular crosstalk in the GI tract contributes to maintaining the homeostasis in coordination with the intestinal microbiome as well as the tissue-specific local immune elements. Thus, it is critical to map the complex crosstalks in the intestinal epithelial-microbiome-immune (EMI) axis to identify a pathological trigger in the development of intestinal inflammation, including inflammatory bowel disease. However, deciphering a specific contributor to the onset of pathophysiological cascades has been considerably hindered by the challenges in current in vivo and in vitro models. Here, we introduce various microphysiological engineering models of human immune responses in the EMI axis under the healthy conditions and gut inflammation. As a prospective model, we highlight how the human “gut inflammation-on-a-chip” can reconstitute the pathophysiological immune responses and contribute to understanding the independent role of inflammatory factors in the EMI axis on the initiation of immune responses under barrier dysfunction. We envision that the microengineered immune models can be useful to build a customizable patient's chip for the advance in precision medicine.

Published

2020

11. A multimodal 3D neuro-microphysiological system with neurite-trapping microelectrodes

Author

Beatriz Molina-Martínez, Laura-Victoria Jentsch, Fulya Ersoy, Matthijs van der Moolen, Stella Donato, Torbjørn V Ness, Peter Heutink, Peter D Jones, and Paolo Cesare

Subjects

Neurons, induced pluripotent stem cells, microelectrode array, Induced Pluripotent Stem Cells, microfluidics, Biomedical Engineering, Bioengineering, General Medicine, electrophysiology, Biochemistry, Electrophysiological Phenomena, Biomaterials, ddc:570, Neurites, Humans, microphysiological system, 3D engineered neural tissues, Microelectrodes, Biotechnology

Abstract

Three-dimensional cell technologies as pre-clinical models are emerging tools for mimicking the structural and functional complexity of the nervous system. The accurate exploration of phenotypes in engineered 3D neuronal cultures, however, demands morphological, molecular and especially functional measurements. Particularly crucial is measurement of electrical activity of individual neurons with millisecond resolution. Current techniques rely on customized electrophysiological recording set-ups, characterized by limited throughput and poor integration with other readout modalities. Here we describe a novel approach, using multiwell glass microfluidic microelectrode arrays, allowing non-invasive electrical recording from engineered 3D neuronal cultures. We demonstrate parallelized studies with reference compounds, calcium imaging and optogenetic stimulation. Additionally, we show how microplate compatibility allows automated handling and high-content analysis of human induced pluripotent stem cell–derived neurons. This microphysiological platform opens up new avenues for high-throughput studies on the functional, morphological and molecular details of neurological diseases and their potential treatment by therapeutic compounds.

Published

2022

12. Organ-on-a-chip technologies that can transform ophthalmic drug discovery and disease modeling

Author

Stefan Kustermann, Jasmin Haderspeck, Stefan Liebau, Peter Loskill, Johanna Chuchuy, and Publica

Subjects

medicine.medical_specialty, in-vitro models, Eye Diseases, genetic structures, Visual impairment, cornea-on-a-chip, Administration, Ophthalmic, Disease, Models, Biological, Organ-on-a-chip, ocular model, 03 medical and health sciences, 0302 clinical medicine, Lab-On-A-Chip Devices, Drug Discovery, Ophthalmic drug, Animals, Humans, Medicine, Effective treatment, microphysiological system, Precision Medicine, Intensive care medicine, 030304 developmental biology, organ-on-a-chip, 0303 health sciences, ophthalmic model, business.industry, retina-on-a-chip, eye diseases, 030220 oncology & carcinogenesis, medicine.symptom, business

Abstract

Introduction: Disorders of the eye that lead to visual impairment are affecting millions of people worldwide. Nevertheless, for many of these disorders, there are still no effective treatment options available due to the lack of in vitro model systems that emulate the physiological in vivo structure and function of human eyes. Microphysiological organ-on-a-chip (OoC) technology represents a novel and powerful approach to overcome the limitations of conventional model systems and lead to a paradigm shift in ophthalmic research. Areas covered: This review provides an overview of the various tissues of interest in ophthalmology and summarizes existing model systems, including their applications and limitations. Additionally, novel OoC systems with applications in ophthalmology are described and the advantages of these systems compared to conventional models are highlighted. Expert opinion: The physiological relevance of the first ophthalmic OoC systems that mimic human ocular compartments, such as the cornea and retina, has been successfully demonstrated in recent years. There is a great potential for the application of these platforms for future pharmacological target identification, safety, and efficacy testing, as well as personalized medicine. Further improvements and the development of new systems are of upmost importance, especially to model complex disorders affecting several tissues.

