Your search keyword '"Microphysiological system"' showing total 32 results

1. IMSIS: An instrumented microphysiological system with integrated sensors for monitoring cellular metabolic activities.

Author

Cheng MH, Way R, Fresa K, Catandi GD, Carnevale E, Chicco AJ, and Chen TW

Subjects

Animals, Humans, Hydrogen Peroxide analysis, Hydrogen-Ion Concentration, Lab-On-A-Chip Devices, Mitochondria metabolism, Oxygen metabolism, Oxygen analysis, Biosensing Techniques instrumentation, Biosensing Techniques methods, Equipment Design, Microphysiological Systems

Abstract

Well plates are widely used in biological experiments, particularly in pharmaceutical sciences and cell biology. Its popularity stems from its versatility to support a variety of fluorescent markers for high throughput monitoring of cellular activities. However, using fluorescent markers in traditional well plates has its own challenges, namely, they can be potentially toxic to cells, and thus, may perturb their biological functions; and it is difficult to monitor multiple analytes concurrently and in real-time inside each well. This paper presents a fully instrumented microphysiological system with integrated sensors (IMSIS) with a similar well format. Each well in the microphysiological system has a set of sensors for monitoring multiple metabolic analytes in real-time. The IMSIS platform is supported by integrated bioelectronic circuits and a graphical user interface for easy user configuration and monitoring. The system has integrated microfluidics to maintain its microphysiological environment within each well. The IMSIS platform currently incorporates O 2 , H 2 O 2 , and pH sensors inside each well, allowing up to six wells to perform concurrent measurements in real-time. Furthermore, the architecture is scalable to achieve an even higher level of throughput. The miniaturized design ensures portability, suitable for small offices and field applications. The IMSIS platform was successfully used to monitor in real-time the mitochondrial functions of live bovine embryos in O 2 consumption, H 2 O 2 release as an indication of ROS production, and extracellular acidity changes before and after the introduction of external substrates., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024. Published by Elsevier B.V.)

Published

2024

2. Microphysiological Systems for Cancer Immunotherapy Research and Development.

Author

Peng Y and Lee E

Subjects

Animals, Humans, Precision Medicine instrumentation, Precision Medicine methods, Tumor Microenvironment immunology, Immunotherapy instrumentation, Immunotherapy methods, Microphysiological Systems, Neoplasms therapy, Neoplasms immunology

Abstract

Cancer immunotherapy focuses on the use of patients' adaptive immune systems to combat cancer. In the past decade, FDA has approved many immunotherapy products for cancer patients who suffer from primary tumors, tumor relapse, and metastases. However, these immunotherapies still show resistance in many patients and often lead to inconsistent responses in patients due to variations in tumor genetic mutations and tumor immune microenvironment. Microfluidics-based organ-on-a-chip technologies or microphysiological systems have opened new ways that can provide relatively fast screening for personalized immunotherapy and help researchers and clinicians understand tumor-immune interactions in a patient-specific manner. They also have the potential to overcome the limitations of traditional drug screening and testing, given the models provide a more realistic 3D microenvironment with better controllability, reproducibility, and physiological relevance. This review focuses on the cutting-edge microphysiological organ-on-a-chip devices developed in recent years for studying cancer immunity and testing cancer immunotherapeutic agents, as well as some of the largest challenges of translating this technology to clinical applications in immunotherapy and personalized medicine., (© 2023 Wiley‐VCH GmbH.)

Published

2024

3. 3D human tissue models and microphysiological systems for HIV and related comorbidities.

Subjects

Animals, Humans, Comorbidity, COVID-19 complications, Models, Biological, Tuberculosis complications, HIV Infections complications, Microphysiological Systems

Abstract

Three-dimensional (3D) human tissue models/microphysiological systems (e.g., organs-on-chips, organoids, and tissue explants) model HIV and related comorbidities and have potential to address critical questions, including characterization of viral reservoirs, insufficient innate and adaptive immune responses, biomarker discovery and evaluation, medical complexity with comorbidities (e.g., tuberculosis and SARS-CoV-2), and protection and transmission during pregnancy and birth. Composed of multiple primary or stem cell-derived cell types organized in a dedicated 3D space, these systems hold unique promise for better reproducing human physiology, advancing therapeutic development, and bridging the human-animal model translational gap. Here, we discuss the promises and achievements with 3D human tissue models in HIV and comorbidity research, along with remaining barriers with respect to cell biology, virology, immunology, and regulatory issues., Competing Interests: Declaration of interests D.E.Y. was previously an unpaid technical advisor for the non-profits Cover the Globe and Maipelo Trust. K.M.B. has received consulting fees from ViiV Healthcare. S.C. is the cofounder of OncoBeat, LLC, and a consultant of Vesalius Therapeutics. A.R.M. is a cofounder and has an equity interest in TISMOO, a company dedicated to genetic analysis and human brain organogenesis focusing on therapeutic applications customized for the autism spectrum disorders and other neurological disorders origin genetics. The terms of this arrangement have been reviewed and approved by the University of California, San Diego, in accordance with its conflict-of-interest policies. M.Z.S. is an employee of GlaxoSmithKline Research and Development, United Kingdom. L.E.W. is a co-inventor on a US patent describing systems and methods to model adaptive immune responses, assigned to Stanford University. The remaining authors declare no competing interests., (Published by Elsevier Ltd.)

Published

2024

4. Mechanobiological stimulation in organ-on-a-chip systems reduces hepatic drug metabolic capacity in favor of regenerative specialization.

Author

Scheidecker B, Poulain S, Sugimoto M, Arakawa H, Kim SH, Kawanishi T, Kato Y, Danoy M, Nishikawa M, and Sakai Y

Subjects

Hepatocytes metabolism, Gene Expression Profiling, Oxygen metabolism, Microphysiological Systems, Liver metabolism

Abstract

Hepatic physiology depends on the liver's complex structural composition which among others, provides high oxygen supply rates, locally differential oxygen tension, endothelial paracrine signaling, as well as residual hemodynamic shear stress to resident hepatocytes. While functional improvements were shown by implementing these factors into hepatic culture systems, direct cause-effect relationships are often not well characterized-obfuscating their individual contribution in more complex microphysiological systems. By comparing increasingly complex hepatic in vitro culture systems that gradually implement these parameters, we investigate the influence of the cellular microenvironment to overall hepatic functionality in pharmacological applications. Here, hepatocytes were modulated in terms of oxygen tension and supplementation, endothelial coculture, and exposure to fluid shear stress delineated from oxygen influx. Results from transcriptomic and metabolomic evaluation indicate that particularly oxygen supply rates are critical to enhance cellular functionality-with cellular drug metabolism remaining comparable to physiological conditions after prolonged static culture. Endothelial signaling was found to be a major contributor to differential phenotype formation known as metabolic zonation, indicated by WNT pathway activity. Lastly, oxygen-delineated shear stress was identified to direct cellular fate towards increased hepatic plasticity and regenerative phenotypes at the cost of drug metabolic functionality - in line with regenerative effects observed in vivo. With these results, we provide a systematic evaluation of critical parameters and their impact in hepatic systems. Given their adherence to physiological effects in vivo, this highlights the importance of their implementation in biomimetic devices, such as organ-on-a-chip systems. Considering recent advances in basic liver biology, direct translation of physiological structures into in vitro models is a promising strategy to expand the capabilities of pharmacological models., (© 2024 Wiley Periodicals LLC.)

