Your search keyword '"Soft Tissue Biomech. ' showing total 1,157 results

1. Computer Model-Driven Design in Cardiovascular Regenerative Medicine

Author

Sandra Loerakker, Jay D. Humphrey, Modeling in Mechanobiology, Soft Tissue Biomech. & Tissue Eng., and ICMS Affiliated

Subjects

Mechanobiology, Finite element, Biomedical Engineering, Homeostasis, Tissue Engineering/methods, Animals, Tissue engineering, Computer Simulation, Regenerative Medicine, Cardiovascular System, Growth and remodeling, Blood Vessel Prosthesis

Abstract

Continuing advances in genomics, molecular and cellular mechanobiology and immunobiology, including transcriptomics and proteomics, and biomechanics increasingly reveal the complexity underlying native tissue and organ structure and function. Identifying methods to repair, regenerate, or replace vital tissues and organs remains one of the greatest challenges of modern biomedical engineering, one that deserves our very best effort. Notwithstanding the continuing need for improving standard methods of investigation, including cell, organoid, and tissue culture, biomaterials development and fabrication, animal models, and clinical research, it is increasingly evident that modern computational methods should play increasingly greater roles in advancing the basic science, bioengineering, and clinical application of regenerative medicine. This brief review focuses on the development and application of computational models of tissue and organ mechanobiology and mechanics for purposes of designing tissue engineered constructs and understanding their development in vitro and in situ. Although the basic approaches are general, for illustrative purposes we describe two recent examples from cardiovascular medicine—tissue engineered heart valves (TEHVs) and tissue engineered vascular grafts (TEVGs)—to highlight current methods of approach as well as continuing needs.

Published

2023

2. Methacrylated human recombinant collagen peptide as a hydrogel for manipulating and monitoring stiffness-related cardiac cell behavior

Author

Dylan Mostert, Ignasi Jorba, Bart G.W. Groenen, Robert Passier, Marie-José T.H. Goumans, Huibert A. van Boxtel, Nicholas A. Kurniawan, Carlijn V.C. Bouten, Leda Klouda, Cell-Matrix Interact. Cardiov. Tissue Reg., Immunoengineering, Biomedical Engineering, Soft Tissue Biomech. & Tissue Eng., and ICMS Affiliated

Subjects

Biomaterials, Cell biology, Multidisciplinary, Stem cells research, Materials in biotechnology, Article

Abstract

Environmental stiffness is a crucial determinant of cell function. There is a long-standing quest for reproducible and (human matrix) bio-mimicking biomaterials with controllable mechanical properties to unravel the relationship between stiffness and cell behavior. Here, we evaluate methacrylated human recombinant collagen peptide (RCPhC1-MA) hydrogels as a matrix to control 3D microenvironmental stiffness and monitor cardiac cell response. We show that RCPhC1-MA can form hydrogels with reproducible stiffness in the range of human developmental and adult myocardium. Cardiomyocytes (hPSC-CMs) and cardiac fibroblasts (cFBs) remain viable for up to 14 days inside RCPhC1-MA hydrogels while the effect of hydrogel stiffness on extracellular matrix production and hPSC-CM contractility can be monitored in real-time. Interestingly, whereas the beating behavior of the hPSC-CM monocultures is affected by environmental stiffness, this effect ceases when cFBs are present. Together, we demonstrate RCPhC1-MA to be a promising candidate to mimic and control the 3D biomechanical environment of cardiac cells.

Published

2023

3. Changes in extracellular matrix in failing human non-ischemic and ischemic hearts with mechanical unloading

Author

Yimu Zhao, Amandine Godier-Furnemont, Noortje A.M. Bax, Carlijn V.C. Bouten, Lewis M. Brown, Barry Fine, Gordana Vunjak-Novakovic, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., Center for Care & Cure Technology Eindhoven, NeuroPlatform, and ICMS Core

Subjects

Proteomics, Myocardium, Disease niches, Heart failure, Extracellular matrix, LVAD support, SDG 3 – Goede gezondheid en welzijn, Article, Ischemic cardiomyopathy, Non-ischemic cardiomyopathy, SDG 3 - Good Health and Well-being, Humans, Heart-Assist Devices, Cardiology and Cardiovascular Medicine, Molecular Biology

Abstract

Ischemic and non-ischemic cardiomyopathies have distinct etiologies and underlying disease mechanisms, which require in-depth investigation for improved therapeutic interventions. The goal of this study was to use clinically obtained myocardium from healthy and heart failure patients, and characterize the changes in extracellular matrix (ECM) in ischemic and non-ischemic failing hearts, with and without mechanical unloading. Using tissue engineering methodologies, we also investigated how diseased human ECM, in the absence of systemic factors, can influence cardiomyocyte function. Heart tissues from heart failure patients with ischemic and non-ischemic cardiomyopathy were compared to explore differential disease phenotypes and reverse remodeling potential of left ventricular assisted device (LVAD) support at transcriptomic, proteomic and structural levels. The collected data demonstrated that the differential ECM compositions recapitulated the disease microenvironment and induced cardiomyocytes to undergo disease-like functional alterations. In addition, our study also revealed molecular profiles of non-ischemic and ischemic heart failure patients and explored the underlying mechanisms of etiology-specific impact on clinical outcome of LVAD support and tendency towards reverse remodeling.

Published

2022

4. Stimuli-responsive materials

Author

Maaike Bril, Sebastian Fredrich, Nicholas A. Kurniawan, Soft Tissue Biomech. & Tissue Eng., Cell-Matrix Interact. Cardiov. Tissue Reg., Stimuli-responsive Funct. Materials & Dev., and ICMS Affiliated

Subjects

Biomaterials, Mechanobiology, Dynamic physical stimuli, Biomedical Engineering, Stimuli-responsive materials, Bioengineering, Cell migration, Epigenetics, Extracellular matrix

Abstract

Cells in the body reside within the extracellular matrix (ECM), a three-dimensional environment that not only provides structural support for the cells, but also influences cellular processes, like migration and differentiation. The ECM and the cells continuously engage in a complex and highly dynamic interplay, shaping both the matrix as well as the cellular outcome. To study these dynamic, bidirectional interactions in a systematic manner, the ability to dynamically control cellular environments is highly desirable. Stimuli-responsive materials are a class of materials that have been engineered to respond to external cues, e.g., light, electricity, or magnetic field, and therefore hold fascinating potentials as an ideal experimental platform to introduce changing spatiotemporal signals to cells. Here, we review the state of the art in stimuli-responsive materials and their design strategies, with an emphasis on the dynamic introduction of physical and mechanical cues. The effects of such dynamic stimuli on the responses of living cells are examined on three different levels: cellular phenotypes, intracellular and cytoskeletal changes, and nuclear and epigenetic effects. Finally, we discuss the current challenges and limitations as well as the potential outlooks in exploiting stimuli-responsive biomaterials.