Published

2018

13. Probing Insulin Sensitivity with Metabolically Competent Human Stem Cell‐Derived White Adipose Tissue Microphysiological Systems

Author

Lin Qi, Ching-Fang Chang, Peter-James H. Zushin, Yue Tung Lee, Suneil K. Koliwad, Diana L. Alba, and Andreas Stahl

Subjects

medicine.medical_specialty, Adipose Tissue, White, medicine.medical_treatment, Glucose uptake, Adipose tissue, White, White adipose tissue, Regenerative Medicine, Article, Biomaterials, white adipose tissue, Stem Cell Research - Nonembryonic - Human, Internal medicine, Lipid droplet, Adipocytes, human-induced pluripotent stem cells, medicine, Humans, Insulin, insulin sensitivity, Lipolysis, General Materials Science, Obesity, microphysiological system, Nanoscience & Nanotechnology, Metabolic and endocrine, organ-on-a-chip, Chemistry, Stem Cells, Diabetes, General Chemistry, Stem Cell Research, Endocrinology, Adipose Tissue, Insulin Resistance, Stem cell, Ex vivo, Biotechnology

Abstract

Impaired white adipose tissue (WAT) function has been recognized as a critical early event in obesity-driven disorders, but high buoyancy, fragility, and heterogeneity of primary adipocytes have largely prevented their use in drug discovery efforts highlighting the need for human stem cell-based approaches. Here, human stem cells are utilized to derive metabolically functional 3D adipose tissue (iADIPO) in a microphysiological system (MPS). Surprisingly, previously reported WAT differentiation approaches create insulin resistant WAT ill-suited for type-2 diabetes mellitus drug discovery. Using three independent insulin sensitivity assays, i.e., glucose and fatty acid uptake and suppression of lipolysis, as the functional readouts new differentiation conditions yielding hormonally responsive iADIPO are derived. Through concomitant optimization of an iADIPO-MPS, it is abled to obtain WAT with more unilocular and significantly larger (≈40%) lipid droplets compared to iADIPO in 2D culture, increased insulin responsiveness of glucose uptake (≈2-3 fold), fatty acid uptake (≈3-6 fold), and ≈40% suppressing of stimulated lipolysis giving a dynamic range that is competent to current in vivo and ex vivo models, allowing to identify both insulin sensitizers and desensitizers.

Published

2021

14. A microfluidic chip carrier including temperature control and perfusion system for long-term cell imaging

Author

Maria Tenje, Laurent Barbe, Federico Cantoni, Ana Maria Porras, and Gabriel Werr

Subjects

Microphysiological system, Science (General), Microscope, Materials science, Microfluidics, Biomedical Engineering, functional assay on-chipPortable microfluidics, Industrial and Manufacturing Engineering, law.invention, Q1-390, Long-term cell monitoring, law, Biomedicinsk laboratorievetenskap/teknologi, Microscopy, Biomedical Laboratory Science/Technology, Instrumentation, Civil and Structural Engineering, Resistive touchscreen, Temperature control, Mechanical Engineering, long-term cell monitoring, Incubator, Chip, Functional assay on-chip, Sample collection, Portable microfluidics, Biomedical engineering