Published

2024

5. Patient-Derived Microphysiological Systems for Precision Medicine.

Author

Ko J, Song J, Choi N, and Kim HN

Subjects

Humans, Precision Medicine, Lab-On-A-Chip Devices, Organoids, Microphysiological Systems, Induced Pluripotent Stem Cells physiology

Abstract

Patient-derived microphysiological systems (P-MPS) have emerged as powerful tools in precision medicine that provide valuable insight into individual patient characteristics. This review discusses the development of P-MPS as an integration of patient-derived samples, including patient-derived cells, organoids, and induced pluripotent stem cells, into well-defined MPSs. Emphasizing the necessity of P-MPS development, its significance as a nonclinical assessment approach that bridges the gap between traditional in vitro models and clinical outcomes is highlighted. Additionally, guidance is provided for engineering approaches to develop microfluidic devices and high-content analysis for P-MPSs, enabling high biological relevance and high-throughput experimentation. The practical implications of the P-MPS are further examined by exploring the clinically relevant outcomes obtained from various types of patient-derived samples. The construction and analysis of these diverse samples within the P-MPS have resulted in physiologically relevant data, paving the way for the development of personalized treatment strategies. This study describes the significance of the P-MPS in precision medicine, as well as its unique capacity to offer valuable insights into individual patient characteristics., (© 2023 The Authors. Advanced Healthcare Materials published by Wiley-VCH GmbH.)

Published

2024

6. Amplifying the impact of kidney microphysiological systems: predicting renal drug clearance using mechanistic modelling based on reconstructed drug secretion.

Author

Caetano-Pinto P, Nordell P, Nieskens T, Haughan K, Fenner KS, and Stahl SH

Subjects

Animals, Humans, Cidofovir pharmacology, Kidney metabolism, Drug Elimination Routes, Microphysiological Systems, Metformin metabolism, Metformin pharmacology

Abstract

Accurate prediction of pharmacokinetic parameters, such as renal clearance, is fundamental to the development of effective and safe new treatments for patients. However, conventional renal models have a limited ability to predict renal drug secretion, a process that is dependent on transporters in the proximal tubule. Improvements in microphysiological systems (MPS) have extended our in vitro capabilities to predict pharmacokinetic parameters. In this study a kidney-MPS model was developed that successfully recreated renal drug secretion. Human proximal tubule cells grown in the kidney-MPS, resem­bling an in vivo phenotype, actively secreted the organic cation drug metformin and organic anion drug cidofovir, in contrast to cells cultured in conventional culture formats. Metformin and cidofovir renal secretory clearance were predicted from kid­ney-MPS data within 3.3- and 1.3-fold, respectively, of clinically reported values by employing a semi-mechanistic drug distribution model using kidney-MPS drug transport parameters together with in vitro to in vivo extrapolation. This approach introduces an effective application of a kidney-MPS model coupled with pharmacokinetic modelling tools to evaluate and predict renal drug clearance in humans. Kidney-MPS renal clearance predictions can potentially complement pharma-cokinetic animal studies and contribute to the reduction of pre-clinical species use during drug development.

Published

2023

7. [Toward Regulatory Acceptance of MPS-Cardiac Safety Assessment as an Example].

Author

Yamazaki D

Subjects

Humans, Drug Discovery, Japan, Drug Industry, Liver, Microphysiological Systems

Abstract

Microphysiological system (MPS) are "Cell/tissue culture systems that reproduce in vivo organ functions in vitro by placing organ compartments that mimic the physiological environment of various organs such as the liver, small intestine, and lungs in micro-spaces." The MPS are attracting attention around the world as tools to improve human predictability in drug discovery research. In the U.S., in 2012, the NIH (National Institutes of Health) allocated a large budget to academia for research development of MPS. In Japan, the National Institute of Advanced Industrial Science and Technology and the NIHS (National Institute of Health Sciences) have been playing a central role in commercialization, performance evaluation, and standardization of MPS devices developed by academia for the liver, small intestine, kidney, and BBB as target organs/tissues in the AMED-MPS project that started in 2017. Pharmaceutical companies are beginning to utilize MPS in drug discovery research. However, MPS have only just been raised as a topic of discussion between regulatory authorities and pharmaceutical companies, and it will be necessary to overcome many barriers before data obtained by MPS can be included in drug approval documents and be widely accepted administratively. In this review, I would like to introduce cardiac safety evaluation as a concrete example to show what paths MPS should take to gain regulatory approval. In addition, I would like also to introduce human 3D heart tissue, which was developed in NIHS, as a cardiac MPS.

Published

2023

8. High‐Throughput Microfluidic 3D Outer Blood‐Retinal Barrier Model in a 96‐Well Format: Analysis of Cellular Interactions and Barrier Function in Retinal Health and Disease.

Author

Kim, Jiho, Song, Youngsook, Jolly, Amber L., Hwang, Taeseon, Kim, Suryong, Lee, Byungjun, Jang, Jinhwan, Jo, Dong Hyun, Baek, Kyusuk, Liu, Tsung‐Li, Yoo, Sanghee, and Jeon, Noo Li

Subjects

*MACULAR degeneration, *MICROPHYSIOLOGICAL systems, *DRUG discovery, *EYE abnormalities, *RHODOPSIN

Abstract

Numerous diseases, including age‐related macular degeneration (AMD), arise from the blood‐retinal barrier and blood vessel abnormalities in the eye; unfortunately, there is a lack of reliable in vitro models for their systematic study. This study describes a high‐throughput microphysiological system (MPS) designed to model the outer Blood‐Retinal Barrier (oBRB). The MPS platform is engineered to integrate seamlessly with high‐content screening technologies, utilizing a design with a single oBRB model incorporating RPE (retina pigment epithelial cells) and endothelial cell co‐culture to fit within a single 96‐well. Arranged in the standard 96‐well plate format, the platform allows high‐throughput assessment of barrier integrity through 3D confocal imaging (ZO‐1 staining), Trans Epithelial Electrical Resistance (TEER), and permeability measurements. The oBRB model enables the investigation of crosstalk among different cell types in co‐culture. This includes assessing changes in the barrier integrity of the Retinal Pigment Epithelium (RPE) monolayer and investigating neovascularization events resulting from endothelial cell remodeling. The platform is positioned for utility in drug discovery and development efforts targeting diseases involving oBRB damage and choroidal neovascularization, such as age‐related macular degeneration. [ABSTRACT FROM AUTHOR]

Published

2024

9. Predicting Clinical Outcomes of SARS‐CoV‐2 Drug Efficacy with a High‐Throughput Human Airway Microphysiological System.

Author

Lopez Quezada, Landys, Mba Medie, Felix, Luu, Rebeccah J., Gaibler, Robert B., Gabriel, Elizabeth P., Rubio, Logan D., Mulhern, Thomas J., Marr, Elizabeth E., Borenstein, Jeffrey T., Fisher, Christine R., and Gard, Ashley L.

Subjects

MICROPHYSIOLOGICAL systems, DRUG discovery, AIRWAY (Anatomy), DRUG efficacy, LEAD compounds

Abstract

The average cost to bring a new drug from its initial discovery to a patient's bedside is estimated to surpass $2 billion and requires over a decade of research and development. There is a need for new drug screening technologies that can parse drug candidates with increased likelihood of clinical utility early in development in order to increase the cost‐effectiveness of this pipeline. For example, during the COVID‐19 pandemic, resources were rapidly mobilized to identify effective therapeutic treatments but many lead antiviral compounds failed to demonstrate efficacy when progressed to human trials. To address the lack of predictive preclinical drug screening tools, PREDICT96‐ALI, a high‐throughput (n = 96) microphysiological system (MPS) that recapitulates primary human tracheobronchial tissue,is adapted for the evaluation of differential antiviral efficacy of native SARS‐CoV‐2 variants of concern. Here, PREDICT96‐ALI resolves both the differential viral kinetics between variants and the efficacy of antiviral compounds over a range of drug doses. PREDICT96‐ALI is able to distinguish clinically efficacious antiviral therapies like remdesivir and nirmatrelvir from promising lead compounds that do not show clinical efficacy. Importantly, results from this proof‐of‐concept study track with known clinical outcomes, demonstrate the feasibility of this technology as a prognostic drug discovery tool. [ABSTRACT FROM AUTHOR]

Published

2024

10. Development of a Novel Microphysiological System for Peripheral Neurotoxicity Prediction Using Human iPSC-Derived Neurons with Morphological Deep Learning.

