Your search keyword '"Rasponi M"' showing total 946 results

101. Bioprinting 3D microfibrous scaffolds for engineering endothelialized myocardium and heart-on-a-chip.

Author

Zhang YS, Arneri A, Bersini S, Shin SR, Zhu K, Goli-Malekabadi Z, Aleman J, Colosi C, Busignani F, Dell'Erba V, Bishop C, Shupe T, Demarchi D, Moretti M, Rasponi M, Dokmeci MR, Atala A, and Khademhosseini A

Subjects

Drug Evaluation, Preclinical, Humans, Hydrogels chemistry, Microfibrils chemistry, Myocytes, Cardiac chemistry, Myocytes, Cardiac metabolism, Organoids chemistry, Organoids metabolism, Regenerative Medicine, Bioprinting methods, Endothelial Cells chemistry, Endothelial Cells cytology, Myocardium, Organoids growth & development, Printing, Three-Dimensional, Tissue Engineering methods, Tissue Scaffolds chemistry

Abstract

Engineering cardiac tissues and organ models remains a great challenge due to the hierarchical structure of the native myocardium. The need of integrating blood vessels brings additional complexity, limiting the available approaches that are suitable to produce integrated cardiovascular organoids. In this work we propose a novel hybrid strategy based on 3D bioprinting, to fabricate endothelialized myocardium. Enabled by the use of our composite bioink, endothelial cells directly bioprinted within microfibrous hydrogel scaffolds gradually migrated towards the peripheries of the microfibers to form a layer of confluent endothelium. Together with controlled anisotropy, this 3D endothelial bed was then seeded with cardiomyocytes to generate aligned myocardium capable of spontaneous and synchronous contraction. We further embedded the organoids into a specially designed microfluidic perfusion bioreactor to complete the endothelialized-myocardium-on-a-chip platform for cardiovascular toxicity evaluation. Finally, we demonstrated that such a technique could be translated to human cardiomyocytes derived from induced pluripotent stem cells to construct endothelialized human myocardium. We believe that our method for generation of endothelialized organoids fabricated through an innovative 3D bioprinting technology may find widespread applications in regenerative medicine, drug screening, and potentially disease modeling., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2016

102. Cardiac Meets Skeletal: What's New in Microfluidic Models for Muscle Tissue Engineering.

Author

Visone R, Gilardi M, Marsano A, Rasponi M, Bersini S, and Moretti M

Subjects

Animals, Humans, Muscle, Skeletal cytology, Myocardium cytology, Lab-On-A-Chip Devices, Models, Biological, Muscle, Skeletal metabolism, Myocardium metabolism, Tissue Engineering methods

Abstract

In the last few years microfluidics and microfabrication technique principles have been extensively exploited for biomedical applications. In this framework, organs-on-a-chip represent promising tools to reproduce key features of functional tissue units within microscale culture chambers. These systems offer the possibility to investigate the effects of biochemical, mechanical, and electrical stimulations, which are usually applied to enhance the functionality of the engineered tissues. Since the functionality of muscle tissues relies on the 3D organization and on the perfect coupling between electrochemical stimulation and mechanical contraction, great efforts have been devoted to generate biomimetic skeletal and cardiac systems to allow high-throughput pathophysiological studies and drug screening. This review critically analyzes microfluidic platforms that were designed for skeletal and cardiac muscle tissue engineering. Our aim is to highlight which specific features of the engineered systems promoted a typical reorganization of the engineered construct and to discuss how promising design solutions exploited for skeletal muscle models could be applied to improve cardiac tissue models and vice versa.

Published

2016

103. Microfluidic approaches for the assessment of blood cell trauma: a focus on thrombotic risk in mechanical circulatory support devices.

Author

Consolo F, Dimasi A, Rasponi M, Valerio L, Pappalardo F, Bluestein D, Slepian MJ, Fiore GB, and Redaelli A

Subjects

Blood Coagulation, Blood Coagulation Tests, Blood Platelets drug effects, Hemostasis, Humans, Microfluidics, Point-of-Care Systems, Stress, Mechanical, Thrombosis prevention & control, Heart-Assist Devices adverse effects, Platelet Activation physiology, Thrombosis etiology

Abstract

Introduction: Mechanical circulatory support devices (MCSDs) are emerging as a valuable therapeutic option for the management of end-stage heart failure. However, although recipients are routinely administered with anti-thrombotic (AT) drugs, thrombosis persists as a severe post-implant complication. Conventional clinical assays and coagulation markers demonstrate partial ability in preventing the onset of thrombosis. Through years, different laboratory techniques have been proposed as potential tools for the evaluation of platelets' hemostatic response in MCSD recipients. Most rely on platelet aggregation tests; they are performed in static or low shear conditions, neglecting the prominent contribution of MCSD shear-induced mechanical load in enhancing platelet activation (PA). On the other hand, those tests able to account for shear-induced PA have limited possibility of effective clinical translation., Aims and Methods: Advances on this side have been addressed by microfluidic technology. Microfluidic devices have been developed for AT drug monitoring under flow, able to replicate physiological and/or constant shear flow conditions in vitro. In this paper, we present a newly developed microfluidic platform able to expose platelets to MCSD-specific dynamic shear stress patterns. We performed in vitro tests circulating human platelets in the microfluidic platform and quantifying the dynamics of PA by means of the Platelet Activity State (PAS) assay., Results: Our results prove the feasibility of using microfluidics for the diagnosis of MCSD-related thrombotic risk. This study paves the way for the development of a miniaturized point-of-care device for monitoring AT drug regimen. Such a system may have significant impact on limiting the incidence of thrombosis in MCSD recipients.

Published

2016

104. On-chip assessment of human primary cardiac fibroblasts proliferative responses to uniaxial cyclic mechanical strain.

Author

Ugolini GS, Rasponi M, Pavesi A, Santoro R, Kamm R, Fiore GB, Pesce M, and Soncini M

Subjects

Biomarkers analysis, Cell Culture Techniques instrumentation, Cells, Cultured, Cytological Techniques instrumentation, Cytological Techniques methods, Fibroblasts cytology, Humans, Cell Culture Techniques methods, Cell Proliferation, Fibroblasts physiology, Mechanotransduction, Cellular, Stress, Mechanical

Abstract

Cardiac cell function is substantially influenced by the nature and intensity of the mechanical loads the cells experience. Cardiac fibroblasts (CFs) are primarily involved in myocardial tissue remodeling: at the onset of specific pathological conditions, CFs activate, proliferate, differentiate, and critically alter the amount of myocardial extra-cellular matrix with important consequences for myocardial functioning. While cyclic mechanical strain has been shown to increase matrix synthesis of CFs in vitro, the role of mechanical cues in CFs proliferation is unclear. We here developed a multi-chamber cell straining microdevice for cell cultures under uniform, uniaxial cyclic strain. After careful characterization of the strain field, we extracted human heart-derived CFs and performed cyclic strain experiments. We subjected cells to 2% or 8% cyclic strain for 24 h or 72 h, using immunofluorescence to investigate markers of cell morphology, cell proliferation (Ki67, EdU, phospho-Histone-H3) and subcellular localization of the mechanotransduction-associated transcription factor YAP. Cell morphology was affected by cyclic strain in terms of cell area, cell and nuclear shape and cellular alignment. We additionally observed a strain intensity-dependent control of cell growth: a significant proliferation increase occurred at 2% cyclic strain, while time-dependent effects took place upon 8% cyclic strain. The YAP-dependent mechano-transduction pathway was similarly activated in both strain conditions. These results demonstrate a differential effect of cyclic strain intensity on human CFs proliferation control and provide insights into the YAP-dependent mechano-sensing machinery of human CFs., (© 2015 Wiley Periodicals, Inc.)

Published

2016

105. Beating heart on a chip: a novel microfluidic platform to generate functional 3D cardiac microtissues.

Author

Marsano A, Conficconi C, Lemme M, Occhetta P, Gaudiello E, Votta E, Cerino G, Redaelli A, and Rasponi M

Subjects

Animals, Humans, Rats, Rats, Sprague-Dawley, Induced Pluripotent Stem Cells cytology, Induced Pluripotent Stem Cells metabolism, Microfluidic Analytical Techniques instrumentation, Microfluidic Analytical Techniques methods, Myocardial Contraction, Myocytes, Cardiac cytology, Myocytes, Cardiac metabolism, Tissue Culture Techniques instrumentation, Tissue Culture Techniques methods

Abstract

In the past few years, microfluidic-based technology has developed microscale models recapitulating key physical and biological cues typical of the native myocardium. However, the application of controlled physiological uniaxial cyclic strains on a defined three-dimension cellular environment is not yet possible. Two-dimension mechanical stimulation was particularly investigated, neglecting the complex three-dimensional cell-cell and cell-matrix interactions. For this purpose, we developed a heart-on-a-chip platform, which recapitulates the physiologic mechanical environment experienced by cells in the native myocardium. The device includes an array of hanging posts to confine cell-laden gels, and a pneumatic actuation system to induce homogeneous uniaxial cyclic strains to the 3D cell constructs during culture. The device was used to generate mature and highly functional micro-engineered cardiac tissues (μECTs), from both neonatal rat and human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CM), strongly suggesting the robustness of our engineered cardiac micro-niche. Our results demonstrated that the cyclic strain was effectively highly uniaxial and uniformly transferred to cells in culture. As compared to control, stimulated μECTs showed superior cardiac differentiation, as well as electrical and mechanical coupling, owing to a remarkable increase in junction complexes. Mechanical stimulation also promoted early spontaneous synchronous beating and better contractile capability in response to electric pacing. Pacing analyses of hiPSC-CM constructs upon controlled administration of isoprenaline showed further promising applications of our platform in drug discovery, delivery and toxicology fields. The proposed heart-on-a-chip device represents a relevant step forward in the field, providing a standard functional three-dimensional cardiac model to possibly predict signs of hypertrophic changes in cardiac phenotype by mechanical and biochemical co-stimulation.