Abstract

Microfluidic devices are widely used for biomedical applications but there is still a lack of affordable, reliable and user-friendly systems for transferring microfluidic chips from an incubator to a microscope while maintaining physiological conditions when performing microscopy. The presented carrier represents a cost-effective option for sustaining environmental conditions of microfluidic chips in combination with minimizing the device manipulation required for reagent injection, media exchange or sample collection. The carrier, which has the outer dimension of a standard well plate size, contains an integrated perfusion system that can recirculate the media using piezo pumps, operated in either continuous or intermittent modes (50-1,000 µl/min). Furthermore, a film resistive heater made from 37 µm-thick copper wires, including temperature feedback control, was used to maintain the microfluidic chip temperature at 37 °C when outside the incubator. The heater characterisation showed a uniform temperature distribution along the chip channel for perfusion flow rates up to 10 µl/min. To demonstrate the feasibility of our platform for long term cell culture monitoring, mouse brain endothelial cells (bEnd.3) were repeatedly monitored for a period of 10 days, demonstrating a system with both the versatility and the potential for long imaging in microphysiological system cell cultures.

Published

2021

15. 'Good Fences Make Good Neighbors': How does the Human Gut Microchip Unravel Mechanism of Intestinal Inflammation?

Author

Hyun-Jung Kim, Landon A. Hackley, and Woojung Shin

Subjects

0301 basic medicine, Microbiology (medical), gut inflammation-on-a-chip, microbiome, Inflammation, Biology, Microbiology, Inflammatory bowel disease, Models, Biological, 03 medical and health sciences, Mice, 0302 clinical medicine, Human gut, Immune system, Intestinal inflammation, Lab-On-A-Chip Devices, Microchip Analytical Procedures, medicine, oxidative stress, Animals, Humans, Microbiome, microphysiological system, lcsh:RC799-869, Barrier function, host-microbiome interaction, Host Microbial Interactions, Mechanism (biology), disease model, Probiotics, Gastroenterology, medicine.disease, Cell biology, Gastrointestinal Microbiome, Addendum, Intestinal Diseases, 030104 developmental biology, Infectious Diseases, gut-on-a-chip, lcsh:Diseases of the digestive system. Gastroenterology, 030211 gastroenterology & hepatology, medicine.symptom, barrier function

Abstract

A microengineered human gut-on-a-chip has demonstrated intestinal physiology, three-dimensional (3D) epithelial morphogenesis, and longitudinal host-microbiome interactions in vitro. The modular accessibility and modularity of the microphysiological gut-on-a-chip can lead to the identification of the seminal trigger in intestinal inflammation. By coupling microbial and immune cells in a spatiotemporal manner, we discovered that the maintenance of healthy epithelial barrier function is necessary and sufficient to demonstrate the homeostatic tolerance of the gut. Here, we highlight the breakthrough of our new disease model and discuss the future impact of investigating the etiology and therapeutic targets in the multifactorial inflammatory bowel disease.

Published

2019

16. Testing the Effectiveness of Curcuma longa Leaf Extract on a Skin Equivalent Using a Pumpless Skin-on-a-Chip Model

Author

Kyung Chan Choi, Kyung-Hee Kim, Gun Yong Sung, and Hye Mi Jeon

Subjects

Keratinocytes, 0301 basic medicine, Microfluidics, Human skin, Cosmetics, 02 engineering and technology, lcsh:Chemistry, Lab-On-A-Chip Devices, antiaging, microphysiological system, lcsh:QH301-705.5, Curcuma longa, Cells, Cultured, Spectroscopy, Skin barrier function, Skin, media_common, integumentary system, Chemistry, Dermis, General Medicine, 021001 nanoscience & nanotechnology, Immunohistochemistry, Computer Science Applications, Curcuma longa leaf extract, medicine.anatomical_structure, 0210 nano-technology, media_common.quotation_subject, Article, Catalysis, Inorganic Chemistry, 03 medical and health sciences, Curcuma, Microfluidic channel, human-skin equivalents, medicine, Humans, Skin equivalent, Physical and Theoretical Chemistry, Molecular Biology, Plant Extracts, Organic Chemistry, Fibroblasts, Coculture Techniques, Fibronectins, Plant Leaves, 030104 developmental biology, lcsh:Biology (General), lcsh:QD1-999, Epidermal Cells, pumpless skin-on-a-chip, Epidermis, Biomedical engineering