Published

2022

5. Single-cell analysis reveals TLR-induced macrophage heterogeneity and quorum sensing dictate population wide anti-inflammatory feedback in response to LPS

Author

Tiemeijer, Bart M., Heester, Sebastiaan, Sturtewagen, Ashley Y.W., Smits, Anthal I.P.M., Tel, Jurjen, Immunoengineering, Biomedical Engineering, Soft Tissue Biomech. & Tissue Eng., and ICMS Core

Subjects

Tumor Necrosis Factor-alpha/metabolism, Macrophages, Immunology, Inflammation/metabolism, Quorum Sensing, macrophage, single-cell, Lipopolysaccharides/pharmacology, Anti-Inflammatory Agents/metabolism, Feedback, Interleukin-10/metabolism, IL-10, Immunology and Allergy, Humans, TLR4, heterogeneity, Single-Cell Analysis

Abstract

The role of macrophages in controlling tissue inflammation is indispensable to ensure a context-appropriate response to pathogens whilst preventing excessive tissue damage. Their initial response is largely characterized by high production of tumor necrosis factor alpha (TNFα) which primes and attracts other immune cells, thereafter, followed by production of interleukin 10 (IL-10) which inhibits cell activation and steers towards resolving of inflammation. This delicate balance is understood at a population level but how it is initiated at a single-cell level remains elusive. Here, we utilize our previously developed droplet approach to probe single-cell macrophage activation in response to toll-like receptor 4 (TLR4) stimulation, and how single-cell heterogeneity and cellular communication affect macrophage-mediated inflammatory homeostasis. We show that only a fraction of macrophages can produce IL-10 in addition to TNFα upon LPS-induced activation, and that these cells are not phenotypically different from IL-10 non-producers nor exhibit a distinct transcriptional pathway. Finally, we demonstrate that the dynamics of TNFα and IL-10 are heavily controlled by macrophage density as evidenced by 3D hydrogel cultures suggesting a potential role for quorum sensing. These exploratory results emphasize the relevance of understanding the complex communication between macrophages and other immune cells and how these amount to population-wide responses.

Published

2023

6. Imparting Immunomodulatory Activity to Scaffolds via Biotin-Avidin Interactions

Author

Victoria A. Nash, Hannah S Abee, Anthal I.P.M. Smits, Emily B. Lurier, Carlijn V. C. Bouten, Tamar B Wissing, Kara L. Spiller, Biomedical Engineering, Soft Tissue Biomech. & Tissue Eng., Cell-Matrix Interact. Cardiov. Tissue Reg., ICMS Affiliated, and ICMS Core

Subjects

Streptavidin, Scaffold, biology, Chemistry, macrophage polarization, Biomedical Engineering, Macrophage polarization, Biotin, Biocompatible Materials, Avidin, immunomodulation, interleukin 4, Cell biology, Biomaterials, chemistry.chemical_compound, In vivo, Biotinylation, Drug delivery, drug delivery, biology.protein, Humans, biotin-avidin

Abstract

Biotin-avidin interactions have been explored for decades as a technique to functionalize biomaterials, as well as for in vivo targeting, but whether changes in these interactions can be leveraged for immunomodulation remain unknown. The goal of this study was to investigate how biotin density and avidin variant can be used to deliver the immunomodulatory cytokine, interleukin 4 (IL4), from a porous gelatin scaffold, Gelfoam, to primary human macrophages in vitro. Here, we demonstrate that the degree of scaffold biotinylation controlled the binding of two different avidin variants, streptavidin and CaptAvidin. Biotinylated scaffolds were also loaded with streptavidin and biotinylated IL4 under flow, suggesting a potential use for targeting this biomaterial in vivo. While biotin-avidin interactions did not appear to influence the protein release in this system, increasing degrees of biotinylation did lead to increased M2-like polarization of primary human macrophages over time in vitro, highlighting the capability to leverage biotin-avidin interactions to modulate the macrophage phenotype. These results demonstrate a versatile and modular strategy to impart immunomodulatory activity to biomaterials.

Published

2021

7. Single‐Cell Profiling Reveals Functional Heterogeneity and Serial Killing in Human Peripheral and Ex Vivo‐Generated CD34+ Progenitor‐Derived Natural Killer Cells

Author

Nikita Subedi, Liesbeth Petronella Verhagen, Paul de Jonge, Laura C. Van Eyndhoven, Mark C. van Turnhout, Vera Koomen, Jean Baudry, Klaus Eyer, Harry Dolstra, Jurjen Tel, Immunoengineering, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., and ICMS Core

Subjects

Cultured, natural killer cells, Cells, Cytotoxicity, Cancer development and immune defence Radboud Institute for Molecular Life Sciences [Radboudumc 2], droplet-based microfluidics, Biomedical Engineering, Cell Differentiation, functional heterogeneity, SDG 3 – Goede gezondheid en welzijn, effector functions, General Biochemistry, Genetics and Molecular Biology, NK cell-based immunotherapy, Biomaterials, single cell studies, SDG 3 - Good Health and Well-being, Immunologic, Natural, Killer Cells, Humans, CD34, Antigens

Abstract

Increasing evidence suggests that natural killer (NK) cells are composed of distinct functional subsets. This multifunctional role has made them an attractive choice for anticancer immunotherapy. A functional NK cell repertoire is generated through cellular education, resulting in a heterogeneous NK cell population with distinct capabilities responding to different stimuli. The application of a high-throughput droplet-based microfluidic platform allows monitoring of NK cell-target cell interactions at the single-cell level and in real-time. A variable response of single NK cells toward different target cells is observed, and a distinct population of NK cells (serial killers) capable of inducing multiple target lysis is identified. By assessing the cytotoxic dynamics, it is shown that single umbilical cord blood-derived CD34+ hematopoietic progenitor (HPC)-NK cells display superior antitumor cytotoxicity. With an integrated analysis of cytotoxicity and cytokine secretion, it is shown that target cell interactions augment cytotoxic as well as secretory behavior of NK cells. By providing an integrated assessment of NK cell functions by microfluidics, this study paves the way to further functionally characterize NK cells ultimately aimed to improve cancer immunotherapy., Advanced Biology, 7 (4), ISSN:2701-0198

Published

2022

8. Inflammatory and regenerative processes in bioresorbable synthetic pulmonary valves up to two years in sheep–Spatiotemporal insights augmented by Raman microspectroscopy

Author

Martijn Cox, Aurelie Serrero, Eva-Maria Brauchle, Hannah Bauer, B.J. de Kort, Julia Marzi, Frederick J. Schoen, Sylvia Dekker, Katja Schenke-Layland, A.M. Lichauco, Anthal I.P.M. Smits, Carlijn V. C. Bouten, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., ICMS Affiliated, and ICMS Core

Subjects

Pathology, medicine.medical_specialty, Foreign-body giant cell, Biomedical Engineering, Inflammation, Biochemistry, Biomaterials, In situ tissue engineering, Tissue engineering, In vivo, Absorbable Implants, medicine, Animals, Foreign body response, Heart valve, Molecular Biology, Cells, Cultured, Pulmonary Valve, Sheep, Guided tissue regeneration, Tissue Engineering, business.industry, Regeneration (biology), Calcinosis, Aortic Valve Stenosis, General Medicine, Endogenous tissue restoration, Biomaterial, Heart Valves, Resorption, medicine.anatomical_structure, Aortic Valve, Heart Valve Prosthesis, Immunohistochemistry, medicine.symptom, business, Tissue-engineered heart valve (TEHV), Biotechnology