Author

Han, Xiaobo, Matsuda, Naoki, Yamanaka, Makoto, and Suzuki, Ikuro

Subjects

MICROPHYSIOLOGICAL systems, POISONS, PERIPHERAL neuropathy, ANTINEOPLASTIC agents, DRUG side effects, DEEP learning

Abstract

A microphysiological system (MPS) is an in vitro culture technology that reproduces the physiological microenvironment and functionality of humans and is expected to be applied for drug screening. In this study, we developed an MPS for the structured culture of human iPSC-derived sensory neurons and then predicted drug-induced neurotoxicity by morphological deep learning. Using human iPSC-derived sensory neurons, after the administration of representative anti-cancer drugs, the toxic effects on soma and axons were evaluated by an AI model with neurite images. Significant toxicity was detected in positive drugs and could be classified by different effects on soma or axons, suggesting that the current method provides an effective evaluation of chemotherapy-induced peripheral neuropathy. The results of neurofilament light chain expression changes in the MPS device also agreed with clinical reports. Therefore, the present MPS combined with morphological deep learning is a useful platform for in vitro peripheral neurotoxicity assessment. [ABSTRACT FROM AUTHOR]

Published

2024

11. Improved functionality of hepatic spheroids cultured in acoustic levitation compared to existing 2D and 3D models.

Author

Rabiet, Lucile, Jeger-Madiot, Nathan, García, Duván Rojas, Tosca, Lucie, Tachdjian, Gérard, Kellouche, Sabrina, Agniel, Rémy, Larghero, Jérôme, Aider, Jean-Luc, and Arakelian, Lousineh

Subjects

*MICROPHYSIOLOGICAL systems, *DRUG discovery, *APPROPRIATE technology, *DNA damage, *CELL survival

Abstract

Hepatic spheroids are of high interest in basic research, drug discovery and cell therapy. Existing methods for spheroid culture present advantages and drawbacks. An alternative technology is explored: the hepatic spheroid formation and culture in an acoustofluidic chip, using HepaRG cell line. Spheroid formation and morphology, cell viability, genetic stability, and hepatic functions are analyzed after 6 days of culture in acoustic levitation. They are compared to 2D culture and non-levitated 3D cultures. Sizes of the 25 spheroids created in a single acoustofluidic microphysiological system are homogeneous. The acoustic parameters in our system do not induce cell mortality nor DNA damage. Spheroids are cohesive and dense. From a functional point of view, hepatic spheroids obtained by acoustic levitation exhibit polarity markers, secrete albumin and express hepatic genes at higher levels compared to 2D and low attachment 3D cultures. In conclusion, this microphysiological system proves not only to be suitable for long-term culture of hepatic spheroids, but also to favor differentiation and functionality within 6 days of culture. [ABSTRACT FROM AUTHOR]

Published

2024

12. A three-dimensional valve-on-chip microphysiological system implicates cell cycle progression, cholesterol metabolism and protein homeostasis in early calcific aortic valve disease progression.

Author

Tandon, Ishita, Woessner, Alan E., Ferreira, Laίs A., Shamblin, Christine, Vaca-Diez, Gustavo, Walls, Amanda, Kuczwara, Patrick, Applequist, Alexis, Nascimento, Denise F., Tandon, Swastika, Kim, Jin-Woo, Rausch, Manuel, Timek, Tomasz, Padala, Muralidhar, Kinter, Michael T., Province, Dennis, Byrum, Stephanie D., Quinn, Kyle P., and Balachandran, Kartik

Subjects

AORTIC valve diseases, MICROPHYSIOLOGICAL systems, CELL metabolism, CHOLESTEROL metabolism, INTERSTITIAL cells, AORTIC valve

Abstract

Calcific aortic valve disease (CAVD) is one of the most common forms of valvulopathy, with a 50 % elevated risk of a fatal cardiovascular event, and greater than 15,000 annual deaths in North America alone. The treatment standard is valve replacement as early diagnostic, mitigation, and drug strategies remain underdeveloped. The development of early diagnostic and therapeutic strategies requires the fabrication of effective in vitro valve mimetic models to elucidate early CAVD mechanisms. In this study, we developed a multilayered physiologically relevant 3D valve-on-chip (VOC) system that incorporated aortic valve mimetic extracellular matrix (ECM), porcine aortic valve interstitial cell (VIC) and endothelial cell (VEC) co-culture and dynamic mechanical stimuli. Collagen and glycosaminoglycan (GAG) based hydrogels were assembled in a bilayer to mimic healthy or diseased compositions of the native fibrosa and spongiosa. Multiphoton imaging and proteomic analysis of healthy and diseased VOCs were performed. Collagen-based bilayered hydrogel maintained the phenotype of the VICs. Proteins related to cellular processes like cell cycle progression, cholesterol biosynthesis, and protein homeostasis were found to be significantly altered and correlated with changes in cell metabolism in diseased VOCs. This study suggested that diseased VOCs may represent an early, adaptive disease initiation stage, which was corroborated by human aortic valve proteomic assessment. In this study, we developed a collagen-based bilayered hydrogel to mimic healthy or diseased compositions of the native fibrosa and spongiosa layers. When the gels were assembled in a VOC with VECs and VICs, the diseased VOCs revealed key insights about the CAVD initiation process. Calcific aortic valve disease (CAVD) elevates the risk of death due to cardiovascular pathophysiology by 50 %, however, prevention and mitigation strategies are lacking, clinically. Developing tools to assess early disease would significantly aid in the prevention of disease and in the development of therapeutics. Previously, studies have utilized collagen and glycosaminoglycan-based hydrogels for valve cell co-cultures, valve cell co-cultures in dynamic environments, and inorganic polymer-based multilayered hydrogels; however, these approaches have not been combined to make a physiologically relevant model for CAVD studies. We fabricated a bi-layered hydrogel that closely mimics the aortic valve and used it for valve cell co-culture in a dynamic platform to gain mechanistic insights into the CAVD initiation process using proteomic and multiphoton imaging assessment. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

13. A Pumpless, High‐Throughput Microphysiological System to Mimic Enteric Innervation of Duodenal Epithelium and the Impact on Barrier Function.

Author

Kaiser, Kyla N., Snyder, Jessica R., Koppes, Ryan A., and Koppes, Abigail N.

Subjects

*ENTERIC nervous system, *MICROPHYSIOLOGICAL systems, *EPIDERMAL growth factor, *NERVE tissue, *WNT genes

Abstract

Enteric neurons are critical in maintaining organ homeostasis within the small intestine, and their dysregulation are implicated in gastrointestinal disorders and neurodegenerative diseases. Most in vitro models lack enteric innervation, limiting basic discovery and disease modeling research. Here, a high‐throughput 3D microphysiological system (MPS), or organ chip is presented that supports a primary epithelial monolayer interfacing directly with encapsulated primary enteric neurons. The device features twelve 3D MPSs per device and gravity‐driven flow via a laboratory rocker to induce biomimetic shear stress on the epithelium culture and provide continuous nutrient presentation. Intestinal and neural tissue exhibited expected morphologies. Neural gene upregulation in the epithelium suggests RNA contamination from proximal enteric neurons extending neurites toward the epithelial monolayer. With the enteric nervous system (ENS), barrier integrity significantly increased for both TEER and permeability assays, a 1.25‐fold greater resistance and 10% lower permeability as compared to epithelium cultured alone. The presence of the ENS resulted in a significant (1.4‐fold) reduction in epidermal growth factor (EGF). Additionally, several key epithelial genes are compared between duodenal tissue and epithelial monolayers with and without neurons present. Results demonstrated changes in cytokine gene expression and WNT pathways, highlighting innervation is essential to create more biomimetic and physiologically relevant in vitro models. [ABSTRACT FROM AUTHOR]

Published

2024

14. A Microphysiological System with an Anaerobic Air‐Liquid Interface and Functional Mucus Layer for Coculture of Intestinal Bacteria and Primary Human Colonic Epithelium.