Published

2016

106. Design of a microfluidic strategy for trapping and screening single cells.

Author

Occhetta P, Licini M, Redaelli A, and Rasponi M

Subjects

Cell Culture Techniques, Dimethylpolysiloxanes, Equipment Design, HeLa Cells, Humans, Cell Separation instrumentation, Lab-On-A-Chip Devices, Single-Cell Analysis instrumentation

Abstract

Traditionally, in vitro investigations on biology and physiology of cells rely on averaging the responses eliciting from heterogeneous cell populations, thus being unsuitable for assessing individual cell behaviors in response to external stimulations. In the last years, great interest has thus been focused on single cell analysis and screening, which represents a promising tool aiming at pursuing the direct and deterministic control over cause-effect relationships guiding cell behavior. In this regard, a high-throughput microfluidic platform for trapping and culturing adherent single cells was presented. A single cell trapping mechanism was implemented based on dynamic variation of fluidic resistances. A round-shaped culture chamber (Φ = 250 µm, h = 25 µm) was conceived presenting two connections with a main fluidic path: (i) an upper wide opening, and (ii) a bottom trapping junction which modulates the hydraulic resistance. Starting from eight different layouts, the chamber geometry was computationally optimized for maximizing the single cell trapping efficacy and then integrated in a polydimethylsiloxane (PDMS) microfluidic device. The final platform consists in (i) 288 chambers for trapping single cells organized in six culture units, independently addressable through the lines of (ii) a chaotic-mixer based serial dilution generator (SDG), designed for creating spatio-temporally controlled patterns of both soluble factors and non-diffusive particles. The device was experimentally validated by trapping polystyrene microspheres, featuring diameters comparable to cell size (Φ = 10 µm)., (Copyright © 2015 IPEM. Published by Elsevier Ltd. All rights reserved.)

Published

2016

107. Young at Heart: Pioneering Approaches to Model Nonischaemic Cardiomyopathy with Induced Pluripotent Stem Cells.

Author

Gowran A, Rasponi M, Visone R, Nigro P, Perrucci GL, Righetti S, Zanobini M, and Pompilio G

Abstract

A mere 9 years have passed since the revolutionary report describing the derivation of induced pluripotent stem cells from human fibroblasts and the first in-patient translational use of cells obtained from these stem cells has already been achieved. From the perspectives of clinicians and researchers alike, the promise of induced pluripotent stem cells is alluring if somewhat beguiling. It is now evident that this technology is nascent and many areas for refinement have been identified and need to be considered before induced pluripotent stem cells can be routinely used to stratify, treat and cure patients, and to faithfully model diseases for drug screening purposes. This review specifically addresses the pioneering approaches to improve induced pluripotent stem cell based models of nonischaemic cardiomyopathy.

Published

2016

108. Construction, Features and Regulatory Aspects of Organ-chip for Drug Delivery Applications: Advances and Prospective.

Author

Gupta B, Malviya R, Srivastava S, Ahmad I, Rab SO, and Uniyal P

Subjects

Humans, Tissue Engineering, Animals, Drug Delivery Systems, Lab-On-A-Chip Devices

Abstract

Organ-on-chip is an innovative technique that emerged from tissue engineering and microfluidic technologies. Organ-on-chip devices (OoCs) are anticipated to provide efficient explanations for dealing with challenges in pharmaceutical advancement and individualized illness therapies. Organ-on-chip is an advanced method that can replicate human organs' physiological conditions and functions on a small chip. It possesses the capacity to greatly transform the drug development process by enabling the simulation of diseases and the testing of drugs. Effective integration of this advanced technical platform with common pharmaceutical and medical contexts is still a challenge. Microfluidic technology, a micro-level technique, has become a potent tool for biomedical engineering research. As a result, it has revolutionized disciplines, including physiological material interpreting, compound detection, cell-based assay, tissue engineering, biological diagnostics, and pharmaceutical identification. This article aims to offer an overview of newly developed organ-on-a-chip systems. It includes single-organ platforms, emphasizing the most researched organs, including the heart, liver, blood arteries, and lungs. Subsequently, it provides a concise overview of tumor-on-a-chip systems and emphasizes their use in evaluating anti-cancer medications., (Copyright© Bentham Science Publishers; For any queries, please email at epub@benthamscience.net.)

Published

2024

109. Recent advances in pluripotent stem cell-derived cardiac organoids and heart-on-chip applications for studying anti-cancer drug-induced cardiotoxicity.

Author

Liu S, Fang C, Zhong C, Li J, and Xiao Q

Subjects

Humans, Cardiotoxicity etiology, Myocytes, Cardiac, Drug Evaluation, Preclinical, Organoids, Cardiovascular Diseases, Induced Pluripotent Stem Cells, Antineoplastic Agents adverse effects, Neoplasms drug therapy

Abstract

Cardiovascular disease (CVD) caused by anti-cancer drug-induced cardiotoxicity is now the second leading cause of mortality among cancer survivors. It is necessary to establish efficient in vitro models for early predicting the potential cardiotoxicity of anti-cancer drugs, as well as for screening drugs that would alleviate cardiotoxicity during and post treatment. Human induced pluripotent stem cells (hiPSCs) have opened up new avenues in cardio-oncology. With the breakthrough of tissue engineering technology, a variety of hiPSC-derived cardiac microtissues or organoids have been recently reported, which have shown enormous potential in studying cardiotoxicity. Moreover, using hiPSC-derived heart-on-chip for studying cardiotoxicity has provided novel insights into the underlying mechanisms. Herein, we summarize different types of anti-cancer drug-induced cardiotoxicities and present an extensive overview on the applications of hiPSC-derived cardiac microtissues, cardiac organoids, and heart-on-chips in cardiotoxicity. Finally, we highlight clinical and translational challenges around hiPSC-derived cardiac microtissues/organoids/heart-on chips and their applications in anti-cancer drug-induced cardiotoxicity. • Anti-cancer drug-induced cardiotoxicities represent pressing challenges for cancer treatments, and cardiovascular disease is the second leading cause of mortality among cancer survivors. • Newly reported in vitro models such as hiPSC-derived cardiac microtissues/organoids/chips show enormous potential for studying cardio-oncology. • Emerging evidence supports that hiPSC-derived cardiac organoids and heart-on-chip are promising in vitro platforms for predicting and minimizing anti-cancer drug-induced cardiotoxicity., (© 2023. The Author(s), under exclusive licence to Springer Nature B.V.)

Published

2023

110. Short-term effects of microstructured surfaces: role in cell differentiation toward a contractile phenotype.

Author

Boccafoschi F, Rasponi M, Ramella M, Ferreira AM, Vesentini S, and Cannas M

Subjects

Animals, Cell Adhesion physiology, Cell Line, Mice, Muscle Proteins metabolism, Myoblasts metabolism, Myoblasts physiology, Surface Properties, Cell Culture Techniques instrumentation, Cell Differentiation physiology, Myoblasts cytology, Tissue Engineering

Abstract

Cell adhesion plays a key role in cell behavior, in terms of migration, proliferation, differentiation and apoptosis. All of these events concur with tissue regeneration and remodeling mechanisms, integrating a complex network of intracellular signaling modules. Morphogenetic responses, which involve changes in cell shape, proliferation and differentiation, are thought to be controlled by both biochemical and biophysical cues. Indeed, the extracellular matrix not only displays adhesive ligands necessary for cell adhesion but also plays an essential biomechanical role - responsible, for instance, for the acquisition of the contractile phenotype. The substrate topography around the forming tissues and the associated mechanical stresses that are generated regulate cellular morphology, proliferation and differentiation. Thus, the ability to tailor topographical features around cells can be a crucial design parameter in tissue engineering applications, inducing cells to exhibit the required performances.In this work, we designed micropillared substrates using highly spaced arrays (interspacing equal to 25 µm) to evaluate the effects of topography on C2C12 myoblasts' adhesion and differentiation. Optical and fluorescence microscopy images were used to observe cell adhesion, together with Western blot analysis on vinculin and focal adhesion kinase (FAK) expression, a protein highly involved in adhesive processes. Differentiation marker (Myf5, myogenin and myosin heavy chain [MHC]) expression was also studied, in relation to the effect of different substrate topographies on the enhancement of a contractile phenotype. Our results demonstrated that microstructured surfaces may play a key role in the regeneration of functional tissues.