Abstract

In situ heart valve tissue engineering is an emerging approach in which resorbable, off-the-shelf available scaffolds are used to induce endogenous heart valve restoration. Such scaffolds are designed to recruit endogenous cells in vivo, which subsequently resorb polymer and produce and remodel new valvular tissue in situ. Recently, preclinical studies using electrospun supramolecular elastomeric valvular grafts have shown that this approach enables in situ regeneration of pulmonary valves with long-term functionality in vivo. However, the evolution and mechanisms of inflammation, polymer absorption and tissue regeneration are largely unknown, and adverse valve remodeling and intra- and inter-valvular variability have been reported. Therefore, the goal of the present study was to gain a mechanistic understanding of the in vivo regenerative processes by combining routine histology and immunohistochemistry, using a comprehensive sheep-specific antibody panel, with Raman microspectroscopy for the spatiotemporal analysis of in situ tissue-engineered pulmonary valves with follow-up to 24 months from a previous preclinical study in sheep. The analyses revealed a strong spatial heterogeneity in the influx of inflammatory cells, graft resorption, and foreign body giant cells. Collagen maturation occurred predominantly between 6 and 12 months after implantation, which was accompanied by a progressive switch to a more quiescent phenotype of infiltrating cells with properties of valvular interstitial cells. Variability among specimens in the extent of tissue remodeling was observed for follow-up times after 6 months. Taken together, these findings advance the understanding of key events and mechanisms in material-driven in situ heart valve tissue engineering. Statement of significance This study describes for the first time the long-term in vivo inflammatory and regenerative processes that underly in situ heart valve tissue engineering using resorbable synthetic scaffolds. Using a unique combinatorial analysis of immunohistochemistry and Raman microspectroscopy, important spatiotemporal variability in graft resorption and tissue formation was pinpointed in in situ tissue-engineered heart valves, with a follow-up time of up to 24 months in sheep. This variability was correlated to heterogenous regional cellular repopulation, most likely instigated by region-specific differences in surrounding tissue and hemodynamics. The findings of this research contribute to the mechanistic understanding of in situ tissue engineering using resorbable synthetics, which is necessary to enable rational design of improved grafts, and ensure safe and robust clinical translation.

Published

2021

9. An N-glycan on the C2 domain of JAGGED1 is important for Notch activation

Author

Yao Meng, Sami Sanlidag, Sacha A. Jensen, Sean A. Burnap, Weston B. Struwe, Andreas H. Larsen, Xinyi Feng, Shruti Mittal, Mark S. P. Sansom, Cecilia Sahlgren, Penny A. Handford, ICMS Affiliated, Cell-Matrix Interact. Cardiov. Tissue Reg., and Soft Tissue Biomech. & Tissue Eng.

Subjects

Calcium-Binding Proteins/genetics, Receptors, Notch/genetics, Glycoside Hydrolases, Receptors, Notch, Calcium-Binding Proteins, Membrane Proteins, Cell Biology, Ligands, Biochemistry, Lipids, Notch/genetics, Glycoside Hydrolases/metabolism, C2 Domains, Polysaccharides, Liposomes, Receptors, Humans, Polysaccharides/genetics, Membrane Proteins/genetics, Molecular Biology, Mannose, Jagged-1 Protein, Jagged-1 Protein/genetics

Abstract

The canonical members of the Jagged/Serrate and Delta families of transmembrane ligands have an extracellular, amino-terminal C2 domain that binds to phospholipids and is required for optimal activation of the Notch receptor. Somatic mutations that cause amino substitutions in the C2 domain in human JAGGED1 (JAG1) have been identified in tumors. We found in reporter cell assays that mutations affecting an N-glycosylation site reduced the ligand’s ability to activate Notch. This N-glycosylation site located in the C2 domain is conserved in the Jagged/Serrate family but is lacking in the Delta family. Site-specific glycan analysis of the JAG1 amino terminus demonstrated that occupancy of this site by either a complex-type or high-mannose N-glycan was required for full Notch activation in reporter cell assays. Similarly to JAG1 variants with defects in Notch binding, N-glycan removal, either by mutagenesis of the glycosylation site or by endoglycosidase treatment, reduced receptor activation. The N-glycan variants also reduced receptor activation in a Notch signaling–dependent vascular smooth muscle cell differentiation assay. Loss of the C2 N-glycan reduced JAG1 binding to liposomes to a similar extent as the loss of the entire C2 domain. Molecular dynamics simulations suggested that the presence of the N-glycan limits the orientation of JAG1 relative to the membrane, thus facilitating Notch binding. These data are consistent with a critical role for the N-glycan in promoting a lipid-binding conformation that is required to orient Jagged at the cell membrane for full Notch activation The canonical members of the Jagged/Serrate and Delta families of transmembrane ligands have an extracellular, amino-terminal C2 domain that binds to phospholipids and is required for optimal activation of the Notch receptor. Somatic mutations that cause amino substitutions in the C2 domain in human JAGGED1 (JAG1) have been identified in tumors. We found in reporter cell assays that mutations affecting an N-glycosylation site reduced the ligand’s ability to activate Notch. This N-glycosylation site located in the C2 domain is conserved in the Jagged/Serrate family but is lacking in the Delta family. Site-specific glycan analysis of the JAG1 amino terminus demonstrated that occupancy of this site by either a complex-type or high-mannose N-glycan was required for full Notch activation in reporter cell assays. Similarly to JAG1 variants with defects in Notch binding, N-glycan removal, either by mutagenesis of the glycosylation site or by endoglycosidase treatment, reduced receptor activation. The N-glycan variants also reduced receptor activation in a Notch signaling–dependent vascular smooth muscle cell differentiation assay. Loss of the C2 N-glycan reduced JAG1 binding to liposomes to a similar extent as the loss of the entire C2 domain. Molecular dynamics simulations suggested that the presence of the N-glycan limits the orientation of JAG1 relative to the membrane, thus facilitating Notch binding. These data are consistent with a critical role for the N-glycan in promoting a lipid-binding conformation that is required to orient Jagged at the cell membrane for full Notch activation.

Published

2022

10. The glycocalyx affects the mechanotransductive perception of the topographical microenvironment

Author

Chighizola, Matteo, Dini, Tania, Marcotti, Stefania, D'Urso, Mirko, Piazzoni, Claudio, Borghi, Francesca, Previdi, Anita, Ceriani, Laura, Folliero, Claudia, Stramer, Brian, Lenardi, Cristina, Milani, Paolo, Podestà, Alessandro, Schulte, Carsten, and Soft Tissue Biomech. & Tissue Eng.

Subjects

Integrins, Molecular clutch, Glycocalyx/physiology, Mechanotransduction, Integrin adhesion complexes, Nanotopography, Adhesion force spectroscopy, Nanostructured cell microenvironment, Colloidal probes, Glycocalyx, Mechanotransduction, Cellular, Actins, Focal adhesion, Atomic force microscopy, Force loading, Perception

Abstract

The cell/microenvironment interface is the starting point of integrin-mediated mechanotransduction, but many details of mechanotransductive signal integration remain elusive due to the complexity of the involved (extra)cellular structures, such as the glycocalyx. We used nano-bio-interfaces reproducing the complex nanotopographical features of the extracellular matrix to analyse the glycocalyx impact on PC12 cell mechanosensing at the nanoscale (e.g., by force spectroscopy with functionalised probes). Our data demonstrates that the glycocalyx configuration affects spatio-temporal nanotopography-sensitive mechanotransductive events at the cell/microenvironment interface. Opposing effects of major glycocalyx removal were observed, when comparing flat and specific nanotopographical conditions. The excessive retrograde actin flow speed and force loading are strongly reduced on certain nanotopographies upon strong reduction of the native glycocalyx, while on the flat substrate we observe the opposite trend. Our results highlight the importance of the glycocalyx configuration in a molecular clutch force loading-dependent cellular mechanism for mechanosensing of microenvironmental nanotopographical features.Graphical Abstract