Abstract

The in vitro tests in current research employ simple culture methods that fail to mimic the real human tissue. In this study, we report drug testing with a &lsquo, pumpless skin-on-a-chip&rsquo, that mimics the structural and functional responses of human skin. This model is a skin equivalent constituting two layers of the skin, dermis and epidermis, developed using human primary fibroblasts and keratinocytes. Using the gravity flow device system, the medium was rotated at an angle of 15 degrees on both sides so as to circulate through the pumpless skin-on-a-chip microfluidic channel. This pumpless skin-on-a-chip is composed of upper and lower chips, and is manufactured using porous membranes so that medium can be diffused and supplied to the skin equivalent. Drug testing was performed using Curcuma longa leaf extract (CLLE), a natural product cosmetic ingredient, to evaluate the usefulness of the chip and the efficacy of the cosmetic ingredient. It was found that the skin barrier function of the skin epidermis layer is enhanced to exhibit antiaging effects. This result indicates that the pumpless skin-on-a-chip model can be potentially used not only in the cosmetics and pharmaceutical industries but also in clinical applications as an alternative to animal studies.

Published

2020

17. iPSC-Derived Endothelial Cells Affect Vascular Function in a Tissue-Engineered Blood Vessel Model of Hutchinson-Gilford Progeria Syndrome

Author

Leigh Atchison, Thomas J. Ribar, Nadia O. Abutaleb, George A. Truskey, Yantenew G. Gete, Kan Cao, Alim Ladha, and Elizabeth Snyder-Mounts

Subjects

0301 basic medicine, Male, Vasodilation, Biochemistry, tissue-engineered blood vessel, 0302 clinical medicine, Progeria, microphysiological system, Induced pluripotent stem cell, lcsh:QH301-705.5, lcsh:R5-920, integumentary system, Progerin, Tissue Donors, 3. Good health, Hutchinson-Gilford progeria syndrome, smooth muscle cells, medicine.anatomical_structure, Phenotype, medicine.symptom, lcsh:Medicine (General), vascular endothelium, Blood vessel, medicine.medical_specialty, congenital, hereditary, and neonatal diseases and abnormalities, Endothelium, induced pluripotent stem cells, Biology, Models, Biological, Article, shear stress, 03 medical and health sciences, Internal medicine, Genetics, medicine, Humans, Tissue Engineering, nutritional and metabolic diseases, Cell Biology, medicine.disease, Blood Vessel Prosthesis, Clone Cells, 030104 developmental biology, Endocrinology, lcsh:Biology (General), Gene Expression Regulation, Blood Vessels, 030217 neurology & neurosurgery, Vasoconstriction, Lamin, Developmental Biology

Abstract

Summary Hutchinson-Gilford progeria syndrome (HGPS) is a rare disorder caused by a point mutation in the Lamin A gene that produces the protein progerin. Progerin toxicity leads to accelerated aging and death from cardiovascular disease. To elucidate the effects of progerin on endothelial cells, we prepared tissue-engineered blood vessels (viTEBVs) using induced pluripotent stem cell-derived smooth muscle cells (viSMCs) and endothelial cells (viECs) from HGPS patients. HGPS viECs aligned with flow but exhibited reduced flow-responsive gene expression and altered NOS3 levels. Relative to viTEBVs with healthy cells, HGPS viTEBVs showed reduced function and exhibited markers of cardiovascular disease associated with endothelium. HGPS viTEBVs exhibited a reduction in both vasoconstriction and vasodilation. Preparing viTEBVs with HGPS viECs and healthy viSMCs only reduced vasodilation. Furthermore, HGPS viECs produced VCAM1 and E-selectin protein in TEBVs with healthy or HGPS viSMCs. In summary, the viTEBV model has identified a role of the endothelium in HGPS., Highlights • Smooth muscle and endothelial cells were derived from progeria and healthy donors • Progeria endothelial cells exhibit altered response to fluid shear stress • Functional engineered blood vessels were fabricated from iPSC-derived SMCs and ECs • Progeria donor-derived engineered blood vessels recapitulated the disease phenotype, Atchison and colleagues produced hiPSC-derived vascular smooth muscle cells and vascular endothelial cells from healthy and progeria patients. These cells were used to fabricate functional tissue-engineered blood vessels that express key features of the progeria cardiovascular phenotype. This work provides a novel platform to study progeria and other cardiovascular diseases using iPSC-derived cells in an in vitro platform.

