Your search keyword '"Rasponi M"' showing total 10 results

1. Enhancing all-in-one bioreactors by combining interstitial perfusion, electrical stimulation, on-line monitoring and testing within a single chamber for cardiac constructs.

Author

Visone R, Talò G, Lopa S, Rasponi M, and Moretti M

Subjects

Animals, Animals, Newborn, Cells, Cultured, Electric Stimulation, Fibroblasts metabolism, Gene Expression, Heart physiology, Myocardial Contraction physiology, Myocardium cytology, Myocardium metabolism, Myocytes, Cardiac metabolism, Myosin Heavy Chains genetics, Myosin Heavy Chains metabolism, Perfusion methods, Rats, Tissue Engineering instrumentation, Bioreactors, Fibroblasts cytology, Myocytes, Cardiac cytology, Tissue Engineering methods

Abstract

Tissue engineering strategies have been extensively exploited to generate functional cardiac patches. To maintain cardiac functionality in vitro, bioreactors have been designed to provide perfusion and electrical stimulation, alone or combined. However, due to several design limitations the integration of optical systems to assess cardiac maturation level is still missing within these platforms. Here we present a bioreactor culture chamber that provides 3D cardiac constructs with a bidirectional interstitial perfusion and biomimetic electrical stimulation, allowing direct cellular optical monitoring and contractility test. The chamber design was optimized through finite element models to house an innovative scaffold anchoring system to hold and to release it for the evaluation of tissue maturation and functionality by contractility tests. Neonatal rat cardiac fibroblasts subjected to a combined perfusion and electrical stimulation showed positive cell viability over time. Neonatal rat cardiomyocytes were successfully monitored for the entire culture period to assess their functionality. The combination of perfusion and electrical stimulation enhanced patch maturation, as evidenced by the higher contractility, the enhanced beating properties and the increased level of cardiac protein expression. This new multifunctional bioreactor provides a relevant biomimetic environment allowing for independently culturing, real-time monitoring and testing up to 18 separated patches.

Published

2018

2. Developmentally inspired programming of adult human mesenchymal stromal cells toward stable chondrogenesis.

Author

Occhetta P, Pigeot S, Rasponi M, Dasen B, Mehrkens A, Ullrich T, Kramer I, Guth-Gundel S, Barbero A, and Martin I

Subjects

Activin Receptors, Type I metabolism, Adult, Animals, Bone Marrow Cells metabolism, Bone Morphogenetic Protein Receptors, Type I metabolism, Bone Morphogenetic Proteins antagonists & inhibitors, Bone Morphogenetic Proteins metabolism, Cartilage, Articular metabolism, Cells, Cultured, Chondrocytes metabolism, Chondrogenesis physiology, Gene Expression Regulation drug effects, Humans, Mesenchymal Stem Cells metabolism, Mice, Osteogenesis drug effects, Primary Cell Culture, Signal Transduction drug effects, Cell Differentiation drug effects, Mesenchymal Stem Cells physiology, Tissue Engineering methods

Abstract

It is generally accepted that adult human bone marrow-derived mesenchymal stromal cells (hMSCs) are default committed toward osteogenesis. Even when induced to chondrogenesis, hMSCs typically form hypertrophic cartilage that undergoes endochondral ossification. Because embryonic mesenchyme is obviously competent to generate phenotypically stable cartilage, it is questioned whether there is a correspondence between mesenchymal progenitor compartments during development and in adulthood. Here we tested whether forcing specific early events of articular cartilage development can program hMSC fate toward stable chondrogenesis. Inspired by recent findings that spatial restriction of bone morphogenetic protein (BMP) signaling guides embryonic progenitors toward articular cartilage formation, we hypothesized that selective inhibition of BMP drives the phenotypic stability of hMSC-derived chondrocytes. Two BMP type I receptor-biased kinase inhibitors were screened in a microfluidic platform for their time- and dose-dependent effect on hMSC chondrogenesis. The different receptor selectivity profile of tested compounds allowed demonstration that transient blockade of both ALK2 and ALK3 receptors, while permissive to hMSC cartilage formation, is necessary and sufficient to maintain a stable chondrocyte phenotype. Remarkably, even upon compound removal, hMSCs were no longer competent to undergo hypertrophy in vitro and endochondral ossification in vivo, indicating the onset of a constitutive change. Our findings demonstrate that adult hMSCs effectively share properties of embryonic mesenchyme in the formation of transient but also of stable cartilage. This opens potential pharmacological strategies to articular cartilage regeneration and more broadly indicates the relevance of developmentally inspired protocols to control the fate of adult progenitor cell systems., Competing Interests: The authors declare no conflict of interest.