Published

2022

11. 3D Human iPSC Blood Vessel Organoids as a Source of Flow-Adaptive Vascular Cells for Creating a Human-Relevant 3D-Scaffold Based Macrovessel Model

Author

Elana M. Meijer, Suzanne E. Koch, Christian G.M. van Dijk, Renee G.C. Maas, Ihsan Chrifi, Wojciech Szymczyk, Paul J. Besseling, Lisa Pomp, Vera J.C.H. Koomen, Jan Willem Buikema, Carlijn V.C. Bouten, Marianne C. Verhaar, Anthal I.P.M. Smits, Caroline Cheng, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., Biomedical Engineering, and Cardiology

Subjects

vasculature, Tissue Scaffolds, vascular graft, blood vessel organoids, graft perfusion, Induced Pluripotent Stem Cells, Biomedical Engineering, Endothelial Cells, SDG 3 – Goede gezondheid en welzijn, General Biochemistry, Genetics and Molecular Biology, Biomaterials, Organoids, SDG 3 - Good Health and Well-being, Tissue Engineering/methods, Humans

Abstract

3D-scaffold based in vitro human tissue models accelerate disease studies and screening of pharmaceutics while improving the clinical translation of findings. Here is reported the use of human induced pluripotent stem cell (hiPSC)-derived vascular organoid cells as a new cell source for the creation of an electrospun polycaprolactone-bisurea (PCL-BU) 3D-scaffold-based, perfused human macrovessel model. A separation protocol is developed to obtain monocultures of organoid-derived endothelial cells (ODECs) and mural cells (ODMCs) from hiPSC vascular organoids. Shear stress responses of ODECs versus HUVECs and barrier function (by trans endothelial electrical resistance) are measured. PCL-BU scaffolds are seeded with ODECs and ODMCs, and tissue organization and flow adaptation are evaluated in a perfused bioreactor system. ODECs and ODMCs harvested from vascular organoids can be cryopreserved and expanded without loss of cell purity and proliferative capacity. ODECs are shear stress responsive and establish a functional barrier that self-restores after the thrombin challenge. Static bioreactor culture of ODECs/ODMCs seeded scaffolds results in a biomimetic vascular bi-layer hierarchy, which is preserved under laminar flow similar to scaffolds seeded with primary vascular cells. HiPSC-derived vascular organoids can be used as a source of functional, flow-adaptive vascular cells for the creation of 3D-scaffold based human macrovascular models.

Published

2022

12. Inconsistency in graft outcome of bilayered bioresorbable supramolecular arterial scaffolds in rats

Author

Serge H. M. Söntjens, Anthal I.P.M. Smits, Carlijn V. C. Bouten, Sylvia Dekker, Andrea Di Luca, Eline E. van Haaften, Patricia Y. W. Dankers, Henk M. Janssen, Renee Duijvelshoff, Soft Tissue Biomech. & Tissue Eng., Cell-Matrix Interact. Cardiov. Tissue Reg., Macromolecular and Organic Chemistry, Biomedical Materials and Chemistry, ICMS Core, and ICMS Affiliated

Subjects

Male, Materials science, 0206 medical engineering, Biomedical Engineering, Bioengineering, 02 engineering and technology, bilayered polymeric scaffold, Biochemistry, Biomaterials, 03 medical and health sciences, Absorbable Implants, Animals, electrospinning, 030304 developmental biology, 0303 health sciences, Ideal (set theory), Tissue Engineering, Tissue Scaffolds, vascular graft, Regeneration (biology), fungi, technology, industry, and agriculture, in situ tissue engineering, Arteries, in situtissue engineering, 020601 biomedical engineering, Blood Vessel Prosthesis, Rats, Rats, Inbred Lew, regeneration, Vascular tissue engineering, Vascular graft, Biomedical engineering

Abstract

There is a continuous search for the ideal bioresorbable material to develop scaffolds for in situ vascular tissue engineering. As these scaffolds are exposed to the harsh hemodynamic environment during the entire transformation process from scaffold to neotissue, it is of crucial importance to maintain mechanical integrity and stability at all times. Bilayered scaffolds made of supramolecular polycarbonate-ester-bisurea were manufactured using dual electrospinning. These scaffolds contained a porous inner layer to allow for cellular infiltration and a dense outer layer to provide strength. Scaffolds (n = 21) were implanted as an interposition graft into the abdominal aorta of male Lewis rats and explanted after 1, 3, and 5 months in vivo to assess mechanical functionality and neotissue formation upon scaffold resorption. Results demonstrated conflicting graft outcomes despite homogeneity in the experimental group and scaffold production. Most grafts exhibited adverse remodeling, resulting in aneurysmal dilatation and calcification. However, a few grafts did not demonstrate such features, but instead were characterized by graft extension and smooth muscle cell proliferation in the absence of endothelium, while remaining patent throughout the study. We conclude that it remains extremely difficult to anticipate graft development and performance in vivo. Next to rational mechanical design and good performance in vitro, a thorough understanding of the mechanobiological mechanisms governing scaffold-driven arterial regeneration as well as potential influences of surgical procedures is warranted to further optimize scaffold designs. Careful analysis of the differences between preclinical successes and failures, as is done in this study, may provide initial handles for scaffold optimization and standardized surgical procedures to improve graft performance in vivo. In situ vascular tissue engineering using cell-free bioresorbable scaffolds is investigated as an off-the-shelf option to grow small caliber arteries inside the body. In this study, we developed a bilayered electrospun supramolecular scaffold with a dense outer layer to provide mechanical integrity and a porous inner layer for cell recruitment and tissue formation. Despite homogenous scaffold properties and mechanical performance in vitro, in vivo testing as rat aorta interposition grafts revealed distinct graft outcomes, ranging from aneurysms to functional arteries. Careful analysis of this variability provided valuable insights into materials-driven in situ artery formation relevant for scaffold design and implantation procedures.

Published

2021

13. Effectiveness of cell adhesive additives in different supramolecular polymers

Author

Muhabbat I. Komil, Bastiaan D. Ippel, Patricia Y. W. Dankers, Ronald C. van Gaal, Sergio Spaans, Soft Tissue Biomech. & Tissue Eng., Institute for Complex Molecular Systems, Biomedical Materials and Chemistry, and ICMS Core

Subjects

Materials science, Polymers and Plastics, Supramolecular chemistry, ureido‐pyrimidinone, 02 engineering and technology, 010402 general chemistry, Elastomer, 01 natural sciences, chemistry.chemical_compound, Materials Chemistry, Physical and Theoretical Chemistry, Research Articles, bis‐urea, supramolecular polymers, chemistry.chemical_classification, bis-urea, technology, industry, and agriculture, Biomaterial, Polymer, ureido-pyrimidinone, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Supramolecular polymers, Chemical engineering, chemistry, Polycaprolactone, Surface modification, Adhesive, 0210 nano-technology, bioactive additives, Research Article, biomaterials