Published

2018

18. Integrated gut/liver microphysiological systems elucidates inflammatory inter-tissue crosstalk

Author

Wen L.K. Chen, Collin Edington, Emily Suter, Jiajie Yu, Jeremy J. Velazquez, Jason G. Velazquez, Michael Shockley, Emma M. Large, Raman Venkataramanan, David J. Hughes, Cynthia L. Stokes, David L. Trumper, Rebecca L. Carrier, Murat Cirit, Linda G. Griffith, Douglas A. Lauffenburger, Institute for Medical Engineering and Science, Harvard University--MIT Division of Health Sciences and Technology, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Massachusetts Institute of Technology. Department of Mechanical Engineering, Chen, Wen Li, Edington, Collin D, Suter, Emily C, Yu, Jiajie, Velazquez, Jeremy J., Velazquez, Jason G, Shockley, Michael J, Trumper, David L, Carrier, Rebecca, Cirit, Murat, Griffith, Linda G, and Lauffenburger, Douglas A

Subjects

0301 basic medicine, Cell signaling, Chemokine, Colon, Kupffer Cells, medicine.medical_treatment, Bioengineering, Inflammation, Cell Communication, Biology, Applied Microbiology and Biotechnology, Article, Systems Biotechnology, sepsis, 03 medical and health sciences, gut‐liver interaction, Downregulation and upregulation, Lab-On-A-Chip Devices, medicine, Humans, Immunologic Factors, organ‐on‐a‐chip, microphysiological system, Cells, Cultured, Immunoassay, Miniaturization, CXCR3 ligands, FGF19, Articles, Equipment Design, Coculture Techniques, Cell biology, Equipment Failure Analysis, Systems Integration, Crosstalk (biology), 030104 developmental biology, Cytokine, Liver, Immunology, Hepatocytes, biology.protein, Cytokines, CXCL9, Caco-2 Cells, medicine.symptom, Biotechnology

Abstract

A capability for analyzing complex cellular communication among tissues is important in drug discovery and development, and in vitro technologies for doing so are required for human applications. A prominent instance is communication between the gut and the liver, whereby perturbations of one tissue can influence behavior of the other. Here, we present a study on human gut-liver tissue interactions under normal and inflammatory contexts, via an integrative multi-organ platform comprising human liver (hepatocytes and Kupffer cells), and intestinal (enterocytes, goblet cells, and dendritic cells) models. Our results demonstrated long-term (>2 weeks) maintenance of intestinal (e.g., barrier integrity) and hepatic (e.g., albumin) functions in baseline interaction. Gene expression data comparing liver in interaction with gut, versus isolation, revealed modulation of bile acid metabolism. Intestinal FGF19 secretion and associated inhibition of hepatic CYP7A1 expression provided evidence of physiologically relevant gut-liver crosstalk. Moreover, significant non-linear modulation of cytokine responses was observed under inflammatory gut-liver interaction; for example, production of CXCR3 ligands (CXCL9,10,11) was synergistically enhanced. RNA-seq analysis revealed significant upregulation of IFNα/β/γ signaling during inflammatory gut-liver crosstalk, with these pathways implicated in the synergistic CXCR3 chemokine production. Exacerbated inflammatory response in gut-liver interaction also negatively affected tissue-specific functions (e.g., liver metabolism). These findings illustrate how an integrated multi-tissue platform can generate insights useful for understanding complex pathophysiological processes such as inflammatory organ crosstalk., National Institutes of Health (U.S.) (grant UH3TR00069), United States. Defense Advanced Research Projects Agency (grant Microphysiological Systems Program (W911NF-12-2-00))

Published

2017

19. A Modular, Reconfigurable Microfabricated Assembly Platform for Microfluidic Transport and Multitype Cell Culture and Drug Testing