Author

Kim, Raehyun and Allbritton, Nancy L.

Subjects

MICROPHYSIOLOGICAL systems, INTESTINAL mucosa, ANAEROBIC bacteria, LACTOBACILLUS rhamnosus, PATHOGENIC bacteria

Abstract

Coculture of intestinal bacteria with primary human intestinal epithelium provides a valuable tool for investigating host‐colon bacterial interactions and for testing and screening therapeutics. However, most current intestinal model systems lack key physiological features of the in vivo colon, such as both a proper oxygen microenvironment and a mucus layer. In this work, a new in vitro colonic microphysiological system is demonstrated with a cell‐derived, functional mucus that closely resembles the in vivo colonic mucosa and apical microenvironment by employing an anaerobic air‐liquid interface culture. The human primary colon epithelial cells in this new in vitro system exhibit high cell viability (>98%) with ≈100 µm thick functional mucus layer on average. Successful coculture of model anaerobic gut bacterial strains Lactobacillus rhamnosus GG and Anaerobutyricum hallii without loss in human cell viability demonstrates that this new model can be an invaluable tool for future studies of the impact of commensal and pathogenic bacteria on the colon. [ABSTRACT FROM AUTHOR]

Published

2024

15. A dynamic flow fetal membrane organ-on-a-chip system for modeling the effects of amniotic fluid motion.

Author

Kim, Sungjin, Lam, Po Yi, Richardson, Lauren S., Menon, Ramkumar, and Han, Arum

Subjects

FETAL membranes, MICROPHYSIOLOGICAL systems, AMNIOTIC liquid, AMNION, CELL physiology, SHEARING force

Abstract

Fetal membrane (amniochorion), the innermost lining of the intrauterine cavity, surround the fetus and enclose amniotic fluid. Unlike unidirectional blood flow, amniotic fluid subtly rocks back and forth, and thus, the innermost amnion epithelial cells are continuously exposed to low levels of shear stress from fluid undulation. Here, we tested the impact of fluid motion on amnion epithelial cells (AECs) as a bearer of force impact and their potential vulnerability to cytopathologic changes that can destabilize fetal membrane functions. A previously developed amnion membrane (AM) organ-on-chip (OOC) was utilized but with dynamic flow to culture human fetal amnion membrane cells. The applied flow was modulated to perfuse culture media back and forth for 48 h to mimic fluid motion. A static culture condition was used as a negative control, and oxidative stress (OS) condition was used as a positive control representing pathophysiological changes. The impacts of fluidic motion were evaluated by measuring cell viability, cellular transition, and inflammation. Additionally, scanning electron microscopy (SEM) imaging was performed to observe microvilli formation. The results show that regardless of the applied flow rate, AECs and AMCs maintained their viability, morphology, innate meta-state, and low production of pro-inflammatory cytokines. E-cadherin expression and microvilli formation in the AECs were upregulated in a flow rate-dependent fashion; however, this did not impact cellular morphology or cellular transition or inflammation. OS treatment induced a mesenchymal morphology, significantly higher vimentin to cytokeratin 18 (CK-18) ratio, and pro-inflammatory cytokine production in AECs, whereas AMCs did not respond in any significant manner. Fluid motion and shear stress, if any, did not impact AEC cell function and did not cause inflammation. Thus, when using an amnion membrane OOC model, the inclusion of a dynamic flow environment is not necessary to mimic in utero physiologic cellular conditions of an amnion membrane. [ABSTRACT FROM AUTHOR]

Published

2024

16. Oxygenator assisted dynamic microphysiological culture elucidates the impact of hypoxia on valvular interstitial cell calcification.

Author

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

Subjects

*MICROPHYSIOLOGICAL systems, *AORTIC valve diseases, *HUMAN cell culture, *INTERSTITIAL cells, *AORTIC valve

Abstract

Introduction: Microphysiological systems (MPS) offer simulation of (patho)physiological parameters. Investigation includes items which lead to fibrosis and calcification in development and progress of calcific aortic valve disease, based e.g. on culturing of isolated valvular interstitial cells (VICs). Hypoxia regulated by hypoxia inducible factors impacts pathological differentiation in aortic valve (AV) disease. This is mimicked via an MPS implemented oxygenator in combination with calcification inducing medium supplementation. Methods: Human valvular interstitial cells were isolated and dynamically cultured in MPS at hypoxic, normoxic, arterial blood oxygen concentration and cell incubator condition. Expression profile of fibrosis and calcification markers was monitored and calcification was quantified in induction and control media with and without hypoxia and in comparison to statically cultured counterparts. Results: Hypoxic 24-hour culture of human VICs leads to HIF1α nuclear localization and induction of EGLN1, EGLN3 and LDHA mRNA expression but does not directly impact expression of fibrosis and calcification markers. Dependent on medium formulation, induction medium induces monolayer calcification and elevates RUNX2, ACTA2 and FN1 but reduces SOX9 mRNA expression in dynamic and static MPS culture. But combining hypoxic oxygen concentration leads to higher calcification potential of human VICs in calcification and standard medium formulation dynamically cultured for 96 h. Conclusion: In hypoxic oxygen concentration an increased human VIC calcification in 2D VIC culture in an oxygenator assisted MPS was detected. Oxygen regulation therefore can be combined with calcification induction media to monitor additional effects of pathological marker expression. Validation of oxygenator dependent VIC behavior envisions future advancement and transfer to long term aortic valve tissue culture MPS. [ABSTRACT FROM AUTHOR]

Published

2024

17. Microphysiological system with integrated sensors to study the effect of pulsed electric field.

Author

Bakute, Neringa, Andriukonis, Eivydas, Kasperaviciute, Kamile, Dobilas, Jorunas, Sapurov, Martynas, Mozolevskis, Gatis, and Stirke, Arunas

Subjects

*MICROPHYSIOLOGICAL systems, *ELECTRIC field effects, *SOFT lithography, *ELECTRIC fields, *CELL permeability

Abstract

This study focuses on the use of pulsed electric fields (PEF) in microfluidics for controlled cell studies. The commonly used material for soft lithography, polydimethylsiloxane (PDMS), does not fully ensure the necessary chemical and mechanical resistance in these systems. Integration of specific analytical measurement setups into microphysiological systems (MPS) are also challenging. We present an off-stoichiometry thiol-ene (OSTE)-based microchip, containing integrated electrodes for PEF and transepithelial electrical resistance (TEER) measurement and the equipment to monitor pH and oxygen concentration in situ. The effectiveness of the MPS was empirically demonstrated through PEF treatment of the C6 cells. The effects of PEF treatment on cell viability and permeability to the fluorescent dye DapI were tested in two modes: stop flow and continuous flow. The maximum permeability was achieved at 1.8 kV/cm with 16 pulses in stop flow mode and 64 pulses per cell in continuous flow mode, without compromising cell viability. Two integrated sensors detected changes in oxygen concentration before and after the PEF treatment, and the pH shifted towards alkalinity following PEF treatment. Therefore, our proof-of-concept technology serves as an MPS for PEF treatment of mammalian cells, enabling in situ physiological monitoring. [ABSTRACT FROM AUTHOR]

Published

2024

18. Collagen concentration regulates neutrophil extravasation and migration in response to infection in an endothelium dependent manner.