Abstract

Supramolecular motifs in elastomeric biomaterials facilitate the modular incorporation of additives with corresponding motifs. The influence of the elastomeric supramolecular base polymer on the presentation of additives has been sparsely examined, limiting the knowledge of transferability of effective functionalization between polymers. Here it was investigated if the polymer backbone and the additive influence biomaterial modification in two different types of hydrogen bonding supramolecular systems, that is, based on ureido‐pyrimidinone or bis‐urea units. Two different cell‐adhesive additives, that is, catechol or cyclic RGD, were incorporated into different elastomeric polymers, that is, polycaprolactone, priplast or polycarbonate. The additive effectiveness was evaluated with three different cell types. AFM measurements showed modest alterations on nano‐scale assembly in ureido‐pyrimidinone materials modified with additives. On the contrary, additive addition was highly intrusive in bis‐urea materials. Detailed cell adhesive studies revealed additive effectiveness varied between base polymers and the supramolecular platform, with bis‐urea materials more potently affecting cell behavior. This research highlights that additive transposition might not always be as evident. Therefore, additive effectiveness requires re‐evaluation in supramolecular biomaterials when altering the polymer backbone to suit the biomaterial application., In this study, it is noted that the polymer backbone is of influence on the effective presentation of cell adhesive additives in supramolecular biomaterials. This was observed in both ureido‐pyrimidinone and bis‐urea based supramolecular systems and over different cell types.

Published

2021

14. Protein Micropatterning in 2.5D

Author

Hannah F.M. Brouwer, Patricia Y. W. Dankers, Maike Werner, Carlijn V. C. Bouten, Antonetta B.C. Buskermolen, Cas van der Putten, Nicholas A. Kurniawan, Paul A.A. Bartels, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., Biomedical Engineering, Biomedical Materials and Chemistry, ICMS Core, and ICMS Affiliated

Subjects

Umbilical Veins, Cell type, Stromal cell, Materials science, Surface Properties, extracellular matrix, Cell, Regulator, cellular orientation, Cell Communication, 02 engineering and technology, Extracellular matrix, 03 medical and health sciences, topography, Cell Movement, Cell Adhesion, medicine, Extracellular, 2.5D substrate, Humans, General Materials Science, Myofibroblasts, 030304 developmental biology, 0303 health sciences, Endothelial Cells, Proteins, Mesenchymal Stem Cells, 021001 nanoscience & nanotechnology, micropatterning, contact guidance, medicine.anatomical_structure, Cellular Microenvironment, Cell culture, curvature, Biophysics, 0210 nano-technology, Research Article, Micropatterning

Abstract

The extracellular microenvironment is an important regulator of cell functions. Numerous structural cues present in the cellular microenvironment, such as ligand distribution and substrate topography, have been shown to influence cell behavior. However, the roles of these cues are often studied individually using simplified, single-cue platforms that lack the complexity of the three-dimensional, multi-cue environment cells encounter in vivo. Developing ways to bridge this gap, while still allowing mechanistic investigation into the cellular response, represents a critical step to advance the field. Here, we present a new approach to address this need by combining optics-based protein patterning and lithography-based substrate microfabrication, which enables high-throughput investigation of complex cellular environments. Using a contactless and maskless UV-projection system, we created patterns of extracellular proteins (resembling contact-guidance cues) on a two-and-a-half-dimensional (2.5D) cell culture chip containing a library of well-defined microstructures (resembling topographical cues). As a first step, we optimized experimental parameters of the patterning protocol for the patterning of protein matrixes on planar and non-planar (2.5D cell culture chip) substrates and tested the technique with adherent cells (human bone marrow stromal cells). Next, we fine-tuned protein incubation conditions for two different vascular-derived human cell types (myofibroblasts and umbilical vein endothelial cells) and quantified the orientation response of these cells on the 2.5D, physiologically relevant multi-cue environments. On concave, patterned structures (curvatures between κ = 1/2500 and κ = 1/125 μm-1), both cell types predominantly oriented in the direction of the contact-guidance pattern. In contrast, for human myofibroblasts on micropatterned convex substrates with higher curvatures (κ ≥ 1/1000 μm-1), the majority of cells aligned along the longitudinal direction of the 2.5D features, indicating that these cells followed the structural cues from the substrate curvature instead. These findings exemplify the potential of this approach for systematic investigation of cellular responses to multiple microenvironmental cues.

Published

2021

15. 3D Interfacial and Spatiotemporal Regulation of Human Neuroepithelial Organoids

Author

Chunling Tang, Xinhui Wang, Mirko D'Urso, Cas van der Putten, Nicholas A. Kurniawan, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., and ICMS Affiliated

Subjects

Central Nervous System, General Chemical Engineering, dorsal–ventral patterning, Induced Pluripotent Stem Cells, General Engineering, General Physics and Astronomy, Medicine (miscellaneous), Cell Differentiation, Central Nervous System/metabolism, neuroepithelial organoid, Biochemistry, Genetics and Molecular Biology (miscellaneous), Organoids, Humans, General Materials Science, cellular self-organization, interfacial cues, neural tube

Abstract

Neuroepithelial (NE) organoids with dorsal-ventral patterning provide a useful three-dimensional (3D) in vitro model to interrogate neural tube formation during early development of the central nervous system. Understanding the fundamental processes behind the cellular self-organization in NE organoids holds the key to the engineering of organoids with higher, more in vivo-like complexity. However, little is known about the cellular regulation driving the NE development, especially in the presence of interfacial cues from the microenvironment. Here a simple 3D culture system that allows generation and manipulation of NE organoids from human-induced pluripotent stem cells (hiPSCs), displaying developmental phases of hiPSC differentiation and self-aggregation, first into NE cysts with lumen structure and then toward NE organoids with floor-plate patterning, is established. Longitudinal inhibition reveals distinct and dynamic roles of actomyosin contractility and yes-associated protein (YAP) signaling in governing these phases. By growing NE organoids on culture chips containing anisotropic surfaces or confining microniches, it is further demonstrated that interfacial cues can sensitively exert dimension-dependent influence on luminal cyst and organoid morphology, successful floor-plate patterning, as well as cytoskeletal regulation and YAP activity. This study therefore sheds new light on how organoid and tissue architecture can be steered through intracellular and extracellular means.

Published

2022

16. Donor Heterogeneity in the Human Macrophage Response to a Biomaterial under Hyperglycemia in vitro

Author

Suzanne E. Koch, Franka L.P. Verhaegh, Simone Smink, Silvia M. Mihăilă, Carlijn V.C. Bouten, Anthal I.P.M. Smits, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., and Biomedical Engineering

Subjects

diabetes, vascular graft, Macrophages, macrophage polarization, Biomedical Engineering, Medicine (miscellaneous), Biocompatible Materials, Bioengineering, scaffold, SDG 3 – Goede gezondheid en welzijn, Glucose/pharmacology, Glucose, SDG 3 - Good Health and Well-being, Hyperglycemia, tissue engineering, Humans, Tissue Engineering/methods, Biocompatible Materials/pharmacology, Hyperglycemia/metabolism