Published

2015

111. Controlled electromechanical cell stimulation on-a-chip.

Author

Pavesi A, Adriani G, Rasponi M, Zervantonakis IK, Fiore GB, and Kamm RD

Subjects

Bone Marrow Cells cytology, Bone Marrow Cells metabolism, Electric Stimulation, Gene Expression, Humans, Mesenchymal Stem Cells metabolism, Stress, Mechanical, Cell Differentiation, Mesenchymal Stem Cells cytology, Regenerative Medicine

Abstract

Stem cell research has yielded promising advances in regenerative medicine, but standard assays generally lack the ability to combine different cell stimulations with rapid sample processing and precise fluid control. In this work, we describe the design and fabrication of a micro-scale cell stimulator capable of simultaneously providing mechanical, electrical, and biochemical stimulation, and subsequently extracting detailed morphological and gene-expression analysis on the cellular response. This micro-device offers the opportunity to overcome previous limitations and recreate critical elements of the in vivo microenvironment in order to investigate cellular responses to three different stimulations. The platform was validated in experiments using human bone marrow mesenchymal stem cells. These experiments demonstrated the ability for inducing changes in cell morphology, cytoskeletal fiber orientation and changes in gene expression under physiological stimuli. This novel bioengineering approach can be readily applied to various studies, especially in the fields of stem cell biology and regenerative medicine.

Published

2015

112. Fabrication of multi-well chips for spheroid cultures and implantable constructs through rapid prototyping techniques.

Author

Lopa S, Piraino F, Kemp RJ, Di Caro C, Lovati AB, Di Giancamillo A, Moroni L, Peretti GM, Rasponi M, and Moretti M

Subjects

Cell Count, Cells, Cultured, Gene Expression Profiling, Humans, Time Factors, Cell Culture Techniques instrumentation, Cell Culture Techniques methods, Chondrocytes physiology

Abstract

Three-dimensional (3D) culture models are widely used in basic and translational research. In this study, to generate and culture multiple 3D cell spheroids, we exploited laser ablation and replica molding for the fabrication of polydimethylsiloxane (PDMS) multi-well chips, which were validated using articular chondrocytes (ACs). Multi-well ACs spheroids were comparable or superior to standard spheroids, as revealed by glycosaminoglycan and type-II collagen deposition. Moreover, the use of our multi-well chips significantly reduced the operation time for cell seeding and medium refresh. Exploiting a similar approach, we used clinical-grade fibrin to generate implantable multi-well constructs allowing for the precise distribution of multiple cell types. Multi-well fibrin constructs were seeded with ACs generating high cell density regions, as shown by histology and cell fluorescent staining. Multi-well constructs were compared to standard constructs with homogeneously distributed ACs. After 7 days in vitro, expression of SOX9, ACAN, COL2A1, and COMP was increased in both constructs, with multi-well constructs expressing significantly higher levels of chondrogenic genes than standard constructs. After 5 weeks in vivo, we found that despite a dramatic size reduction, the cell distribution pattern was maintained and glycosaminoglycan content per wet weight was significantly increased respect to pre-implantation samples. In conclusion, multi-well chips for the generation and culture of multiple cell spheroids can be fabricated by low-cost rapid prototyping techniques. Furthermore, these techniques can be used to generate implantable constructs with defined architecture and controlled cell distribution, allowing for in vitro and in vivo investigation of cell interactions in a 3D environment., (© 2015 Wiley Periodicals, Inc.)

Published

2015

113. VA-086 methacrylate gelatine photopolymerizable hydrogels: A parametric study for highly biocompatible 3D cell embedding.

Author

Occhetta P, Visone R, Russo L, Cipolla L, Moretti M, and Rasponi M

Subjects

Animals, Coculture Techniques, Cross-Linking Reagents pharmacology, Elastic Modulus drug effects, Green Fluorescent Proteins metabolism, Human Umbilical Vein Endothelial Cells cytology, Human Umbilical Vein Endothelial Cells drug effects, Humans, Mesenchymal Stem Cells cytology, Sus scrofa, Acetamides pharmacology, Azo Compounds pharmacology, Biocompatible Materials pharmacology, Cell Culture Techniques methods, Gelatin pharmacology, Hydrogels pharmacology, Light, Methacrylates pharmacology, Polymerization

Abstract

The ability to replicate in vitro the native extracellular matrix (ECM) features and to control the three-dimensional (3D) cell organization plays a fundamental role in obtaining functional engineered bioconstructs. In tissue engineering (TE) applications, hydrogels have been successfully implied as biomatrices for 3D cell embedding, exhibiting high similarities to the natural ECM and holding easily tunable mechanical properties. In the present study, we characterized a promising photocrosslinking process to generate cell-laden methacrylate gelatin (GelMA) hydrogels in the presence of VA-086 photoinitiator using a ultraviolet LED source. We investigated the influence of prepolymer concentration and light irradiance on mechanical and biomimetic properties of resulting hydrogels. In details, the increasing of gelatin concentration resulted in enhanced rheological properties and shorter polymerization time. We then defined and validated a reliable photopolymerization protocol for cell embedding (1.5% VA-086, LED 2 mW/cm2) within GelMA hydrogels, which demonstrated to support bone marrow stromal cells viability when cultured up to 7 days. Moreover, we showed how different mechanical properties, derived from different crosslinking parameters, strongly influence cell behavior. In conclusion, this protocol can be considered a versatile tool to obtain biocompatible cell-laden hydrogels with properties easily adaptable for different TE applications., (© 2014 Wiley Periodicals, Inc.)

Published

2015

114. High-Throughput Microfluidic Platform for 3D Cultures of Mesenchymal Stem Cells, Towards Engineering Developmental Processes.

Author

Occhetta P, Centola M, Tonnarelli B, Redaelli A, Martin I, and Rasponi M

Subjects

Cell Differentiation drug effects, Cell Proliferation drug effects, Cells, Cultured, Collagen Type II metabolism, Fibroblast Growth Factor 2 pharmacology, Humans, Mesenchymal Stem Cells drug effects, Microfluidics instrumentation, Transforming Growth Factor beta3 pharmacology, Wnt3A Protein pharmacology, Cell Culture Techniques, Mesenchymal Stem Cells cytology, Microfluidics methods, Tissue Engineering instrumentation, Tissue Engineering methods

Abstract

The development of in vitro models to screen the effect of different concentrations, combinations and temporal sequences of morpho-regulatory factors on stem/progenitor cells is crucial to investigate and possibly recapitulate developmental processes with adult cells. Here, we designed and validated a microfluidic platform to (i) allow cellular condensation, (ii) culture 3D micromasses of human bone marrow-derived mesenchymal stromal cells (hBM-MSCs) under continuous flow perfusion, and (ii) deliver defined concentrations of morphogens to specific culture units. Condensation of hBM-MSCs was obtained within 3 hours, generating micromasses in uniform sizes (56.2 ± 3.9 μm). As compared to traditional macromass pellet cultures, exposure to morphogens involved in the first phases of embryonic limb development (i.e. Wnt and FGF pathways) yielded more uniform cell response throughout the 3D structures of perfused micromasses (PMMs), and a 34-fold higher percentage of proliferating cells at day 7. The use of a logarithmic serial dilution generator allowed to identify an unexpected concentration of TGFβ3 (0.1 ng/ml) permissive to hBM-MSCs proliferation and inductive to chondrogenesis. This proof-of-principle study supports the described microfluidic system as a tool to investigate processes involved in mesenchymal progenitor cells differentiation, towards a 'developmental engineering' approach for skeletal tissue regeneration.

Published

2015

115. Comparative analysis of 3D-printed and freeze-dried biodegradable gelatin methacrylate/ poly‐ε‐caprolactone- polyethylene glycol-poly‐ε‐caprolactone (GelMA/PCL-PEG-PCL) hydrogels for bone applications.

Author

Khoeini, Roghayeh, Roshangar, Leila, Aghazadeh, Marziyeh, Soltani, Saeideh, Soltani, Somaieh, Danafar, Hossein, Hosseinpour, Rasoul, and Davaran, Soodabeh

Abstract

Gelatin methacrylate (GelMA) is a photo-cross-linkable biopolymer. A combination of GelMA with biodegradable polyesters such as PCL (poly‐ε‐caprolactone) and their triblock derivatives improve the mechanical properties of GelMA. PCL-PEG-PCL (PCEC) was synthesized using ring-opening polymerization of ε-caprolactone in the presence of polyethylene glycol (PEG). The GelMA- PCEC was fabricated using freeze-drying and 3D printing and their porosity, mechanical properties, and swelling behavior were investigated. Human dental pulp stem cells were cultured on the scaffolds for a period of 14 days and cell adhesion was evaluated by scanning electron microscopy. Cell viability was analyzed by MTT and osteogenic differentiation was evaluated by Alizarin red S. Results showed that the 3D-printed scaffold had higher water absorption rate, retaining its structure up to a strain of 0.2 %, and a higher Young's modulus compared to the freeze-dried scaffold. In terms of cell viability, the 3D-printed scaffold outperformed the freeze-dried scaffold with a percentage of 86 % and 63 % viability respectively. Moreover, the 3D-printed scaffold exhibited better osteodifferentiation with calcium deposition. Overall, these findings suggest that the 3D-printed scaffold may have advantages over the freeze-dried scaffold in tissue engineering applications that require high water absorption, elasticity, and cell viability. The fabricated scaffolds provided suitable cell proliferation. [ABSTRACT FROM AUTHOR]

Published

2024

116. Improving tumor microenvironment assessment in chip systems through next-generation technology integration.

Author

Gaebler, Daniela, Hachey, Stephanie J., and Hughes, Christopher C. W.

Published

2024

117. Tumor-on-chip platforms for breast cancer continuum concept modeling.

Author

Neagu, Anca-Narcisa, Whitham, Danielle, Bruno, Pathea, Versaci, Nicholas, Biggers, Peter, and Darie, Costel C.