Author

Calo, Christopher J., Patil, Tanvi, Palizzi, Mallory, Wheeler, Nicola, and Hind, Laurel E.

Subjects

VASCULAR endothelium, NEUTROPHILS, MICROPHYSIOLOGICAL systems, EXTRACELLULAR matrix proteins, COLLAGEN, QUORUM sensing, TISSUE mechanics, ENDOTHELIUM diseases

Abstract

Introduction: As the body's first line of defense against disease and infection, neutrophils must efficiently navigate to sites of inflammation; however, neutrophil dysregulation contributes to the pathogenesis of numerous diseases that leave people susceptible to infections. Many of these diseases are also associated with changes to the protein composition of the extracellular matrix. While it is known that neutrophils and endothelial cells, which play a key role in neutrophil activation, are sensitive to the mechanical and structural properties of the extracellular matrix, our understanding of how protein composition in the matrix affects the neutrophil response to infection is incomplete. Methods: To investigate the effects of extracellular matrix composition on the neutrophil response to infection, we used an infection-on-a-chip microfluidic device that replicates a portion of a blood vessel endothelium surrounded by a model extracellular matrix. Model blood vessels were fabricated by seeding human umbilical vein endothelial cells on 2, 4, or 6 mg/mL type I collagen hydrogels. Primary human neutrophils were loaded into the endothelial lumens and stimulated by adding the bacterial pathogen Pseudomonas aeruginosa to the surrounding matrix. Results: Collagen concentration did not affect the cell density or barrier function of the endothelial lumens. Upon infectious challenge, we found greater neutrophil extravasation into the 4 mg/mL collagen gels compared to the 6 mg/mL collagen gels. We further found that extravasated neutrophils had the highest migration speed and distance in 2mg/mL gels and that these values decreased with increasing collagen concentration. However, these phenomena were not observed in the absence of an endothelial lumen. Lastly, no differences in the percent of extravasated neutrophils producing reactive oxygen species were observed across the various collagen concentrations. Discussion: Our study suggests that neutrophil extravasation and migration in response to an infectious challenge are regulated by collagen concentration in an endothelial cell-dependent manner. The results demonstrate how the mechanical and structural aspects of the tissue microenvironment affect the neutrophil response to infection. Additionally, these findings underscore the importance of developing and using microphysiological systems for studying the regulatory factors that govern the neutrophil response. [ABSTRACT FROM AUTHOR]

Published

2024

19. Modeling lung endothelial dysfunction in sepsis‐associated ARDS using a microphysiological system.

Author

Liang, Nai‐Wen, Wilson, Carole, Davis, Brooke, Wolf, Ian, Qyli, Tonela, Moy, Joy, Beebe, David J., Schnapp, Lynn M., Kerr, Sheena C., and Faust, Hilary E.

Subjects

*MICROPHYSIOLOGICAL systems, *ENDOTHELIUM diseases, *ADULT respiratory distress syndrome, *LUNGS

Abstract

Endothelial dysfunction is a critical feature of acute respiratory distress syndrome (ARDS) associated with higher disease severity and worse outcomes. Preclinical in vivo models of sepsis and ARDS have failed to yield useful therapies in humans, perhaps due to interspecies differences in inflammatory responses and heterogeneity of human host responses. Use of microphysiological systems (MPS) to investigate lung endothelial function may shed light on underlying mechanisms and targeted treatments for ARDS. We assessed the response to plasma from critically ill sepsis patients in our lung endothelial MPS through measurement of endothelial permeability, expression of adhesion molecules, and inflammatory cytokine secretion. Sepsis plasma induced areas of endothelial cell (EC) contraction, loss of cellular coverage, and luminal defects. EC barrier function was significantly worse following incubation with sepsis plasma compared to healthy plasma. EC ICAM‐1 expression, IL‐6 and soluble ICAM‐1 secretion increased significantly more after incubation with sepsis plasma compared with healthy plasma. Plasma from sepsis patients who developed ARDS further increased IL‐6 and sICAM‐1 compared to plasma from sepsis patients without ARDS and healthy plasma. Our results demonstrate the proof of concept that lung endothelial MPS can enable interrogation of specific mechanisms of endothelial dysfunction that promote ARDS in sepsis patients. [ABSTRACT FROM AUTHOR]

Published

2024

20. Zoledronic acid and ibandronate-induced nephrotoxicity in 2D and 3D proximal tubule cells derived from human and rat.

Author

Valencia, Leslie J, Tseng, Min, Chu, Mei-Lan, Yu, Lanlan, Adedeji, Adeyemi O, and Kiyota, Tomomi

Subjects

*ZOLEDRONIC acid, *MICROPHYSIOLOGICAL systems, *NEPHROTOXICOLOGY, *CANCER cell culture, *CYTOTOXINS, *ACUTE kidney failure

Abstract

Drug-induced proximal tubule (PT) injury remains a serious safety concern throughout drug development. Traditional in vitro 2-dimensional (2D) and preclinical in vivo models often fail to predict drug-related injuries presented in clinical trials. Various 3-dimensional (3D) microphysiological systems (MPSs) have been developed to mimic physiologically relevant properties, enabling them to be more predictive toward nephrotoxicity. To explore the capabilities of an MPS across species, we compared cytotoxicity in hRPTEC/TERT1s and rat primary proximal tubular epithelial cells (rPPTECs) following exposure to zoledronic acid and ibandronate (62.5–500 µM), and antibiotic polymyxin B (PMB) (50 and 250 µM, respectively). For comparison, we investigated cytotoxicity using 2D cultured hRPTEC/TERT1s and rPPTECs following exposure to the same drugs, including overlapping concentrations, as their 3D counterparts. Regardless of the in vitro model, bisphosphonate-exposed rPPTECs exhibited cytotoxicity quicker than hRPTEC/TERT1s. PMB was less sensitive toward nephrotoxicity in rPPTECs than hRPTEC/TERT1s, demonstrating differences in species sensitivity within both 3D and 2D models. Generally, 2D cultured cells experienced faster drug-induced cytotoxicity compared to the MPSs, suggesting that MPSs can be advantageous for longer-term drug-exposure studies, if warranted. Furthermore, ibandronate-exposed hRPTEC/TERT1s and rPPTECs produced higher levels of inflammatory and kidney injury biomarkers compared to zoledronic acid, indicating that ibandronate induces acute kidney injury, but also a potential protective response since ibandronate is less toxic than zoledronic acid. Our study suggests that the MPS model can be used for preclinical screening of compounds prior to animal studies and human clinical trials. [ABSTRACT FROM AUTHOR]

Published

2024

21. Adipose Tissue in Breast Cancer Microphysiological Models to Capture Human Diversity in Preclinical Models.

Author

Hamel, Katie M., Frazier, Trivia P., Williams, Christopher, Duplessis, Tamika, Rowan, Brian G., Gimble, Jeffrey M., and Sanchez, Cecilia G.