Author

Sushila Maharjan, Xin Xie, Carol Livermore, Yu Shrike Zhang, and Sanwei Liu

Subjects

Materials science, Fabrication, drug toxicity assay, Microfluidics, Nanotechnology, 02 engineering and technology, 01 natural sciences, Article, chemistry.chemical_compound, Stack (abstract data type), microphysiological system, Electrical and Electronic Engineering, Microelectromechanical systems, cell culture, Microchannel, Polydimethylsiloxane, business.industry, Mechanical Engineering, 010401 analytical chemistry, Reconfigurability, modular microassembly, Modular design, modular microfluidics, 021001 nanoscience & nanotechnology, 0104 chemical sciences, chemistry, Control and Systems Engineering, 0210 nano-technology, business

Abstract

Modular microfluidics offer the opportunity to combine the precise fluid control, rapid sample processing, low sample and reagent volumes, and relatively lower cost of conventional microfluidics with the flexible reconfigurability needed to accommodate the requirements of target applications such as drug toxicity studies. However, combining the capabilities of fully adaptable modular microelectromechanical systems (MEMS) assembly with the simplicity of conventional microfluidic fabrication remains a challenge. A hybrid polydimethylsiloxane (PDMS)-molding/photolithographic process is demonstrated to rapidly fabricate LEGO&reg, like modular blocks. The blocks are created with different sizes that interlock via tongue-and-groove joints in the plane and stack via interference fits out of the plane. These miniature strong but reversible connections have a measured resistance to in-plane and out-of-plane forces of up to &gt, 6000&times, and &gt, 1000&times, the weight of the block itself, respectively. The LEGO&reg, like interference fits enable O-ring-free microfluidic connections that withstand internal fluid pressures of &gt, 120 kPa. A single layer of blocks is assembled into LEGO&reg, like cell culture plates, where the in vitro biocompatibility and drug toxicity to lung epithelial adenocarcinoma cells and hepatocellular carcinoma cells cultured in the modular microwells are measured. A double-layer block structure is then assembled so that a microchannel formed at the interface between layers connects two microwells. Breast tumor cells and hepatocytes cultured in the coupled wells demonstrate interwell migration as well as the simultaneous effects of a single drug on the two cell types.

Published

2019

20. Priming nanoparticle-guided diagnostics and therapeutics towards human organs-on-chips microphysiological system

Author

Jaewon Lee, Jin-Ha Choi, Woojung Shin, Jeong-Woo Choi, and Hyun-Jung Kim

Subjects

Microphysiological system, 0301 basic medicine, Organs-on-chips, Materials science, Biocompatibility, General Engineering, Nanoparticle, Nanotechnology, Review, Nano-biotechnology, Therapeutics, 02 engineering and technology, 021001 nanoscience & nanotechnology, Rapid detection, 03 medical and health sciences, 030104 developmental biology, Biopharmaceutical, Drug development, Nanobiotechnology, General Materials Science, 0210 nano-technology, Diagnostics

Abstract

Nanotechnology and bioengineering have converged over the past decades, by which the application of multi-functional nanoparticles (NPs) has been emerged in clinical and biomedical fields. The NPs primed to detect disease-specific biomarkers or to deliver biopharmaceutical compounds have beena validated in conventional in vitro culture models including two dimensional (2D) cell cultures or 3D organoid models. However, a lack of experimental models that have strong human physiological relevance has hampered accurate validation of the safety and functionality of NPs. Alternatively, biomimetic human "Organs-on-Chips" microphysiological systems have recapitulated the mechanically dynamic 3D tissue interface of human organ microenvironment, in which the transport, cytotoxicity, biocompatibility, and therapeutic efficacy of NPs and their conjugates may be more accurately validated. Finally, integration of NP-guided diagnostic detection and targeted nanotherapeutics in conjunction with human organs-on-chips can provide a novel avenue to accelerate the NP-based drug development process as well as the rapid detection of cellular secretomes associated with pathophysiological processes.