Published

2024

118. Resting natural killer cells promote the progress of colon cancer liver metastasis by elevating tumor- derived stem cell factor.

Author

Chenchen Mao, Yanyu Chen, Dong Xing, Teming Zhang, Yangxuan Lin, Cong Long, Jiaye Yu, Yunhui Luo, Tao Ming, Wangkai Xie, Zheng Han, Dianfeng Mei, Dan Xiang, Mingdong Lu, Xian Shen, and Xiangyang Xue

Published

2024

119. Combining human liver ECM with topographically featured electrospun scaffolds for engineering hepatic microenvironment.

Author

Gao, Yunxi, Gadd, Victoria L., Heim, Maria, Grant, Rhiannon, Bate, Thomas S. R., Esser, Hannah, Gonzalez, Sofia Ferreira, Man, Tak Yung, Forbes, Stuart J., and Callanan, Anthony

Subjects

EXTRACELLULAR matrix, CELL growth, TISSUE engineering, LIVER cells, MATERIAL culture

Abstract

Liver disease cases are rapidly expanding worldwide, and transplantation remains the only effective cure for end-stage disease. There is an increasing demand for developing potential drug treatments, and regenerative therapies using in-vitro culture platforms. Human decellularized extracellular matrix (dECM) is an appealing alternative to conventional animal tissues as it contains human-specific proteins and can serve as scaffolding materials. Herein we exploit this with human donor tissue from discarded liver which was not suitable for transplant using a synergistic approach to combining biological and topographical cues in electrospun materials as an in-vitro culture platform. To realise this, we developed a methodology for incorporating human liver dECM into electrospun polycaprolactone (PCL) fibres with surface nanotopographies (230–580 nm). The hybrid scaffolds were fabricated using varying concentrations of dECM; their morphology, mechanical properties, hydrophilicity and stability were analysed. The scaffolds were validated using HepG2 and primary mouse hepatocytes, with subsequent results indicating that the modified scaffolds-maintained cell growth and influenced cell attachment, proliferation and hepatic-related gene expression. This work demonstrates a novel approach to harvesting the potential from decellularized human tissues in the form of innovative in-vitro culture platforms for liver. [ABSTRACT FROM AUTHOR]

Published

2024

120. Advancements in Microfluidic Platforms for Glioblastoma Research.

Author

Raman, Rachana, Prabhu, Vijendra, Kumar, Praveen, and Mani, Naresh Kumar

Subjects

CANCER stem cells, DRUG delivery systems, SYSTEMS on a chip, BRAIN tumors, TUMOR microenvironment, PROGRESSION-free survival

Abstract

Glioblastoma (GBM) is a malignant cancer affecting the brain. As per the WHO classifications, it is a grade IV glioma and is characterized by heterogenous histopathology, high recurrence rates, and a high median age of diagnosis. Most individuals diagnosed with GBM are aged between 50 and 64 years, and the prognosis is often poor. Untreated GBM patients have a median survival of 3 months, while treatments with Temozolomide (TMZ) and radiotherapy can improve the survival to 10–14 months. Tumor recurrence is common, owing to the inefficiency of surgical resection in removing microscopic tumor formations in the brain. A crucial component of GBM-related research is understanding the tumor microenvironment (TME) and its characteristics. The various cellular interactions in the TME contribute to the higher occurrence of malignancy, resistance to treatments, and difficulty in tumor resection and preventative care. Incomplete pictures of the TME have been obtained in 2D cultures, which fail to incorporate the ECM and other crucial components. Identifying the hallmarks of the TME and developing ex vivo and in vitro models can help study patient-specific symptoms, assess challenges, and develop courses of treatment in a timely manner which is more efficient than the current methods. Microfluidic models, which incorporate 3D cultures and co-culture models with various channel patterns, are capable of stimulating tumor conditions accurately and provide better responses to therapeutics as would be seen in the patient. This facilitates a more refined understanding of the potential treatment delivery systems, resistance mechanisms, and metastatic pathways. This review collates information on the application of such microfluidics-based systems to analyze the GBM TME and highlights the use of such systems in improving patient care and treatment options. [ABSTRACT FROM AUTHOR]

Published

2024

121. Bridging the Gap: Advances and Challenges in Heart Regeneration from In Vitro to In Vivo Applications.

Author

Watanabe, Tatsuya, Hatayama, Naoyuki, Guo, Marissa, Yuhara, Satoshi, and Shinoka, Toshiharu

Subjects

CARDIAC regeneration, CORONARY disease, MYOCARDIAL ischemia, STEM cell treatment, MYOCARDIAL infarction, VENTRICULAR remodeling

Abstract

Cardiovascular diseases, particularly ischemic heart disease, area leading cause of morbidity and mortality worldwide. Myocardial infarction (MI) results in extensive cardiomyocyte loss, inflammation, extracellular matrix (ECM) degradation, fibrosis, and ultimately, adverse ventricular remodeling associated with impaired heart function. While heart transplantation is the only definitive treatment for end-stage heart failure, donor organ scarcity necessitates the development of alternative therapies. In such cases, methods to promote endogenous tissue regeneration by stimulating growth factor secretion and vascular formation alone are insufficient. Techniques for the creation and transplantation of viable tissues are therefore highly sought after. Approaches to cardiac regeneration range from stem cell injections to epicardial patches and interposition grafts. While numerous preclinical trials have demonstrated the positive effects of tissue transplantation on vasculogenesis and functional recovery, long-term graft survival in large animal models is rare. Adequate vascularization is essential for the survival of transplanted tissues, yet pre-formed microvasculature often fails to achieve sufficient engraftment. Recent studies report success in enhancing cell survival rates in vitro via tissue perfusion. However, the transition of these techniques to in vivo models remains challenging, especially in large animals. This review aims to highlight the evolution of cardiac patch and stem cell therapies for the treatment of cardiovascular disease, identify discrepancies between in vitro and in vivo studies, and discuss critical factors for establishing effective myocardial tissue regeneration in vivo. [ABSTRACT FROM AUTHOR]

Published

2024

122. Beyond Cancer Cells: How the Tumor Microenvironment Drives Cancer Progression.

Author

Sabit, Hussein, Arneth, Borros, Abdel-Ghany, Shaimaa, Madyan, Engy F., Ghaleb, Ashraf H., Selvaraj, Periasamy, Shin, Dong M., Bommireddy, Ramireddy, and Elhashash, Ahmed

Subjects

VASCULAR endothelial cells, EXTRACELLULAR matrix, TUMOR microenvironment, CANCER cells, CELL anatomy

Abstract

Liver cancer represents a substantial global health challenge, contributing significantly to worldwide morbidity and mortality. It has long been understood that tumors are not composed solely of cancerous cells, but also include a variety of normal cells within their structure. These tumor-associated normal cells encompass vascular endothelial cells, fibroblasts, and various inflammatory cells, including neutrophils, monocytes, macrophages, mast cells, eosinophils, and lymphocytes. Additionally, tumor cells engage in complex interactions with stromal cells and elements of the extracellular matrix (ECM). Initially, the components of what is now known as the tumor microenvironment (TME) were thought to be passive bystanders in the processes of tumor proliferation and local invasion. However, recent research has significantly advanced our understanding of the TME's active role in tumor growth and metastasis. Tumor progression is now known to be driven by an intricate imbalance of positive and negative regulatory signals, primarily influenced by specific growth factors produced by both inflammatory and neoplastic cells. This review article explores the latest developments and future directions in understanding how the TME modulates liver cancer, with the aim of informing the design of novel therapies that target critical components of the TME. [ABSTRACT FROM AUTHOR]

Published

2024

123. Three-Dimensional iPSC-Based In Vitro Cardiac Models for Biomedical and Pharmaceutical Research Applications.

Author

Bufi, Simona and Santoro, Rosaria

Subjects

INDUCED pluripotent stem cells, MEDICAL research, CARDIOVASCULAR diseases, INDIVIDUALIZED medicine, CARDIOMYOPATHIES

Abstract

Cardiovascular diseases are a major cause of death worldwide. Advanced in vitro models can be the key stone for a better understanding of the mechanisms at the basis of the different pathologies, supporting the development of novel therapeutic protocols. In particular, the implementation of induced pluripotent stem cell (iPSC) technology allows for the generation of a patient-specific pluripotent cell line that is able to differentiate in several organ-specific cell subsets while retaining the patient genetic background, thus putting the basis for personalized in vitro modeling toward personalized medicine. The design of iPSC-based models able to recapitulate the complexity of the cardiac environment is a critical goal. Here, we review some of the published efforts to exploit three dimensional (3D) iPSC-based methods to recapitulate the relevant cardiomyopathies, including genetically and non-genetically determined cardiomyopathies and cardiotoxicity studies. Finally, we discuss the actual method limitations and the future perspectives in the field. [ABSTRACT FROM AUTHOR]

Published

2024

124. Bridging the gap: advancing cancer cell culture to reveal key metabolic targets.

Author

Kes, Marjolein M. G., Berkers, Celia R., and Drost, Jarno

Subjects

CANCER cell culture, CELL metabolism, TUMOR microenvironment, CANCER cells, ORGANOIDS