Subjects

*ADIPOSE tissues, *BREAST, *ANIMAL models in research, *MICROPHYSIOLOGICAL systems, *BREAST cancer, *EXTRACELLULAR matrix

Abstract

Female breast cancer accounts for 15.2% of all new cancer cases in the United States, with a continuing increase in incidence despite efforts to discover new targeted therapies. With an approximate failure rate of 85% for therapies in the early phases of clinical trials, there is a need for more translatable, new preclinical in vitro models that include cellular heterogeneity, extracellular matrix, and human-derived biomaterials. Specifically, adipose tissue and its resident cell populations have been identified as necessary attributes for current preclinical models. Adipose-derived stromal/stem cells (ASCs) and mature adipocytes are a normal part of the breast tissue composition and not only contribute to normal breast physiology but also play a significant role in breast cancer pathophysiology. Given the recognized pro-tumorigenic role of adipocytes in tumor progression, there remains a need to enhance the complexity of current models and account for the contribution of the components that exist within the adipose stromal environment to breast tumorigenesis. This review article captures the current landscape of preclinical breast cancer models with a focus on breast cancer microphysiological system (MPS) models and their counterpart patient-derived xenograft (PDX) models to capture patient diversity as they relate to adipose tissue. [ABSTRACT FROM AUTHOR]

Published

2024

22. Recent Advances in the Gastrointestinal Complex in Vitro Model for ADME Studies.

Author

Michiba, Kazuyoshi, Watanabe, Kengo, Imaoka, Tomoki, and Nakai, Daisuke

Subjects

*MICROPHYSIOLOGICAL systems, *DRUG discovery, *INTESTINAL absorption, *RESEARCH questions, *INVESTIGATIONAL drugs, *INTESTINAL physiology, *ABSORPTION

Abstract

Intestinal absorption is a complex process involving the permeability of the epithelial barrier, efflux transporter activity, and intestinal metabolism. Identifying the key factors that govern intestinal absorption for each investigational drug is crucial. To assess and predict intestinal absorption in humans, it is necessary to leverage appropriate in vitro systems. Traditionally, Caco-2 monolayer systems and intestinal Ussing chamber studies have been considered the 'gold standard' for studying intestinal absorption. However, these methods have limitations that hinder their universal use in drug discovery and development. Recently, there has been an increasing number of reports on complex in vitro models (CIVMs) using human intestinal organoids derived from intestinal tissue specimens or iPSC-derived enterocytes plated on 2D or 3D in microphysiological systems. These CIVMs provide a more physiologically relevant representation of key ADME-related proteins compared to conventional in vitro methods. They hold great promise for use in drug discovery and development due to their ability to replicate the expressions and functions of these proteins. This review highlights recent advances in gut CIVMs employing intestinal organoid model systems compared to conventional methods. It is important to note that each CIVM should be tailored to the investigational drug properties and research questions at hand. [ABSTRACT FROM AUTHOR]

Published

2024

23. Machine learning chained neural network analysis of oxygen transport amplifies the physiological relevance of vascularized microphysiological systems.

Author

Tronolone, James J., Mathur, Tanmay, Chaftari, Christopher P., Sun, Yuxiang, and Jain, Abhishek

Subjects

*PHYSIOLOGICAL transport of oxygen, *ISLANDS of Langerhans, *MACHINE learning, *HUMAN biology, *BIOLOGICAL systems, *CELL transplantation, *OXYGEN consumption, *MICROPHYSIOLOGICAL systems

Abstract

Since every biological system requires capillaries to support its oxygenation, design of engineered preclinical models of such systems, for example, vascularized microphysiological systems (vMPS) have gained attention enhancing the physiological relevance of human biology and therapies. But the physiology and function of formed vessels in the vMPS is currently assessed by non‐standardized, user‐dependent, and simple morphological metrics that poorly relate to the fundamental function of oxygenation of organs. Here, a chained neural network is engineered and trained using morphological metrics derived from a diverse set of vMPS representing random combinations of factors that influence the vascular network architecture of a tissue. This machine‐learned algorithm outputs a singular measure, termed as vascular network quality index (VNQI). Cross‐correlation of morphological metrics and VNQI against measured oxygen levels within vMPS revealed that VNQI correlated the most with oxygen measurements. VNQI is sensitive to the determinants of vascular networks and it consistently correlates better to the measured oxygen than morphological metrics alone. Finally, the VNQI is positively associated with the functional outcomes of cell transplantation therapies, shown in the vascularized islet‐chip challenged with hypoxia. Therefore, adoption of this tool will amplify the predictions and enable standardization of organ‐chips, transplant models, and other cell biosystems. [ABSTRACT FROM AUTHOR]

Published

2023

24. Organ-on-a-Chip and Microfluidic Platforms for Oncology in the UK.

Author

Nolan, Joanne, Pearce, Oliver M. T., Screen, Hazel R. C., Knight, Martin M., and Verbruggen, Stefaan W.

Subjects

*BIOLOGICAL models, *THERAPEUTICS, *RESEARCH methodology, *MICROFLUIDIC analytical techniques, *METASTASIS, *TISSUE culture, *MICROPHYSIOLOGICAL systems, *BIOCHIPS, *ONCOLOGY, *MEDICAL research, *SARCOMA

Abstract

Simple Summary: Organ-on-a-chip models, or organ chips, are tiny devices designed to accurately recreate the natural physiology and mechanical forces that cells experience in the human body. Similar to computer microchips, though carrying fluid through channels instead of an electric current, organ-chips are lined with living human cells and their tiny channels can reproduce blood and/or airflow just as in the human body. Their flexibility allows the chips to recreate breathing motions or undergo muscle contractions. This new and rapidly expanding field of research provides a unique opportunity to build models of human organs and to study how cancer cells develop and spread within them. As these chips are simpler and cheaper than animal models of cancer, they could significantly increase the speed of drug discovery and testing in cancer research. This exciting potential has led to the rapid development of this technology in the United Kingdom, with active research on a range of cancer types. This review covers the broad sweep of organ-chip research in the UK, and the network of researchers and companies being developed. Finally, it concludes with a perspective on the future directions in the field as researchers aim to bring about a leap forward in cancer therapies. Organ-on-chip systems are capable of replicating complex tissue structures and physiological phenomena. The fine control of biochemical and biomechanical cues within these microphysiological systems provides opportunities for cancer researchers to build complex models of the tumour microenvironment. Interest in applying organ chips to investigate mechanisms such as metastatsis and to test therapeutics has grown rapidly, and this review draws together the published research using these microfluidic platforms to study cancer. We focus on both in-house systems and commercial platforms being used in the UK for fundamental discovery science and therapeutics testing. We cover the wide variety of cancers being investigated, ranging from common carcinomas to rare sarcomas, as well as secondary cancers. We also cover the broad sweep of different matrix microenvironments, physiological mechanical stimuli and immunological effects being replicated in these models. We examine microfluidic models specifically, rather than organoids or complex tissue or cell co-cultures, which have been reviewed elsewhere. However, there is increasing interest in incorporating organoids, spheroids and other tissue cultures into microfluidic organ chips and this overlap is included. Our review includes a commentary on cancer organ-chip models being developed and used in the UK, including work conducted by members of the UK Organ-on-a-Chip Technologies Network. We conclude with a reflection on the likely future of this rapidly expanding field of oncological research. [ABSTRACT FROM AUTHOR]

Published

2023

25. Hepatotoxic assessment in a microphysiological system: Simulation of the drug absorption and toxic process after an overdosed acetaminophen on intestinal-liver-on-chip.

Author

Yu, Yue, Sun, Baiyang, Ye, Xiao, Wang, Yupeng, Zhao, Manman, Song, Jie, Geng, Xingchao, Marx, Uwe, Li, Bo, and Zhou, Xiaobing

Subjects

*MICROPHYSIOLOGICAL systems, *POISONS, *KUPFFER cells, *DRUG absorption, *HIGH performance liquid chromatography, *ASPARTATE aminotransferase

Abstract

To compensate the limitation of animal models, new models were proposed for drug safety evaluation to refine and reduce existing models. To mimic drug absorption and metabolism and predict toxicokinetic and toxic effects in an in vitro intestinal-liver microphysiological system (MPS), we constructed an intestinal-liver-on-chip and detected the acute liver injury process after an overdose of acetaminophen (APAP). Caco-2 and HT29-MTX-E12 cell lines were utilized to establish intestinal equivalents, along with HepG2, HUVEC-T1, and THP-1 induced by PMA and human hepatic stellate cell to establish liver equivalents. The APAP concentration was determined using high-performance liquid chromatography, and the toxicokinetic parameters were fitted using the non-compartmental analysis method by Phoenix. Changes in liver injury biomarkers aspartate aminotransferase and alanine aminotransferase, and liver function marker albumin indicated that the short-term culture of the two organs-on-chip model was stable for 4 days. Reactive oxygen species signaling was enhanced after APAP administration, along with decreased mitochondrial membrane potential, activated caspase-3, and enhanced p53 signaling, indicating a toxic response induced by APAP overdose. In the gut-liver MPS model, we fitted the toxicokinetic parameters and simulated the hepatotoxicity procedure following an APAP overdose, which will facilitate the organ-on-chips application in drug toxicity assays. An illustration of the gut-liver microphysiological system and a proof-of-concept for drug absorption and subsequent hepatotoxic examination with acetaminophen as a prototypical model compound. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

26. Conversation before crossing: dissecting metastatic tumor-vascular interactions in microphysiological systems.

Author

Mayo, Lakyn N. and Kutys, Matthew L.