Abstract

Macrophages have a commanding role in scaffold-driven in situ tissue regeneration. Depending on their polarization state, macrophages mediate the formation and remodeling of new tissue by secreting growth factors and cytokines. Therefore, successful outcomes of material-driven in situ tissue vascular tissue engineering depend largely on the immuno-regenerative potential of the recipient. A large cohort of patients requiring vascular replacements suffers from systemic multifactorial diseases, such as diabetes, which gives rise to a hyperglycemic and aggressive oxidative inflammatory environment that is hypothesized to hamper a well-balanced regenerative process. Here, we aimed at fundamentally exploring the effects of hyperglycemia, as one of the hallmarks of diabetes, on the macrophage response to three-dimensional (3D) electrospun synthetic biomaterials for in situ tissue engineering, in terms of inflammatory profile and tissue regenerative capacity. To simulate the early phases of the in situ regenerative cascade, we used a bottom-up in vitro approach. Primary human macrophages (n = 8 donors) were seeded in two-dimensional (2D) culture wells and polarized to pro-inflammatory M1 and anti-inflammatory M2 phenotype in normoglycemic (5.5 mM glucose), hyperglycemic (25 mM), and osmotic control (OC) conditions (5.5 mM glucose, 19.5 mM mannitol). Unpolarized macrophages and (myo)fibroblasts were seeded in mono-or co-culture in a 3D electrospun resorbable polycaprolactone bisurea scaffold and exposed to normoglycemic, hyperglycemic, and OC conditions. The results showed that macrophage polarization by biochemical stimuli was effective under all glycemic conditions and that the polarization states dictated expression of the receptors SCL2A1 (glucose transporter 1) and CD36 (fatty acid transporter). In 3D, the macrophage response to hyperglycemic conditions was strongly donor-dependent in terms of phenotype, cytokine secretion profile, and metabolic receptor expression. When co-cultured with (myo)fibroblasts, hyperglycemic conditions led to an increased expression of fibrogenic markers (ACTA2, COL1, COL3, IL-1β). Together, these findings show that the hyperglycemic and hyperosmotic conditions may, indeed, influence the process of macrophage-driven in situ tissue engineering, and that the extent of this is likely to be patient-specific. Success or failure of cell-free bioresorbable in situ tissue-engineered vascular grafts hinges around the immuno-regenerative response of the recipient. Most patients requiring blood vessel replacements suffer from additional multifactorial diseases, such as diabetes, which may compromise their intrinsic regenerative potential. In this study, we used a bottom-up approach to study the effects of hyperglycemia, a hallmark of diabetes, on important phases in the in situ regenerative cascade, such as macrophage polarization and macrophage-myofibroblast crosstalk. The results demonstrate a relatively large donor-to-donor variation, which stresses the importance of taking scaffold-independent patient-specific factors into account when studying in situ biomaterial-driven tissue engineering.

Published

2022

17. Generation of Multicue Cellular Microenvironments by UV-Photopatterning of Three-Dimensional Cell Culture Substrates

Author

Nicholas A. Kurniawan, Carlijn V. C. Bouten, Thomas E. Woud, Maaike Bril, Mirko D’Urso, Cas van der Putten, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., Biomedical Engineering, and ICMS Affiliated

Subjects

Cellular Microenvironment, General Immunology and Microbiology, Polymers/metabolism, Polymers, General Chemical Engineering, General Neuroscience, Cell Culture Techniques, Cell Culture Techniques/methods, Microtechnology, Extracellular Matrix/metabolism, General Biochemistry, Genetics and Molecular Biology, Extracellular Matrix

Abstract

The extracellular matrix is an important regulator of cell function. Environmental cues existing in the cellular microenvironment, such as ligand distribution and tissue geometry, have been increasingly shown to play critical roles in governing cell phenotype and behavior. However, these environmental cues and their effects on cells are often studied separately using in vitro platforms that isolate individual cues, a strategy that heavily oversimplifies the complex in vivo situation of multiple cues. Engineering approaches can be particularly useful to bridge this gap, by developing experimental setups that capture the complexity of the in vivo microenvironment, yet retain the degree of precision and manipulability of in vitro systems. This study highlights an approach combining ultraviolet (UV)-based protein patterning and lithography-based substrate microfabrication, which together enable high-throughput investigation into cell behaviors in multicue environments. By means of maskless UV-photopatterning, it is possible to create complex, adhesive protein distributions on three-dimensional (3D) cell culture substrates on chips that contain a variety of well-defined geometrical cues. The proposed technique can be employed for culture substrates made from different polymeric materials and combined with adhesive patterned areas of a broad range of proteins. With this approach, single cells, as well as monolayers, can be subjected to combinations of geometrical cues and contact guidance cues presented by the patterned substrates. Systematic research using combinations of chip materials, protein patterns, and cell types can thus provide fundamental insights into cellular responses to multicue environments.

Published

2022

18. In VitroMethods to Model Cardiac Mechanobiology in Health and Disease

Author

Leon H.L. Hermans, Ignasi Jorba, Nicholas A. Kurniawan, Atze van der Pol, Dylan Mostert, Carlijn V. C. Bouten, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., ICMS Core, and ICMS Affiliated

Subjects

Experimental control, Cell type, cardiac in vitro models, multiscale cardiac mechanical properties, Induced Pluripotent Stem Cells, 0206 medical engineering, Biophysics, Biomedical Engineering, Reviews, Medicine (miscellaneous), Bioengineering, 02 engineering and technology, Disease, Biology, SDG 3 – Goede gezondheid en welzijn, 03 medical and health sciences, Mechanobiology, SDG 3 - Good Health and Well-being, Tissue engineering, Humans, Induced pluripotent stem cell, in vitro models, 030304 developmental biology, 0303 health sciences, Tissue Engineering, cardiac (patho)physiology, Heart, Hydrogels, mechanobiology, 020601 biomedical engineering, In vitro, engineered heart tissue, Neuroscience, Function (biology)

Abstract

In vitro cardiac modeling has taken great strides in the past decade. While most cell and engineered tissue models have focused on cell and tissue contractile function as readouts, mechanobiological cues from the cell environment that affect this function, such as matrix stiffness or organization, are less well explored. In this study, we review two-dimensional (2D) and three-dimensional (3D) models of cardiac function that allow for systematic manipulation or precise control of mechanobiological cues under simulated (patho)physiological conditions while acquiring multiple readouts of cell and tissue function. We summarize the cell types used in these models and highlight the importance of linking 2D and 3D models to address the multiscale organization and mechanical behavior. Finally, we provide directions on how to advance in vitro modeling for cardiac mechanobiology using next generation hydrogels that mimic mechanical and structural environmental features at different length scales and diseased cell types, along with the development of new tissue fabrication and readout techniques. Impact statement Understanding the impact of mechanobiology in cardiac (patho)physiology is essential for developing effective tissue regeneration and drug discovery strategies and requires detailed cause-effect studies. The development of three-dimensional in vitro models allows for such studies with high experimental control, while integrating knowledge from complementary cell culture models and in vivo studies for this purpose. Complemented by the use of human-induced pluripotent stem cells, with or without predisposed genetic diseases, these in vitro models will offer promising outlooks to delineate the impact of mechanobiological cues on human cardiac (patho)physiology in a dish.