Abstract

Metabolic rewiring is a defining characteristic of cancer cells, driving their ability to proliferate. Leveraging these metabolic vulnerabilities for therapeutic purposes has a long and impactful history, with the advent of antimetabolites marking a significant breakthrough in cancer treatment. Despite this, only a few in vitro metabolic discoveries have been successfully translated into effective clinical therapies. This limited translatability is partially due to the use of simplistic in vitro models that do not accurately reflect the tumor microenvironment. This Review examines the effects of current cell culture practices on cancer cell metabolism and highlights recent advancements in establishing more physiologically relevant in vitro culture conditions and technologies, such as organoids. Applying these improvements may bridge the gap between in vitro and in vivo findings, facilitating the development of innovative metabolic therapies for cancer. [ABSTRACT FROM AUTHOR]

Published

2024

125. The promise of Synovial Joint-on-a-Chip in rheumatoid arthritis.

Author

Xin Zhang, Rui Su, Hui Wang, Ruihe Wu, Yuxin Fan, Zexuan Bin, Chong Gao, and Caihong Wang

Subjects

MICROPHYSIOLOGICAL systems, RHEUMATOID arthritis, FLUID control, JOINT diseases, SPATIAL arrangement

Abstract

Rheumatoid arthritis (RA) affects millions of people worldwide, but there are limited drugs available to treat it, so acquiring a more comprehensive comprehension of the underlying reasons and mechanisms behind inflammation is crucial, as well as developing novel therapeutic approaches to manage it and mitigate or forestall associated harm. It is evident that current in vitro models cannot faithfully replicate all aspects of joint diseases, which makes them ineffective as tools for disease research and drug testing. Organ-on-a-chip (OoC) technology is an innovative platform that can mimic the microenvironment and physiological state of living tissues more realistically than traditional methods by simulating the spatial arrangement of cells and interorgan communication. This technology allows for the precise control of fluid flow, nutrient exchange, and the transmission of physicochemical signals, such as bioelectrical, mechanical stimulation and shear force. In addition, the integration of cutting-edge technologies like sensors, 3D printing, and artificial intelligence enhances the capabilities of these models. Here, we delve into OoC models with a particular focus on Synovial Joints-on-a-Chip, where we outline their structure and function, highlighting the potential of the model to advance our understanding of RA. We integrate the actual evidence regarding various OoC models and their possible integration for multisystem disease study in RA research for the first time and introduce the prospects and opportunities of the chip in RA etiology and pathological mechanism research, drug research, disease prevention and human precision medicine. Although many challenges remain, OoC holds great promise as an in vitro model that approaches physiology and dynamics. [ABSTRACT FROM AUTHOR]

Published

2024

126. Construction of Thick Myocardial Tissue through Layered Seeding in Multi-Layer Nanofiber Scaffolds.

Author

You, Yuru, Xu, Feng, Liu, Lingling, Chen, Songyue, Ding, Zhengmao, and Sun, Daoheng

Subjects

TECHNOLOGICAL innovations, TISSUE engineering, EXTRACELLULAR matrix, CELL growth, POLYCAPROLACTONE

Abstract

A major challenge in myocardial tissue engineering is replicating the heart's highly complex three-dimensional (3D) anisotropic structure. Heart-on-a-chip (HOC) is an emerging technology for constructing myocardial tissue in vitro in recent years, but most existing HOC systems face difficulties in constructing 3D myocardial tissue aligned with multiple cell layers. Electrospun nanofibers are commonly used as scaffolds for cell growth in myocardial tissue engineering, which can structurally simulate the extracellular matrix to induce the aligned growth of myocardial cells. Here, we developed an HOC that integrates multi-layered aligned polycaprolactone (PCL) nanofiber scaffolds inside microfluidic chips, and constructed 3D thick and aligned tissue with a layered seeding approach. By culturing human-induced pluripotent stem-cell-derived cardiomyocytes (hiPSC-CMs) on chip, the myocardial tissue on the two layered nanofibers reached a thickness of ~53 μm compared with ~19 μm for single-layered nanofibers. The obtained myocardial tissue presented well-aligned structures, with densely distributed α-actinin. By the third day post seeding, the hiPSC-CMs contract highly synchronously, with a contraction frequency of 18 times/min. The HOC with multi-layered biomimetic scaffolds provided a dynamic in vitro culture environment for hiPSC-CMs. Together with the layered cell-seeding process, the designed HOC promoted the formation of thick, well-aligned myocardial tissue. [ABSTRACT FROM AUTHOR]

Published

2024

127. A Synergistic Overview between Microfluidics and Numerical Research for Vascular Flow and Pathological Investigations.

Author

Shayor, Ahmed Abrar, Kabir, Md. Emamul, Rifath, Md. Sartaj Ahamed, Rashid, Adib Bin, and Oh, Kwang W.

Subjects

COMPUTATIONAL fluid dynamics, RHEOLOGY, FLUID flow, FLUID control, MICROFLUIDIC devices, MICROFLUIDICS

Abstract

Vascular diseases are widespread, and sometimes such life-threatening medical disorders cause abnormal blood flow, blood particle damage, changes to flow dynamics, restricted blood flow, and other adverse effects. The study of vascular flow is crucial in clinical practice because it can shed light on the causes of stenosis, aneurysm, blood cancer, and many other such diseases, and guide the development of novel treatments and interventions. Microfluidics and computational fluid dynamics (CFDs) are two of the most promising new tools for investigating these phenomena. When compared to conventional experimental methods, microfluidics offers many benefits, including lower costs, smaller sample quantities, and increased control over fluid flow and parameters. In this paper, we address the strengths and weaknesses of computational and experimental approaches utilizing microfluidic devices to investigate the rheological properties of blood, the forces of action causing diseases related to cardiology, provide an overview of the models and methodologies of experiments, and the fabrication of devices utilized in these types of research, and portray the results achieved and their applications. We also discuss how these results can inform clinical practice and where future research should go. Overall, it provides insights into why a combination of both CFDs, and experimental methods can give even more detailed information on disease mechanisms recreated on a microfluidic platform, replicating the original biological system and aiding in developing the device or chip itself. [ABSTRACT FROM AUTHOR]

Published

2024

128. The dark side of beauty: an in-depth analysis of the health hazards and toxicological impact of synthetic cosmetics and personal care products.

Author

Alnuqaydan, Abdullah M.

Published

2024

129. In Silico Approach to Model Heat Distribution of Magnetic Hyperthermia in the Tumoral and Healthy Vascular Network Using Tumor-on-a-Chip to Evaluate Effective Therapy.

Author

Munoz, Juan Matheus, Pileggi, Giovana Fontanella, Nucci, Mariana Penteado, Alves, Arielly da Hora, Pedrini, Flavia, Valle, Nicole Mastandrea Ennes do, Mamani, Javier Bustamante, Oliveira, Fernando Anselmo de, Lopes, Alexandre Tavares, Carreño, Marcelo Nelson Páez, and Gamarra, Lionel Fernel

Subjects

MAGNETIC nanoparticle hyperthermia, MICROFLUIDIC devices, GLIOBLASTOMA multiforme, TEMPERATURE distribution, MAGNETIC nanoparticles

Abstract

Glioblastoma multiforme (GBM) is the most severe form of brain cancer in adults, characterized by its complex vascular network that contributes to resistance to conventional therapies. Thermal therapies, such as magnetic hyperthermia (MHT), emerge as promising alternatives, using heat to selectively target tumor cells while minimizing damage to healthy tissues. The organ-on-a-chip can replicate this complex vascular network of GBM, allowing for detailed investigations of heat dissipation in MHT, while computational simulations refine treatment parameters. In this in silico study, tumor-on-a-chip models were used to optimize MHT therapy by comparing heat dissipation in normal and abnormal vascular networks, considering geometries, flow rates, and concentrations of magnetic nanoparticles (MNPs). In the high vascular complexity model, the maximum velocity was 19 times lower than in the normal vasculature model and 4 times lower than in the low-complexity tumor model, highlighting the influence of vascular complexity on velocity and temperature distribution. The MHT simulation showed greater heat intensity in the central region, with a flow rate of 1 µL/min and 0.5 mg/mL of MNPs being the best conditions to achieve the therapeutic temperature. The complex vasculature model had the lowest heat dissipation, reaching 44.15 °C, compared to 42.01 °C in the low-complexity model and 37.80 °C in the normal model. These results show that greater vascular complexity improves heat retention, making it essential to consider this heterogeneity to optimize MHT treatment. Therefore, for an efficient MHT process, it is necessary to simulate ideal blood flow and MNP conditions to ensure heat retention at the tumor site, considering its irregular vascularization and heat dissipation for effective destruction. [ABSTRACT FROM AUTHOR]

Published

2024

130. Revolutionizing Drug Discovery: The Impact of Distinct Designs and Biosensor Integration in Microfluidics-Based Organ-on-a-Chip Technology.