Subjects

*METASTASIS, *CANCER invasiveness, *CELL morphology, *ENDOTHELIAL cells, *EXTRAVASATION, *CHATBOTS, *MICROPHYSIOLOGICAL systems

Abstract

Tumor metastasis via the circulation requires crossing the vascular barrier twice: first, during intravasation when tumor cells disseminate from the primary site through proximal vasculature, and second, during extravasation, when tumor cells exit the circulation to form distant metastatic seeds. During these key metastatic events, chemomechanical signaling between tumor cells and endothelial cells elicits reciprocal changes in cell morphology and behavior that are necessary to breach the vessel wall. Existing experimental systems have provided a limited understanding of the diverse mechanisms underlying tumor-endothelial interactions during intravasation and extravasation. Recent advances in microphysiological systems have revolutionized the ability to generate miniaturized human tissues with tailored three-dimensional architectures, physiological cell interfaces, and precise chemical and physical microenvironments. By doing so, microphysiological systems enable experimental access to complex morphogenic processes associated with human tumor progression with unprecedented resolution and biological control. Here, we discuss recent examples in which microphysiological systems have been leveraged to reveal new mechanistic insight into cellular and molecular control systems operating at the tumor-endothelial interface during intravasation and extravasation. [ABSTRACT FROM AUTHOR]

Published

2022

27. An in vitro-in silico workflow for predicting renal clearance of PFAS.

Author

Lin, Hsing-Chieh, Sakolish, Courtney, Moyer, Haley L., Carmichael, Paul L., Baltazar, Maria T., Ferguson, Stephen S., Stanko, Jason P., Hewitt, Philip, Rusyn, Ivan, and Chiu, Weihsueh A.

Subjects

*FLUOROALKYL compounds, *PROXIMAL kidney tubules, *MICROPHYSIOLOGICAL systems, *PHARMACOKINETICS, *WORKFLOW, *PERMEABILITY, *MANUFACTURING cells

Abstract

Per - and poly-fluoroalkyl substances (PFAS) have a wide range of elimination half-lives (days to years) in humans, thought to be in part due to variation in proximal tubule reabsorption. While human biomonitoring studies provide important data for some PFAS, renal clearance (CL renal) predictions for hundreds of PFAS in commerce requires experimental studies with in vitro models and physiologically-based in vitro -to- in vivo extrapolation (IVIVE). Options for studying renal proximal tubule pharmacokinetics include cultures of renal proximal tubule epithelial cells (RPTECs) and/or microphysiological systems. This study aimed to compare CL renal predictions for PFAS using in vitro models of varying complexity (96-well plates, static 24-well Transwells and a fluidic microphysiological model, all using human telomerase reverse transcriptase-immortalized and OAT1-overexpressing RPTECs combined with in silico physiologically-based IVIVE. Three PFAS were tested: one with a long half-life (PFOS) and two with shorter half-lives (PFHxA and PFBS). PFAS were added either individually (5 μM) or as a mixture (2 μM of each substance) for 48 h. Bayesian methods were used to fit concentrations measured in media and cells to a three-compartmental model to obtain the in vitro permeability rates, which were then used as inputs for a physiologically-based IVIVE model to estimate in vivo CL renal. Our predictions for human CL renal of PFAS were highly concordant with available values from in vivo human studies. The relative values of CL renal between slow- and faster-clearance PFAS were most highly concordant between predictions from 2D culture and corresponding in vivo values. However, the predictions from the more complex model (with or without flow) exhibited greater concordance with absolute CL renal. Overall, we conclude that a combined in vitro-in silico workflow can predict absolute CL renal values, and effectively distinguish between PFAS with slow and faster clearance, thereby allowing prioritization of PFAS with a greater potential for bioaccumulation in humans. • Some PFAS can bioaccumulate in humans, in part due to slow renal clearance CL renal. • We test use of 2D culture and MPS models to measure CL renal for three PFAS. • Combined with physiologically-based IVIVE, we can accurately predict CL renal. • Our in vitro-in silico workflow can prioritize PFAS that bioaccumulate in humans. [ABSTRACT FROM AUTHOR]

Published

2024

28. Chamber-specific contractile responses of atrial and ventricular hiPSC-cardiomyocytes to GPCR and ion channel targeting compounds: A microphysiological system for cardiac drug development.

Author

Lickiss, Bettina, Hunker, Jan, Bhagwan, Jamie, Linder, Peter, Thomas, Ulrich, Lotay, Hardeep, Broadbent, Steven, Dragicevic, Elena, Stoelzle-Feix, Sonja, Turner, Jan, and Gossmann, Matthias

Subjects

*MICROPHYSIOLOGICAL systems, *ARRHYTHMIA, *HEART beat, *CARDIOVASCULAR agents, *DRUG development, *ION channels, *INDUCED pluripotent stem cells

Abstract

Human induced pluripotent stem cell (hiPSC)-derived cardiomyocytes (CMs) have found utility for conducting in vitro drug screening and disease modelling to gain crucial insights into pharmacology or disease phenotype. However, diseases such as atrial fibrillation, affecting >33 M people worldwide, demonstrate the need for cardiac subtype-specific cells. Here, we sought to investigate the base characteristics and pharmacological differences between commercially available chamber-specific atrial or ventricular hiPSC-CMs seeded onto ultra-thin, flexible PDMS membranes to simultaneously measure contractility in a 96 multi-well format. We investigated the effects of GPCR agonists (acetylcholine and carbachol), a Ca2+ channel agonist (S-Bay K8644), an HCN channel antagonist (ivabradine) and K+ channel antagonists (4-AP and vernakalant). We observed differential effects between atrial and ventricular hiPSC-CMs on contractile properties including beat rate, beat duration, contractile force and evidence of arrhythmias at a range of concentrations. As an excerpt of the compound analysis, S-Bay K8644 treatment showed an induced concentration-dependent transient increase in beat duration of atrial hiPSC-CMs, whereas ventricular cells showed a physiological increase in beat rate over time. Carbachol treatment produced marked effects on atrial cells, such as increased beat duration alongside a decrease in beat rate over time, but only minimal effects on ventricular cardiomyocytes. In the context of this chamber-specific pharmacology, we not only add to contractile characterization of hiPSC-CMs but propose a multi-well platform for medium-throughput early compound screening. Overall, these insights illustrate the key pharmacological differences between chamber-specific cardiomyocytes and their application on a multi-well contractility platform to gain insights for in vitro cardiac liability studies and disease modelling. [ABSTRACT FROM AUTHOR]

Published

2024

29. Liver-on-chip model and application in predictive genotoxicity and mutagenicity of drugs.

Author

Kopp, B., Khawam, A., Di Perna, K., Lenart, D., Vinette, M., Silva, R., Zanoni, T.B., Rore, C., Guenigault, G., Richardson, E., Kostrzewski, T., Boswell, A., Van, P., Valentine III, C., Salk, J., and Hamel, A.