Published

2021

19. Engineered patterns of Notch ligands Jag1 and Dll4 elicit differential spatial control of endothelial sprouting

Author

Laura A. Tiemeijer, Tommaso Ristori, Oscar M.J. A. Stassen, Jaakko J. Ahlberg, Jonne J.J. de Bijl, Christopher S. Chen, Katie Bentley, Carlijn V.C. Bouten, Cecilia M. Sahlgren, Soft Tissue Biomech. & Tissue Eng., ICMS Affiliated, Cell-Matrix Interact. Cardiov. Tissue Reg., and Biomedical Engineering

Subjects

Chemical Biology & High Throughput, Biological sciences, Multidisciplinary, Developmental biology, cardiovascular system, Bioengineering, Tissue engineering, Cell Biology, Imaging

Abstract

Spatial regulation of angiogenesis is important for the generation of functional engineered vasculature in regenerative medicine. The Notch ligands Jag1 and Dll4 show distinct expression patterns in endothelial cells and, respectively, promote and inhibit endothelial sprouting. Therefore, patterns of Notch ligands may be utilized to spatially control sprouting, but their potential and the underlying mechanisms of action are unclear. Here, we coupled in vitro and in silico models to analyze the ability of micropatterned Jag1 and Dll4 ligands to spatially control endothelial sprouting. Dll4 patterns, but not Jag1 patterns, elicited spatial control. Computational simulations of the underlying signaling dynamics suggest that different timing of Notch activation by Jag1 and Dll4 underlie their distinct ability to spatially control sprouting. Hence, Dll4 patterns efficiently direct the sprouts, whereas longer exposure to Jag1 patterns is required to achieve spatial control. These insights in sprouting regulation offer therapeutic handles for spatial regulation of angiogenesis.

Published

2022

20. Optogenetic control of NOTCH1 signaling

Author

Alicja Przybyszewska-Podstawka, Joanna Kałafut, Cecilia Sahlgren, Arkadiusz Czerwonka, Adolfo Rivero-Müller, Jakub Czapiński, Adrian Odrzywolski, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., and ICMS Affiliated

Subjects

Light-activation, Tumor, Breast Neoplasms, Cell Biology, SDG 3 – Goede gezondheid en welzijn, Biochemistry, Cell Line, Optogenetics, Breast cancer, NOTCH1, SDG 3 - Good Health and Well-being, Receptor, Notch1/metabolism, Breast Neoplasms/metabolism, Cell Line, Tumor, MCF-7 Cells, Humans, Female, Notch1/metabolism, Receptor, Notch1, Molecular Biology, Notch signaling, Cell Proliferation, Signal Transduction, Receptor

Abstract

The Notch signaling pathway is a crucial regulator of cell differentiation as well as tissue organization, whose deregulation is linked to the pathogenesis of different diseases. NOTCH1 plays a key role in breast cancer progression by increasing proliferation, maintenance of cancer stem cells, and impairment of cell death. NOTCH1 is a mechanosensitive receptor, where mechanical force is required to activate the proteolytic cleavage and release of the Notch intracellular domain (NICD). We circumvent this limitation by regulating Notch activity by light. To achieve this, we have engineered an optogenetic NOTCH1 receptor (optoNotch) to control the activation of NOTCH1 intracellular domain (N1ICD) and its downstream transcriptional activities. Using optoNotch we confirm that NOTCH1 activation increases cell proliferation in MCF7 and MDA-MB-468 breast cancer cells in 2D and spheroid 3D cultures, although causing distinct cell-type specific migratory phenotypes. Additionally, optoNotch activation induced chemoresistance on the same cell lines. OptoNotch allows the fine-tuning, ligand-independent, regulation of N1ICD activity and thus a better understanding of the spatiotemporal complexity of Notch signaling.

Published

2022

21. Marker-Independent Monitoring of in vitro and in vivo Degradation of Supramolecular Polymers Applied in Cardiovascular in situ Tissue Engineering

Author

Marzi, Julia, Munnig Schmidt, Emma C., Brauchle, Eva M., Wissing, Tamar B., Bauer, Hannah, Serrero, Aurelie, Söntjens, Serge H.M., Bosman, Anton W., Cox, Martijn A.J., Smits, Anthal I.P.M., Schenke-Layland, Katja, Biomedical Engineering, Soft Tissue Biomech. & Tissue Eng., Macromolecular and Organic Chemistry, and Macro-Organic Chemistry

Subjects

guided tissue engineering, carotid implantation, Raman imaging, resorption, tissue-engineered vascular grafts (TEVG)

Abstract

The equilibrium between scaffold degradation and neotissue formation, is highly essential for in situ tissue engineering. Herein, biodegradable grafts function as temporal roadmap to guide regeneration. The ability to monitor and understand the dynamics of degradation and tissue deposition in in situ cardiovascular graft materials is therefore of great value to accelerate the implementation of safe and sustainable tissue-engineered vascular grafts (TEVGs) as a substitute for conventional prosthetic grafts. In this study, we investigated the potential of Raman microspectroscopy and Raman imaging to monitor degradation kinetics of supramolecular polymers, which are employed as degradable scaffolds in in situ tissue engineering. Raman imaging was applied on in vitro degraded polymers, investigating two different polymer materials, subjected to oxidative and enzymatically-induced degradation. Furthermore, the method was transferred to analyze in vivo degradation of tissue-engineered carotid grafts after 6 and 12 months in a sheep model. Multivariate data analysis allowed to trace degradation and to compare the data from in vitro and in vivo degradation, indicating similar molecular observations in spectral signatures between implants and oxidative in vitro degradation. In vivo degradation appeared to be dominated by oxidative pathways. Furthermore, information on collagen deposition and composition could simultaneously be obtained from the same image scans. Our results demonstrate the sensitivity of Raman microspectroscopy to determine degradation stages and the assigned molecular changes non-destructively, encouraging future exploration of this techniques for time-resolved quality assessment of in situ tissue engineering processes.

Published

2022

22. Myofibroblast transdifferentiation of keratocytes results in slower migration and lower sensitivity to mesoscale curvatures

Author

van der Putten, Cas, van den Broek, Daniëlle, Kurniawan, Nicholas A., Cell-Matrix Interact. Cardiov. Tissue Reg., Self-Organizing Soft Matter, Soft Tissue Biomech. & Tissue Eng., and ICMS Affiliated

Subjects

stress fibers, cell migration, corneal keratocyte, myofibroblast transdifferentiation, substrate curvature, Cell Biology, Developmental Biology

Abstract

Functional tissue repair after injury or disease is governed by the regenerative or fibrotic response by cells within the tissue. In the case of corneal damage, keratocytes are a key cell type that determine the outcome of the remodeling response by either adapting to a fibroblast or myofibroblast phenotype. Although a growing body of literature indicates that geometrical cues in the environment can influence Myo(fibroblast) phenotype, there is a lack of knowledge on whether and how differentiated keratocyte phenotype is affected by the curved tissue geometry in the cornea. To address this gap, in this study we characterized the phenotype of fibroblastic and transforming growth factor β (TGFβ)-induced myofibroblastic keratocytes and studied their migration behavior on curved culture substrates with varying curvatures. Immunofluorescence staining and quantification of cell morphological parameters showed that, generally, fibroblastic keratocytes were more likely to elongate, whereas myofibroblastic keratocytes expressed more pronounced α smooth muscle actin (α-SMA) and actin stress fibers as well as more mature focal adhesions. Interestingly, keratocyte adhesion on convex structures was weak and unstable, whereas they adhered normally on flat and concave structures. On concave cylinders, fibroblastic keratocytes migrated faster and with higher persistence along the longitudinal direction compared to myofibroblastic keratocytes. Moreover, this behavior became more pronounced on smaller cylinders (i.e., higher curvatures). Taken together, both keratocyte phenotypes can sense and respond to the sign and magnitude of substrate curvatures, however, myofibroblastic keratocytes exhibit weaker curvature sensing and slower migration on curved substrates compared to fibroblastic keratocytes. These findings provide fundamental insights into keratocyte phenotype after injury, but also exemplify the potential of tuning the physical cell environments in tissue engineering settings to steer towards a favorable regeneration response.