Author

Yuan, Sheng, Yuan, Huipu, Hay, David C., Hu, Huan, and Wang, Chaochen

Subjects

DRUG discovery, ORGANS (Anatomy), MICROPHYSIOLOGICAL systems, DRUG development, ANIMAL experimentation

Abstract

Traditional drug development is a long and expensive process with high rates of failure. This has prompted the pharmaceutical industry to seek more efficient drug development frameworks, driving the emergence of organ-on-a-chip (OOC) based on microfluidic technologies. Unlike traditional animal experiments, OOC systems provide a more accurate simulation of human organ microenvironments and physiological responses, therefore offering a cost-effective and efficient platform for biomedical research, particularly in the development of new medicines. Additionally, OOC systems enable quick and real-time analysis, high-throughput experimentation, and automation. These advantages have shown significant promise in enhancing the drug development process. The success of an OOC system hinges on the integration of specific designs, manufacturing techniques, and biosensors to meet the need for integrated multiparameter datasets. This review focuses on the manufacturing, design, sensing systems, and applications of OOC systems, highlighting their design and sensing capabilities, as well as the technical challenges they currently face. [ABSTRACT FROM AUTHOR]

Published

2024

131. Recent Advances in Polymer Science and Fabrication Processes for Enhanced Microfluidic Applications: An Overview.

Author

Alexandre-Franco, María F., Kouider, Rahmani, Kassir Al-Karany, Raúl, Cuerda-Correa, Eduardo M., and Al-Kassir, Awf

Subjects

CHEMICAL engineering, INJECTION molding, MANUFACTURING processes, MICROPHYSIOLOGICAL systems, CHEMICAL resistance, DRUG delivery devices, MICROFLUIDICS, MICROFLUIDIC devices

Abstract

This review explores significant advancements in polymer science and fabrication processes that have enhanced the performance and broadened the application scope of microfluidic devices. Microfluidics, essential in biotechnology, medicine, and chemical engineering, relies on precise fluid manipulation in micrometer-sized channels. Recent innovations in polymer materials, such as flexible, biocompatible, and structurally robust polymers, have been pivotal in developing advanced microfluidic systems. Techniques like replica molding, microcontact printing, solvent-assisted molding, injection molding, and 3D printing are examined, highlighting their advantages and recent developments. Additionally, the review discusses the diverse applications of polymer-based microfluidic devices in biomedical diagnostics, drug delivery, organ-on-chip models, environmental monitoring, and industrial processes. This paper also addresses future challenges, including enhancing chemical resistance, achieving multifunctionality, ensuring biocompatibility, and scaling up production. By overcoming these challenges, the potential for widespread adoption and impactful use of polymer-based microfluidic technologies can be realized. [ABSTRACT FROM AUTHOR]

Published

2024

132. Cancer Patient-Derived Cell-Based Models: Applications and Challenges in Functional Precision Medicine.

Author

Dinić, Jelena, Jovanović Stojanov, Sofija, Dragoj, Miodrag, Grozdanić, Marija, Podolski-Renić, Ana, and Pešić, Milica

Subjects

INDIVIDUALIZED medicine, ANTINEOPLASTIC agents, CANCER treatment, TREATMENT effectiveness, DRUG resistance, CELL culture

Abstract

The field of oncology has witnessed remarkable progress in personalized cancer therapy. Functional precision medicine has emerged as a promising avenue for achieving superior treatment outcomes by integrating omics profiling and sensitivity testing of patient-derived cancer cells. This review paper provides an in-depth analysis of the evolution of cancer-directed drugs, resistance mechanisms, and the role of functional precision medicine platforms in revolutionizing individualized treatment strategies. Using two-dimensional (2D) and three-dimensional (3D) cell cultures, patient-derived xenograft (PDX) models, and advanced functional assays has significantly improved our understanding of tumor behavior and drug response. This progress will lead to identifying more effective treatments for more patients. Considering the limited eligibility of patients based on a genome-targeted approach for receiving targeted therapy, functional precision medicine provides unprecedented opportunities for customizing medical interventions according to individual patient traits and individual drug responses. This review delineates the current landscape, explores limitations, and presents future perspectives to inspire ongoing advancements in functional precision medicine for personalized cancer therapy. [ABSTRACT FROM AUTHOR]

Published

2024

133. A compartmentalized microfluidic platform to investigate immune cells cross-talk in rheumatoid arthritis.

Author

Palma, Cecilia, Aterini, Bianca, Ferrari, Erika, Mangione, Marta, Romeo, Martina, Nezi, Luigi, Lopa, Silvia, Manzo, Teresa, Occhetta, Paola, and Rasponi, Marco

Published

2025

134. Numerical and experimental characterization of a novel modular passive micromixer.

Author

Pennella F, Rossi M, Ripandelli S, Rasponi M, Mastrangelo F, Deriu MA, Ridolfi L, Kähler CJ, and Morbiducci U

Subjects

Computer Simulation, Equipment Design, Microfluidic Analytical Techniques methods, Models, Theoretical, Microfluidic Analytical Techniques instrumentation, Microfluidics instrumentation, Microfluidics methods

Abstract

This paper reports a new low-cost passive microfluidic mixer design, based on a replication of identical mixing units composed of microchannels with variable curvature (clothoid) geometry. The micromixer presents a compact and modular architecture that can be easily fabricated using a simple and reliable fabrication process. The particular clothoid-based geometry enhances the mixing by inducing transversal secondary flows and recirculation effects. The role of the relevant fluid mechanics mechanisms promoting the mixing in this geometry were analysed using computational fluid dynamics (CFD) for Reynolds numbers ranging from 1 to 110. A measure of mixing potency was quantitatively evaluated by calculating mixing efficiency, while a measure of particle dispersion was assessed through the lacunarity index. The results show that the secondary flow arrangement and recirculation effects are able to provide a mixing efficiency equal to 80 % at Reynolds number above 70. In addition, the analysis of particles distribution promotes the lacunarity as powerful tool to quantify the dispersion of fluid particles and, in turn, the overall mixing. On fabricated micromixer prototypes the microscopic-Laser-Induced-Fluorescence (μLIF) technique was applied to characterize mixing. The experimental results confirmed the mixing potency of the microdevice.

Published

2012

135. A microfluidic platform for controlled biochemical stimulation of twin neuronal networks.

Author

Biffi E, Piraino F, Pedrocchi A, Fiore GB, Ferrigno G, Redaelli A, Menegon A, and Rasponi M

Abstract

Spatially and temporally resolved delivery of soluble factors is a key feature for pharmacological applications. In this framework, microfluidics coupled to multisite electrophysiology offers great advantages in neuropharmacology and toxicology. In this work, a microfluidic device for biochemical stimulation of neuronal networks was developed. A micro-chamber for cell culturing, previously developed and tested for long term neuronal growth by our group, was provided with a thin wall, which partially divided the cell culture region in two sub-compartments. The device was reversibly coupled to a flat micro electrode array and used to culture primary neurons in the same microenvironment. We demonstrated that the two fluidically connected compartments were able to originate two parallel neuronal networks with similar electrophysiological activity but functionally independent. Furthermore, the device allowed to connect the outlet port to a syringe pump and to transform the static culture chamber in a perfused one. At 14 days invitro, sub-networks were independently stimulated with a test molecule, tetrodotoxin, a neurotoxin known to block action potentials, by means of continuous delivery. Electrical activity recordings proved the ability of the device configuration to selectively stimulate each neuronal network individually. The proposed microfluidic approach represents an innovative methodology to perform biological, pharmacological, and electrophysiological experiments on neuronal networks. Indeed, it allows for controlled delivery of substances to cells, and it overcomes the limitations due to standard drug stimulation techniques. Finally, the twin network configuration reduces biological variability, which has important outcomes on pharmacological and drug screening.

Published

2012

136. Multi-gradient hydrogels produced layer by layer with capillary flow and crosslinking in open microchannels.

Author

Piraino F, Camci-Unal G, Hancock MJ, Rasponi M, and Khademhosseini A

Subjects

Animals, Anisotropy, Capillaries metabolism, Cellular Microenvironment, Cross-Linking Reagents, Gels, Mice, NIH 3T3 Cells, Polymers metabolism, Solutions metabolism, Biocompatible Materials chemical synthesis, Hydrogels chemical synthesis, Materials Testing methods

Abstract

This technical note describes a new bench-top method for producing anisotropic hydrogels composed of gradient layers of soluble factors, particles, polymer concentrations or material properties. Each gradient layer was produced by a previous gradient method in which a droplet of one precursor solution was added to a thin layer of a second solution. The ensuing rapid capillary flow along the open channel generated a gradient precursor solution, which was then crosslinked to form a gradient gel. Repeating these steps allowed a layered gel to be iteratively constructed with as many gradient layers as desired. This technique renders the synthesis of multi-layered gradient gels accessible to virtually any researcher and should help simplify the production of more biologically relevant cellular microenvironments.

Published

2012

137. Validation of long-term primary neuronal cultures and network activity through the integration of reversibly bonded microbioreactors and MEA substrates.

Author

Biffi E, Menegon A, Piraino F, Pedrocchi A, Fiore GB, and Rasponi M

Subjects

Animals, Cells, Cultured, Magnetics, Mice, Time Factors, Cell Culture Techniques methods, Microelectrodes, Microfluidic Analytical Techniques methods, Nerve Net physiology, Neurons physiology

Abstract

In vitro recording of neuronal electrical activity is a widely used technique to understand brain functions and to study the effect of drugs on the central nervous system. The integration of microfluidic devices with microelectrode arrays (MEAs) enables the recording of networks activity in a controlled microenvironment. In this work, an integrated microfluidic system for neuronal cultures was developed, reversibly coupling a PDMS microfluidic device with a commercial flat MEA through magnetic forces. Neurons from mouse embryos were cultured in a 100 µm channel and their activity was followed up to 18 days in vitro. The maturation of the networks and their morphological and functional characteristics were comparable with those of networks cultured in macro-environments and described in literature. In this work, we successfully demonstrated the ability of long-term culturing of primary neuronal cells in a reversible bonded microfluidic device (based on magnetism) that will be fundamental for neuropharmacological studies., (Copyright © 2011 Wiley Periodicals, Inc.)