Published

2018

3. Generation of functional cardiac microtissues in a beating heart-on-a-chip.

Author

Ugolini GS, Visone R, Cruz-Moreira D, Mainardi A, and Rasponi M

Subjects

Humans, Microfluidics, Heart physiology, Lab-On-A-Chip Devices, Tissue Engineering instrumentation, Tissue Engineering methods

Abstract

With the increasing attention on cardiovascular disorders and the current inability of pre-clinical models to accurately predict human physiology, the need for advanced and reliable heart in vitro models is paramount. Microfabrication technologies provide potential solutions in the organs-on-chip systems: microengineered devices where cell cultures can be hosted and cultured to develop three-dimensional models or microtissues with high similarity to human physiology. We here described the fabrication and operation procedures for a beating heart-on-a-chip. The device features a culture region for a 3D cardiac microtissue and a system for applying tuned mechanical stimulation during culture to improve cardiac development. We additionally describe procedures for characterizing tissue maturation via immunofluorescence and functional evaluations of microtissue contractility., (© 2018 Elsevier Inc. All rights reserved.)

Published

2018

4. 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

5. 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

6. 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

7. 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

8. Fabrication of 3D cell-laden hydrogel microstructures through photo-mold patterning.

Author

Occhetta P, Sadr N, Piraino F, Redaelli A, Moretti M, and Rasponi M

Subjects

Cell Proliferation, Human Umbilical Vein Endothelial Cells cytology, Humans, Hydrogel, Polyethylene Glycol Dimethacrylate chemical synthesis, Mesenchymal Stem Cells cytology, Polymerization radiation effects, Hydrogel, Polyethylene Glycol Dimethacrylate chemistry, Photochemistry methods, Tissue Engineering instrumentation, Tissue Scaffolds chemistry

Abstract

Native tissues are characterized by spatially organized three-dimensional (3D) microscaled units which functionally define cells-cells and cells-extracellular matrix interactions. The ability to engineer biomimetic constructs mimicking these 3D microarchitectures is subject to the control over cell distribution and organization. In the present study we introduce a novel protocol to generate 3D cell laden hydrogel micropatterns with defined size and shape. The method, named photo-mold patterning (PMP), combines hydrogel micromolding within polydimethylsiloxane (PDMS) stamps and photopolymerization through a recently introduced biocompatible ultraviolet (UVA) activated photoinitiator (VA-086). Exploiting PDMS micromolds as geometrical constraints for two methacrylated prepolymers (polyethylene glycol diacrylate and gelatin methacrylate), micrometrically resolved structures were obtained within a 3 min exposure to a low cost and commercially available UVA LED. The PMP was validated both on a continuous cell line (human umbilical vein endothelial cells expressing green fluorescent protein, HUVEC GFP) and on primary human bone marrow stromal cells (BMSCs). HUVEC GFP and BMSCs were exposed to 1.5% w/v VA-086 and UVA light (1 W, 385 nm, distance from sample = 5 cm). Photocrosslinking conditions applied during the PMP did not negatively affect cells viability or specific metabolic activity. Quantitative analyses demonstrated the potentiality of PMP to uniformly embed viable cells within 3D microgels, creating biocompatible and favorable environments for cell proliferation and spreading during a seven days' culture. PMP can thus be considered as a promising and cost effective tool for designing spatially accurate in vitro models and, in perspective, functional constructs.

Published

2013

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

Author

Occhetta, P, Visone, R, RUSSO, LAURA, CIPOLLA, LAURA FRANCESCA, Moretti, M, Rasponi, M., Occhetta, P, Visone, R, Russo, L, Cipolla, L, Moretti, M, and Rasponi, M

Subjects

3D cell culture, Light, cell-laden hydrogels photopolymerization, Green Fluorescent Proteins, Sus scrofa, biomaterial, Cell Culture Techniques, Biocompatible Materials, Hydrogels, Mesenchymal Stem Cells, Coculture Techniques, Polymerization, Cross-Linking Reagents, tissue engineering, Elastic Modulus, Acetamides, Human Umbilical Vein Endothelial Cells, Animals, Gelatin, Humans, Methacrylates, Azo Compounds, GelMA

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.

Published

2014

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

Author

Mara Gilardi, Marco Rasponi, Roberta Visone, Anna Marsano, Simone Bersini, Matteo Moretti, Visone, R, Gilardi, M, Marsano, A, Rasponi, M, Bersini, S, and Moretti, M

Subjects

0301 basic medicine, Muscle tissue, cardiac muscle, Computer science, Microfluidics, microfluidic, Pharmaceutical Science, Nanotechnology, Review, heart, Models, Biological, Analytical Chemistry, electrical stimulation, in vitro 3D model, mechanical stimulation, organ-on-a-chip, skeletal muscle, lcsh:QD241-441, 03 medical and health sciences, lcsh:Organic chemistry, Lab-On-A-Chip Devices, Drug Discovery, medicine, Animals, Humans, Physical and Theoretical Chemistry, Muscle, Skeletal, Tissue Engineering, Myocardium, Organic Chemistry, Skeletal muscle, Key features, Electrical stimulations, 030104 developmental biology, medicine.anatomical_structure, Chemistry (miscellaneous), Cardiac muscle tissue, Molecular Medicine, Biomedical engineering

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