Published

2016

21. The ascendance of microphysiological systems to solve the drug testing dilemma

Author

Tobias Hasenberg, Uwe Marx, and Eva-Maria Dehne

Subjects

0301 basic medicine, Process (engineering), business.industry, body-on-a-chip, Nanotechnology, Review, Dilemma, human-on-a-chip, 03 medical and health sciences, 030104 developmental biology, Risk analysis (engineering), Medicine, microphysiological system, multi-organ-chip, business, drug testing, Biotechnology

Abstract

The development of drugs is a process obstructed with manifold security and efficacy concerns. Although animal models are still widely used to meet the diligence required, they are regarded as outdated tools with limited predictability. Novel microphysiological systems intend to create systemic models of human biology. Their ability to host 3D organoid constructs in a controlled microenvironment with mechanical and electrophysiological stimuli enables them to create and maintain homeostasis. These platforms are, thus, envisioned to be superior tools for testing and developing substances such as drugs, cosmetics and chemicals. We will present reasons why microphysiological systems are required for the emerging demands, highlight current technological and regulatory obstacles, and depict possible solutions from state-of-the-art platforms from major contributors., Lay abstract Microphysiological systems are devices constructed for the cocultivation of miniaturized human organ equivalents. They are commonly placed into a continuous stream of nutrient solution. The microphysiological tools aim to reshape current development, toxicity testing and efficacy assessment of therapeutic agents, food additives, chemicals and environmental pollutants. We are on the verge of initiating a paradigm shift away from established, but often misleading animal and single tissue culture techniques toward the generation of predictive data for a compound's safety and efficacy prior to its exposure to humans.

Published

2017

22. An integrated in vitro model of perfused tumor and cardiac tissue

Author

Monica L. Moya, David Tran, and Steven C. George

Subjects

Pathology, medicine.medical_specialty, induced pluripotent stem cell, Cell Survival, Induced Pluripotent Stem Cells, Medicine (miscellaneous), microcirculation, Antineoplastic Agents, cardiomyocyte, 02 engineering and technology, Review, Biology, Biochemistry, Genetics and Molecular Biology (miscellaneous), In vitro model, Microcirculation, 03 medical and health sciences, Tissue engineering, Neoplasms, medicine, Myocyte, Animals, Humans, cancer, Myocytes, Cardiac, microphysiological system, Induced pluripotent stem cell, Organ system, 030304 developmental biology, 0303 health sciences, Cardiac muscle, Endothelial Cells, Cell Differentiation, Cell Biology, Microfluidic Analytical Techniques, 021001 nanoscience & nanotechnology, 3. Good health, medicine.anatomical_structure, Microvessels, Models, Animal, Molecular Medicine, Stem cell, 0210 nano-technology, Neuroscience

Abstract

Cancer and cardiovascular disease remain the two leading causes of death in the United States. Progress in treatment to reduce morbidity and mortality will include the development of new drugs. Recent advances in induced pluripotent stem cell technology, tissue engineering, and microfabrication techniques have created a unique opportunity to develop three-dimensional (3D) microphysiological systems that more accurately reflect in vivo human biology when compared with two-dimensional flat systems or animal models. Our group is working to develop 3D microphysiological systems using induced pluripotent stem cell technology that simulates the microcirculation, the cardiac muscle, and the solid tumor, and then to combine these systems into an integrated microphysiological system that simulates perfused cardiac muscle and solid tumor on a single platform. The platform will be initially validated to predict anti-cancer efficacy while minimizing cardiac muscle toxicity. A critical feature will be blood flow through a human microcirculation (capillaries and larger microvessels), which is necessary to overcome diffusion limitations of nutrients and waste products in realistic 3D cultures, and serves to integrate multiple organ systems. This is a necessary and critical feature of any platform that seeks to simulate integrated human organ systems. The results of our project should produce a new paradigm for efficient and accurate drug and toxicity screening, initially for anti-cancer drugs with minimal cardiac side effects, and a platform technology that can be eventually used to integrate multiple major organ systems of the human body.