Published

2012

138. Realization and efficiency evaluation of a micro-photocatalytic cell prototype for real-time blood oxygenation.

Author

Rasponi M, Ullah T, Gilbert RJ, Fiore GB, and Thorsen TA

Subjects

Animals, Catalysis, Cattle, Coated Materials, Biocompatible chemistry, Dimethylpolysiloxanes chemistry, Electrodes, Methylene Blue chemistry, Platinum chemistry, Time Factors, Titanium chemistry, Blood metabolism, Microfluidic Analytical Techniques methods, Oxygen metabolism, Photochemical Processes

Abstract

A novel, miniaturized, high-efficiency photocatalytic cell, able to work in dynamic conditions, has been designed and validated in this study. Microfluidic channels were molded out of polydimethylsiloxane (PDMS) by means of standard soft lithography techniques, so as to work as photocatalytic cells, where the coupling of anatase titanium dioxide thin films and platinum electrodes, allows an electrically assisted photocatalytic reaction to produce dissolved oxygen gas from the water content of flowing fluid (e.g. blood). The thin films were deposited onto quartz glass substrates at room temperature (300 K) using reactive radio-frequency sputtering with a titanium metal target. The photocatalytic activity was evaluated through reduction rate of methylene blue solution. The results of the current study, as a proof of concept, have shown that the device can generate oxygen at a rate of 4.06 μM O(2)/(cm(2)min), thus extending its possible application range to the full oxygenation of flowing venous blood., (Copyright © 2010 IPEM. Published by Elsevier Ltd. All rights reserved.)

Published

2011

139. Anisotropic material synthesis by capillary flow in a fluid stripe.

Author

Hancock MJ, Piraino F, Camci-Unal G, Rasponi M, and Khademhosseini A

Subjects

Animals, Anisotropy, Mice, Microspheres, NIH 3T3 Cells, Polymers pharmacology, Solutions, Biocompatible Materials chemical synthesis, Rheology methods

Abstract

We present a simple bench-top technique to produce centimeter long concentration gradients in biomaterials incorporating soluble, material, and particle gradients. By patterning hydrophilic regions on a substrate, a stripe of prepolymer solution is held in place on a glass slide by a hydrophobic boundary. Adding a droplet to one end of this "pre-wet" stripe causes a rapid capillary flow that spreads the droplet along the stripe to generate a gradient in the relative concentrations of the droplet and pre-wet solutions. The gradient length and shape are controlled by the pre-wet and droplet volumes, stripe thickness, fluid viscosity and surface tension. Gradient biomaterials are produced by crosslinking gradients of prepolymer solutions. Demonstrated examples include a concentration gradient of cells encapsulated in three dimensions (3D) within a homogeneous biopolymer and a constant concentration of cells encapsulated in 3D within a biomaterial gradient exhibiting a gradient in cell spreading. The technique employs coated glass slides that may be purchased or custom made from tape and hydrophobic spray. The approach is accessible to virtually any researcher or student and should dramatically reduce the time required to synthesize a wide range of gradient biomaterials. Moreover, since the technique employs passive mechanisms it is ideal for remote or resource poor settings., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published

2011

140. Microfabricated polyester conical microwells for cell culture applications.

Author

Selimović S, Piraino F, Bae H, Rasponi M, Redaelli A, and Khademhosseini A

Subjects

Animals, Cell Adhesion, Cell Culture Techniques economics, Cell Culture Techniques instrumentation, Cell Survival, Embryonic Stem Cells cytology, Hep G2 Cells, Humans, Mice, Silicones chemistry, Cell Culture Techniques methods, Polyesters chemistry

Abstract

Over the past few years there has been a great deal of interest in reducing experimental systems to a lab-on-a-chip scale. There has been particular interest in conducting high-throughput screening studies using microscale devices, for example in stem cell research. Microwells have emerged as the structure of choice for such tests. Most manufacturing approaches for microwell fabrication are based on photolithography, soft lithography, and etching. However, some of these approaches require extensive equipment, lengthy fabrication process, and modifications to the existing microwell patterns are costly. Here we show a convenient, fast, and low-cost method for fabricating microwells for cell culture applications by laser ablation of a polyester film coated with silicone glue. Microwell diameter was controlled by adjusting the laser power and speed, and the well depth by stacking several layers of film. By using this setup, a device containing hundreds of microwells can be fabricated in a few minutes to analyze cell behavior. Murine embryonic stem cells and human hepatoblastoma cells were seeded in polyester microwells of different sizes and showed that after 9 days in culture cell aggregates were formed without a noticeable deleterious effect of the polyester film and glue. These results show that the polyester microwell platform may be useful for cell culture applications. The ease of fabrication adds to the appeal of this device as minimal technological skill and equipment is required.

Published

2011

141. How to embed three-dimensional flexible electrodes in microfluidic devices for cell culture applications.

Author

Pavesi A, Piraino F, Fiore GB, Farino KM, Moretti M, and Rasponi M

Subjects

Animals, Cell Culture Techniques methods, Cell Line, Dimethylpolysiloxanes, Electromagnetic Fields, Equipment Design, Microfluidic Analytical Techniques methods, Myoblasts, Cardiac, Nanocomposites, Nylons, Rats, Cell Culture Techniques instrumentation, Electrodes, Microfluidic Analytical Techniques instrumentation

Abstract

This communication describes a simple, rapid and cost effective method of embedding a conductive and flexible material within microfluidic devices as a means to realize uniform electric fields within cellular microenvironments. Fluidic channels and electrodes are fabricated by traditional soft-lithography in conjunction with chemical etching of PDMS. Devices can be deformable (thus allowing for a combination of electro-mechanical stimulation), they are made from inexpensive materials and easily assembled by hand; this method is thus accessible to a wide range of laboratories and budgets., (© The Royal Society of Chemistry 2011)

Published

2011

142. Computational and functional evaluation of a microfluidic blood flow device.

Author

Gilbert RJ, Park H, Rasponi M, Redaelli A, Gellman B, Dasse KA, and Thorsen T

Subjects

Blood Pressure, Capillaries, Dimethylpolysiloxanes, Equipment Design, Finite Element Analysis, Hemoglobins metabolism, Hemolysis, Humans, Materials Testing, Microcirculation, Perfusion, Time Factors, Blood Vessel Prosthesis standards, Computer Simulation, Models, Cardiovascular, Pulmonary Circulation

Abstract

The development of microfluidic devices supporting physiological blood flow has the potential to yield biomedical technologies emulating human organ function. However, advances in this area have been constrained by the fact that artificial microchannels constructed for such devices need to achieve maximum chemical diffusion as well as hemocompatibility. To address this issue, we designed an elastomeric microfluidic flow device composed of poly (dimethylsiloxane) to emulate the geometry and flow properties of the pulmonary microcirculation. Our chip design is characterized by high aspect ratio (width > height) channels in an orthogonally interconnected configuration. Finite element simulations of blood flow through the network design chip demonstrated that the apparent pressure drop varied in a linear manner with flow rate. For simulated flow rates <250 mul min, the simulated pressure drop was <2000 Pa, the flow was laminar, and hemolysis was minimal. Hemolysis rate, assayed in terms of [total plasma hemoglobin (TPH) (sample - control)/(TPH control)] during 6 and 12 hour perfusions at 250 mul/min, was <5.0% through the entire period of device perfusion. There was no evidence of microscopic thrombus at any channel segment or junction under these perfusion conditions. We conclude that a microfluidic blood flow device possessing asymmetric and interconnected microchannels exhibits uniform flow properties and preliminary hemocompatibility. Such technology should foster the development of miniature oxygenators and similar biomedical devices requiring both a microscale reaction volume and physiological blood flow.

Published

2007

143. 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

144. Mesenchymal Stem Cell and Hematopoietic Stem and Progenitor Cell Co-Culture in a Bone-Marrow-on-a-Chip Device toward the Generation and Maintenance of the Hematopoietic Niche.

Author

Kefallinou, Dionysia, Grigoriou, Maria, Boumpas, Dimitrios T., and Tserepi, Angeliki

Subjects

MESENCHYMAL stem cells, CELL culture, HEMATOPOIETIC stem cells, CYTOLOGY, BIOMIMETICS, BONE marrow, ANIMAL experimentation

Abstract

Bone marrow has raised a great deal of scientific interest, since it is responsible for the vital process of hematopoiesis and is affiliated with many normal and pathological conditions of the human body. In recent years, organs-on-chips (OoCs) have emerged as the epitome of biomimetic systems, combining the advantages of microfluidic technology with cellular biology to surpass conventional 2D/3D cell culture techniques and animal testing. Bone-marrow-on-a-chip (BMoC) devices are usually focused only on the maintenance of the hematopoietic niche; otherwise, they incorporate at least three types of cells for on-chip generation. We, thereby, introduce a BMoC device that aspires to the purely in vitro generation and maintenance of the hematopoietic niche, using solely mesenchymal stem cells (MSCs) and hematopoietic stem and progenitor cells (HSPCs), and relying on the spontaneous formation of the niche without the inclusion of gels or scaffolds. The fabrication process of this poly(dimethylsiloxane) (PDMS)-based device, based on replica molding, is presented, and two membranes, a perforated, in-house-fabricated PDMS membrane and a commercial poly(ethylene terephthalate) (PET) one, were tested and their performances were compared. The device was submerged in a culture dish filled with medium for passive perfusion via diffusion in order to prevent on-chip bubble accumulation. The passively perfused BMoC device, having incorporated a commercial poly(ethylene terephthalate) (PET) membrane, allows for a sustainable MSC and HSPC co-culture and proliferation for three days, a promising indication for the future creation of a hematopoietic bone marrow organoid. [ABSTRACT FROM AUTHOR]

Published

2024

145. An Evaluation of Sex-Specific Pharmacokinetics and Bioavailability of Kokusaginine: An In Vitro and In Vivo Investigation.