Subjects

*GENETIC toxicology, *GENE expression, *MICROPHYSIOLOGICAL systems, *BIOTRANSFORMATION (Metabolism), *METHYL methanesulfonate, *TEST systems

Abstract

Currently, there is no test system, whether in vitro or in vivo , capable of examining all endpoints required for genotoxicity evaluation used in pre-clinical drug safety assessment. The objective of this study was to develop a model which could assess all the required endpoints and possesses robust human metabolic activity, that could be used in a streamlined, animal-free manner. Liver-on-chip (LOC) models have intrinsic human metabolic activity that mimics the in vivo environment, making it a preferred test system. For our assay, the LOC was assembled using primary human hepatocytes or HepaRG cells, in a MPS-T12 plate, maintained under microfluidic flow conditions using the PhysioMimix® Microphysiological System (MPS), and co-cultured with human lymphoblastoid (TK6) cells in transwells. This system allows for interaction between two compartments and for the analysis of three different genotoxic endpoints, i.e. DNA strand breaks (comet assay) in hepatocytes, chromosome loss or damage (micronucleus assay) and mutation (Duplex Sequencing) in TK6 cells. Both compartments were treated at 0, 24 and 45 h with two direct genotoxicants: methyl methanesulfonate (MMS) and ethyl methanesulfonate (EMS), and two genotoxicants requiring metabolic activation: benzo[ a ]pyrene (B[ a ]P) and cyclophosphamide (CP). Assessment of cytochrome activity, RNA expression, albumin, urea and lactate dehydrogenase production, demonstrated functional metabolic capacities. Genotoxicity responses were observed for all endpoints with MMS and EMS. Increases in the micronucleus and mutations (MF) frequencies were also observed with CP, and %Tail DNA with B[ a ]P, indicating the metabolic competency of the test system. CP did not exhibit an increase in the %Tail DNA, which is in line with in vivo data. However, B[ a ]P did not exhibit an increase in the % micronucleus and MF, which might require an optimization of the test system. In conclusion, this proof-of-principle experiment suggests that LOC-MPS technology is a promising tool for in vitro hazard identification genotoxicants. • LOC built with primary hepatocytes or HepaRG and maintained under microfluidic flow. • LOC co-cultured with TK6 cells for comet and micronucleus/mutagenicity analysis. • Statistically significant increases observed for all endpoints with MMS and EMS. • Increases in the micronuclei/mutation frequency with CP and %Tail DNA with B[ a ]P. • This study suggests that LOC-MPS is a promising tool for genotoxicity assessment. [ABSTRACT FROM AUTHOR]

Published

2024

30. Organ-On-A-Chip Technologies for Advanced Blood-Retinal Barrier Models.

Author

Ragelle, Héloïse, Goncalves, Andreia, Kustermann, Stefan, Antonetti, David A., and Jayagopal, Ashwath

Subjects

*BIOCOMPLEXITY, *CELL culture, *OPHTHALMIC drugs, *DRUG development, *DRUG design, *FLOW cytometry, *BIOLOGICAL models, *RETINA, *MICROPHYSIOLOGICAL systems, *PSYCHOLOGICAL tests, *BIOCHIPS, *RESEARCH funding, *PSYCHOLOGICAL adaptation, *ANIMALS

Abstract

The blood-retinal barrier (BRB) protects the retina by maintaining an adequate microenvironment for neuronal function. Alterations of the junctional complex of the BRB and consequent BRB breakdown in disease contribute to a loss of neuronal signaling and vision loss. As new therapeutics are being developed to prevent or restore barrier function, it is critical to implement physiologically relevant in vitro models that recapitulate the important features of barrier biology to improve disease modeling, target validation, and toxicity assessment. New directions in organ-on-a-chip technology are enabling more sophisticated 3-dimensional models with flow, multicellularity, and control over microenvironmental properties. By capturing additional biological complexity, organs-on-chip can help approach actual tissue organization and function and offer additional tools to model and study disease compared with traditional 2-dimensional cell culture. This review describes the current state of barrier biology and barrier function in ocular diseases, describes recent advances in organ-on-a-chip design for modeling the BRB, and discusses the potential of such models for ophthalmic drug discovery and development. [ABSTRACT FROM AUTHOR]

Published

2020

31. Physiologically Based Pharmacokinetic and Pharmacodynamic Analysis Enabled by Microfluidically Linked Organs-on-Chips.

Author

Prantil-Baun, Rachelle, Novak, Richard, Das, Debarun, Somayaji, Mahadevabharath R., Przekwas, Andrzej, and Ingber, Donald E.

Subjects

*COMPUTER simulation, *IN vitro studies, *IN vivo studies, *ABSORPTION, *ENDOTHELIUM, *MICROFLUIDIC analytical techniques, *DRUG design, *MICROPHYSIOLOGICAL systems, *BIOTRANSFORMATION (Metabolism), *DOSAGE forms of drugs, *PERFUSION

Abstract

Physiologically based pharmacokinetic (PBPK) modeling and simulation approaches are beginning to be integrated into drug development and approval processes because they enable key pharmacokinetic (PK) parameters to be predicted from in vitro data. However, these approaches are hampered by many limitations, including an inability to incorporate organ-specific differentials in drug clearance, distribution, and absorption that result from differences in cell uptake, transport, and metabolism. Moreover, such approaches are generally unable to provide insight into pharmacodynamic (PD) parameters. Recent development of microfluidic Organ-on-a-Chip (Organ Chip) cell culture devices that recapitulate tissue-tissue interfaces, vascular perfusion, and organ-level functionality offer the ability to overcome these limitations when multiple Organ Chips are linked via their endothelium-lined vascular channels. Here, we discuss successes and challenges in the use of existing culture models and vascularized Organ Chips for PBPK and PD modeling of human drug responses, as well as in vitro to in vivo extrapolation (IVIVE) of these results, and how these approaches might advance drug development and regulatory review processes in the future. [ABSTRACT FROM AUTHOR]

Published

2018

32. Human brain microphysiological systems in the study of neuroinfectious disorders.

Author

Barreras, Paula, Pamies, David, Hartung, Thomas, and Pardo, Carlos A.

Subjects

*BIOPRINTING, *INDUCED pluripotent stem cells, *EMBRYONIC stem cells, *JAPANESE B encephalitis, *VIRUS diseases, *MICROPHYSIOLOGICAL systems

Abstract

Microphysiological systems (MPS) are 2D or 3D multicellular constructs able to mimic tissue microenvironments. The latest models encompass a range of techniques, including co-culturing of various cell types, utilization of scaffolds and extracellular matrix materials, perfusion systems, 3D culture methods, 3D bioprinting, organ-on-a-chip technology, and examination of tissue structures. Several human brain 3D cultures or brain MPS (BMPS) have emerged in the last decade. These organoids or spheroids are 3D culture systems derived from induced pluripotent cells or embryonic stem cells that contain neuronal and glial populations and recapitulate structural and physiological aspects of the human brain. BMPS have been introduced recently in the study and modeling of neuroinfectious diseases and have proven to be useful in establishing neurotropism of viral infections, cell-pathogen interactions needed for infection, assessing cytopathological effects, genomic and proteomic profiles, and screening therapeutic compounds. Here we review the different methodologies of organoids used in neuroinfectious diseases including spheroids, guided and unguided protocols as well as microglia and blood-brain barrier containing models, their specific applications, and limitations. The review provides an overview of the models existing for specific infections including Zika, Dengue, JC virus, Japanese encephalitis, measles, herpes, SARS-CoV2, and influenza viruses among others, and provide useful concepts in the modeling of disease and antiviral agent screening. [ABSTRACT FROM AUTHOR]

Published

2023