Published

2014

23. Design considerations for an integrated microphysiological muscle tissue for drug and tissue toxicity testing

Author

Lauran Madden, William E. Kraus, Sungmin Hong, Kam W. Leong, Cristina E. Fernandez, Nenad Bursac, Youngmee Jung, George A. Truskey, Hon Fai Chan, William M. Reichert, Xuanhe Zhao, Hardean E. Achneck, Timothy R. Koves, and Cindy Cheng

Subjects

Muscle tissue, Tissue toxicity, Pulsatile flow, Medicine (miscellaneous), Review, 02 engineering and technology, Biology, Biochemistry, Genetics and Molecular Biology (miscellaneous), tissue-engineered blood vessel, Myoblasts, 03 medical and health sciences, Tissue engineering, In vivo, Toxicity Tests, medicine, Humans, Myocyte, microphysiological system, Muscle, Skeletal, 030304 developmental biology, 0303 health sciences, Tissue Engineering, oxygen gradients, Endothelial Cells, Skeletal muscle, differentiation, Cell Biology, Microfluidic Analytical Techniques, skeletal muscle myoblasts, contractile force, 021001 nanoscience & nanotechnology, Electric Stimulation, medicine.anatomical_structure, Molecular Medicine, Stress, Mechanical, Hydroxymethylglutaryl-CoA Reductase Inhibitors, 0210 nano-technology, Biological system, Blood vessel, Biomedical engineering

Abstract

Microphysiological systems provide a tool to simulate normal and pathological function of organs for prolonged periods. These systems must incorporate the key functions of the individual organs and enable interactions among the corresponding microphysiological units. The relative size of different microphysiological organs and their flow rates are scaled in proportion to in vivo values. We have developed a microphysiological three-dimensional engineered human skeletal muscle system connected to a circulatory system that consists of a tissue-engineered blood vessel as part of a high-pressure arterial system. The engineered human skeletal muscle tissue reproduces key mechanical behaviors of skeletal muscle in vivo. Pulsatile flow is produced using a novel computer-controlled magnetically activated ferrogel. The system is versatile and the muscle unit can be integrated with other organ systems. Periodic monitoring of biomechanical function provides a non-invasive assessment of the health of the tissue and a way to measure the response to drugs and toxins.

Published

2013

24. Farewell to Animal Testing: Innovations on Human Intestinal Microphysiological Systems

Author

Tae Hyun Kang and Hyun-Jung Kim

Subjects

0301 basic medicine, host-microbe interaction, lcsh:Mechanical engineering and machinery, microbiome, Review, Disease, Gut flora, Inflammatory bowel disease, 03 medical and health sciences, Immune system, inflammatory bowel disease, medicine, lcsh:TJ1-1570, Microbiome, microphysiological system, Electrical and Electronic Engineering, Animal testing, intestine, biology, disease model, Mechanical Engineering, biology.organism_classification, medicine.disease, Intestinal epithelium, 030104 developmental biology, gut-on-a-chip, Control and Systems Engineering, Intestinal Disorder, Neuroscience

Abstract

The human intestine is a dynamic organ where the complex host-microbe interactions that orchestrate intestinal homeostasis occur. Major contributing factors associated with intestinal health and diseases include metabolically-active gut microbiota, intestinal epithelium, immune components, and rhythmical bowel movement known as peristalsis. Human intestinal disease models have been developed; however, a considerable number of existing models often fail to reproducibly predict human intestinal pathophysiology in response to biological and chemical perturbations or clinical interventions. Intestinal organoid models have provided promising cytodifferentiation and regeneration, but the lack of luminal flow and physical bowel movements seriously hamper mimicking complex host-microbe crosstalk. Here, we discuss recent advances of human intestinal microphysiological systems, such as the biomimetic human “Gut-on-a-Chip” that can employ key intestinal components, such as villus epithelium, gut microbiota, and immune components under peristalsis-like motions and flow, to reconstitute the transmural 3D lumen-capillary tissue interface. By encompassing cutting-edge tools in microfluidics, tissue engineering, and clinical microbiology, gut-on-a-chip has been leveraged not only to recapitulate organ-level intestinal functions, but also emulate the pathophysiology of intestinal disorders, such as chronic inflammation. Finally, we provide potential perspectives of the next generation microphysiological systems as a personalized platform to validate the efficacy, safety, metabolism, and therapeutic responses of new drug compounds in the preclinical stage.

Published

2016