Author

Shang, Kaiqi, Ge, Chengyu, Zhang, Yindi, Xiao, Jing, Liu, Shao, and Jiang, Yueping

Subjects

LIVER microsomes, DRUG metabolism, DRUG development, DRUG efficacy, LIQUID chromatography

Abstract

Kokusaginine is a bioactive ingredient extracted from Ruta graveolens L., which has a range of biological activities. Its pharmacokinetic (PK) properties are particularly important for clinical applications; however, they have not been fully elucidated. In addition, the effect of sex differences on drug metabolism is increasingly being recognized, but most studies have ignored this important factor. This study aims to fill this knowledge gap by taking an in-depth look at the PK properties of kokusaginine and how gender affects its metabolism and distribution in the body. It also lays the foundation for clinical drug development. In this study, a sensitive ultra-high-performance liquid chromatography (UPLC) method was developed and validated for quantifying kokusaginine in Sprague Dawley (SD) rat plasma and tissue homogenates. Metabolic stability was evaluated in vitro using gender-specific liver microsomes. Innovatively, we incorporated sex as a variable into both in vitro and in vivo PK studies in SD rats, analyzing key parameters with Phoenix 8.3.5 software. The developed UPLC method demonstrated high sensitivity and precision, essential for PK analysis. Notably, in vitro studies revealed a pronounced sex-dependent metabolic variability (p < 0.05). In vivo, gender significantly affected the Area Under the Moment Curve (AUMC)(0-∞) of the plasma PK parameter (p < 0.05) and the AUMC(0-t) of brain tissue (p < 0.0001), underscoring the necessity of sex-specific PK assessments. The calculated absolute bioavailability of 71.13 ± 12.75% confirmed the favorable oral absorption of kokusaginine. Additionally, our innovative tissue-plasma partition coefficient (Kp) analysis highlighted a rapid and uniform tissue distribution pattern. This study presents a sex-inclusive PK evaluation of kokusaginine, offering novel insights into its metabolic profile and distribution. These findings are instrumental for informing clinical medication practices, dosage optimization, and a nuanced understanding of drug efficacy and safety in a sex-specific context. [ABSTRACT FROM AUTHOR]

Published

2024

146. Blood–brain barrier injury and neuroinflammation induced by SARS-CoV-2 in a lung–brain microphysiological system.

Author

Wang, Peng, Jin, Lin, Zhang, Min, Wu, Yunsong, Duan, Zilei, Guo, Yaqiong, Wang, Chaoming, Guo, Yingqi, Chen, Wenwen, Liao, Zhiyi, Wang, Yaqing, Lai, Ren, Lee, Luke P., and Qin, Jianhua

Published

2024

147. 3D matrix stiffness modulation unveils cardiac fibroblast phenotypic switching.

Author

Han, Yan, Shao, Zehua, Zhang, Yuanhao, Zhao, Huan, Sun, Zirui, Yang, Chaokuan, Tang, Hao, Han, Yu, and Gao, Chuanyu

Subjects

FOCAL adhesions, HEART fibrosis, FIBROBLASTS, PHENOTYPES, MYOFIBROBLASTS

Abstract

This study investigates how dynamic fluctuations in matrix stiffness affect the behavior of cardiac fibroblasts (CFs) within a three-dimensional (3D) hydrogel environment. Using hybrid hydrogels with tunable stiffness, we created an in vitro model to mimic the varying stiffness of the cardiac microenvironment. By manipulating hydrogel stiffness, we examined CF responses, particularly the expression of α-smooth muscle actin (α-SMA), a marker of myofibroblast differentiation. Our findings reveal that increased matrix stiffness promotes the differentiation of CFs into myofibroblasts, while matrix softening reverses this process. Additionally, we identified the role of focal adhesions and integrin β1 in mediating stiffness-induced phenotypic switching. This study provides significant insights into the mechanobiology of cardiac fibrosis and suggests that modulating matrix stiffness could be a potential therapeutic strategy for treating cardiovascular diseases. [ABSTRACT FROM AUTHOR]

Published

2024

148. Architecture design and advanced manufacturing of heart-on-a-chip: scaffolds, stimulation and sensors.

Author

Xu, Feng, Jin, Hang, Liu, Lingling, Yang, Yuanyuan, Cen, Jianzheng, Wu, Yaobin, Chen, Songyue, and Sun, Daoheng

Subjects

ARCHITECTURAL design, HIGH throughput screening (Drug development), DRUG delivery devices, DRUG development, DETECTORS

Abstract

Heart-on-a-chip (HoC) has emerged as a highly efficient, cost-effective device for the development of engineered cardiac tissue, facilitating high-throughput testing in drug development and clinical treatment. HoC is primarily used to create a biomimetic microphysiological environment conducive to fostering the maturation of cardiac tissue and to gather information regarding the real-time condition of cardiac tissue. The development of architectural design and advanced manufacturing for these "3S" components, scaffolds, stimulation, and sensors is essential for improving the maturity of cardiac tissue cultivated on-chip, as well as the precision and accuracy of tissue states. In this review, the typical structures and manufacturing technologies of the "3S" components are summarized. The design and manufacturing suggestions for each component are proposed. Furthermore, key challenges and future perspectives of HoC platforms with integrated "3S" components are discussed. [ABSTRACT FROM AUTHOR]

Published

2024

149. Integrating Computational and Biological Hemodynamic Approaches to Improve Modeling of Atherosclerotic Arteries.

Author

Vuong, Thao Nhu Anne Marie, Bartolf‐Kopp, Michael, Andelovic, Kristina, Jungst, Tomasz, Farbehi, Nona, Wise, Steven G., Hayward, Christopher, Stevens, Michael Charles, and Rnjak‐Kovacina, Jelena

Subjects

HUMAN anatomy, HEMODYNAMICS, BIOCOMPLEXITY, ARTERIES, CORONARY arteries

Abstract

Atherosclerosis is the primary cause of cardiovascular disease, resulting in mortality, elevated healthcare costs, diminished productivity, and reduced quality of life for individuals and their communities. This is exacerbated by the limited understanding of its underlying causes and limitations in current therapeutic interventions, highlighting the need for sophisticated models of atherosclerosis. This review critically evaluates the computational and biological models of atherosclerosis, focusing on the study of hemodynamics in atherosclerotic coronary arteries. Computational models account for the geometrical complexities and hemodynamics of the blood vessels and stenoses, but they fail to capture the complex biological processes involved in atherosclerosis. Different in vitro and in vivo biological models can capture aspects of the biological complexity of healthy and stenosed vessels, but rarely mimic the human anatomy and physiological hemodynamics, and require significantly more time, cost, and resources. Therefore, emerging strategies are examined that integrate computational and biological models, and the potential of advances in imaging, biofabrication, and machine learning is explored in developing more effective models of atherosclerosis. [ABSTRACT FROM AUTHOR]

Published

2024

150. Design Considerations and Flow Characteristics for Couette-Type Blood-Shear Devices.

Author

Chen, Xingbang, Avital, Eldad J., Imran, Shahid, Abbas, Muhammad Mujtaba, Hinkle, Patrick, and Alexander, Theodosios

Subjects

SHEAR flow, PROSTHETICS, UNSTEADY flow, LAMINAR flow, TURBULENT flow

Abstract

Cardiovascular prosthetic devices, stents, prosthetic valves, heart-assist pumps, etc., operate in a wide regime of flows characterized by fluid dynamic flow structures, laminar and turbulent flows, unsteady flow patterns, vortices, and other flow disturbances. These flow disturbances cause shear stress, hemolysis, platelet activation, thrombosis, and other types of blood trauma, leading to neointimal hyperplasia, neoatherosclerosis, pannus overgrowth, etc. Couette-type blood-shearing devices are used to simulate and then clinically measure blood trauma, after which the results can be used to assist in the design of the cardiovascular prosthetic devices. However, previous designs for such blood-shearing devices do not cover the whole range of flow shear, Reynolds numbers, and Taylor numbers characteristic of all types of implanted cardiovascular prosthetic devices, limiting the general applicability of clinical data obtained by tests using different blood-shearing devices. This paper presents the key fluid dynamic parameters that must be met. Based on this, Couette device geometric parameters such as diameter, gap, flow rate, shear stress, and temperature are carefully selected to ensure that the device's Reynolds numbers, Taylor number, operating temperature, and shear stress in the gap fully represent the flow characteristics across the operating range of all types of cardiovascular prosthetic devices. The outcome is that the numerical data obtained from the presented device can be related to all such prosthetic devices and all flow conditions, making the results obtained with such shearing devices widely applicable across the field. Numerical simulations illustrate that the types of flow patterns generated in the blood-shearing device meet the above criteria. [ABSTRACT FROM AUTHOR]

Published

2024