Published

2022

23. Tissue-engineered collagenous fibrous cap models to systematically elucidate atherosclerotic plaque rupture

Author

T.B. Wissing, K. Van der Heiden, S.M. Serra, A.I.P.M. Smits, C.V.C. Bouten, F.J.H. Gijsen, Soft Tissue Biomech. & Tissue Eng., Cell-Matrix Interact. Cardiov. Tissue Reg., Cardiovascular Biomechanics, and Cardiology

Subjects

Multidisciplinary, Humans, Collagen, Fibrosis, Plaque, Atherosclerotic, Plaque, Atherosclerotic

Abstract

A significant amount of vascular thrombotic events is associated with rupture of the fibrous cap that overlie atherosclerotic plaques. Cap rupture is however difficult to predict due to the heterogenous composition of the plaque, unknown material properties, and the stochastic nature of the event. Here, we aim to create tissue engineered human fibrous cap models with a variable but controllable collagen composition, suitable for mechanical testing, to scrutinize the reciprocal relationships between composition and mechanical properties.Myofibroblasts were cultured in 1 × 1.5 cm-sized fibrin-based constrained gels for 21 days according to established (dynamic) culture protocols (i.e. static, intermittent or continuous loading) to vary collagen composition (e.g. amount, type and organization). At day 7, a soft 2 mm Ø fibrin inclusion was introduced in the centre of each tissue to mimic the soft lipid core, simulating the heterogeneity of a plaque.Results demonstrate reproducible collagenous tissues, that mimic the bulk mechanical properties of human caps and vary in collagen composition due to the presence of an successfully integrated soft inclusion and the culture protocol applied. The models can be deployed to assess tissue mechanics, evolution and failure of fibrous caps or complex heterogeneous tissues in general.

Published

2022

24. In Situ Vascular Tissue Engineering: methods, models, and mechanisms

Author

Koch, Suzanne Ellen, Bouten, Carlijn V.C., Smits, Anthal I.P.M., Cell-Matrix Interact. Cardiov. Tissue Reg., and Soft Tissue Biomech. & Tissue Eng.

Published

2022

25. In-vitro engineered human cerebral tissues mimic pathological circuit disturbances in 3D

Author

Aref Saberi, Albert P. Aldenkamp, Nicholas A. Kurniawan, Carlijn V. C. Bouten, Cell-Matrix Interact. Cardiov. Tissue Reg., Signal Processing Systems, Soft Tissue Biomech. & Tissue Eng., ICMS Core, EAISI Health, ICMS Affiliated, RS: MHeNs - R1 - Cognitive Neuropsychiatry and Clinical Neuroscience, and Klinische Neurowetenschappen

Subjects

MODEL, HUMAN BRAIN-DEVELOPMENT, Medicine (miscellaneous), CORTICAL DEVELOPMENT, General Agricultural and Biological Sciences, PLURIPOTENT STEM-CELLS, General Biochemistry, Genetics and Molecular Biology, NETWORKS

Abstract

A method is developed to engineer cerebral tissues with intact 3D neuronal networks, mimicking neuropathological signatures such as the propagation of epileptiform discharges, using a multi-chambered tissue culture chip.In-vitro modeling of brain network disorders such as epilepsy remains a major challenge. A critical step is to develop an experimental approach that enables recapitulation of in-vivo-like three-dimensional functional complexity while allowing local modulation of the neuronal networks. Here, by promoting matrix-supported active cell reaggregation, we engineered multiregional cerebral tissues with intact 3D neuronal networks and functional interconnectivity characteristic of brain networks. Furthermore, using a multi-chambered tissue-culture chip, we show that our separated but interconnected cerebral tissues can mimic neuropathological signatures such as the propagation of epileptiform discharges.

Published

2022

26. GIT1 protects against breast cancer growth through negative regulation of Notch

Author

Songbai Zhang, Ayako Miyakawa, Malin Wickström, Cecilia Dyberg, Lauri Louhivuori, Manuel Varas-Godoy, Kati Kemppainen, Shigeaki Kanatani, Dagmara Kaczynska, Ivar Dehnisch Ellström, Lotta Elfman, Pauliina Kronqvist, Heli Repo, Katsuhiko Mikoshiba, Cecilia Sahlgren, John Inge Johnsen, Per Uhlén, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., and ICMS Affiliated

Subjects

Multidisciplinary, Receptors, Notch, General Physics and Astronomy, Breast Neoplasms, Cell Cycle Proteins, General Chemistry, SDG 3 – Goede gezondheid en welzijn, General Biochemistry, Genetics and Molecular Biology, SDG 3 - Good Health and Well-being, Humans, Female, Breast, Neoplasm Recurrence, Local, Adaptor Proteins, Signal Transducing, Signal Transduction

Abstract

Hyperactive Notch signalling is frequently observed in breast cancer and correlates with poor prognosis. However, relatively few mutations in the core Notch signalling pathway have been identified in breast cancer, suggesting that as yet unknown mechanisms increase Notch activity. Here we show that increased expression levels of GIT1 correlate with high relapse-free survival in oestrogen receptor-negative (ER(-)) breast cancer patients and that GIT1 mediates negative regulation of Notch. GIT1 knockdown in ER(-) breast tumour cells increased signalling downstream of Notch and activity of aldehyde dehydrogenase, a predictor of poor clinical outcome. GIT1 interacts with the Notch intracellular domain (ICD) and influences signalling by inhibiting the cytoplasm-to-nucleus transport of the Notch ICD. In xenograft experiments, overexpression of GIT1 in ER(-) cells prevented or reduced Notch-driven tumour formation. These results identify GIT1 as a modulator of Notch signalling and a guardian against breast cancer growth.

Published

2022

27. Impact of Additives on Mechanical Properties of Supramolecular Electrospun Scaffolds

Author

Carlijn V. C. Bouten, Bastiaan D. Ippel, Eline E. van Haaften, Patricia Y. W. Dankers, Soft Tissue Biomech. & Tissue Eng., Cell-Matrix Interact. Cardiov. Tissue Reg., Biomedical Materials and Chemistry, and ICMS Core

Subjects

Letter, Materials science, Polymers and Plastics, Process Chemistry and Technology, Organic Chemistry, Supramolecular chemistry, technology, industry, and agriculture, Nanotechnology, macromolecular substances, supramolecular chemistry, Electrospinning, multiscale, Robustness (computer science), Surface modification, additives, electrospinning, mechanics, biomaterials

Abstract

The mechanical properties of scaffolds used for mechanically challenging applications such as cardiovascular implants are unequivocally important. Here, the effect of supramolecular additive functionalization on mechanical behavior of electrospun scaffolds was investigated for one bisurea-based model additive and two previously developed antifouling additives. The model additive has no effect on the mechanical properties of the bulk material, whereas the stiffness of electrospun scaffolds was slightly decreased compared to pristine PCL-BU following the addition of the three different additives. These results show the robustness of supramolecular additives used in biomedical applications, in which mechanical properties are important, such as vascular grafts and heart valve constructs.

Published

2020

28. An artificial aquatic polyp that wirelessly attracts, grasps, and releases objects

Author

Harkamaljot S. Kandail, Jaap M.J. den Toonder, Albert P. H. J. Schenning, Marina Pilz da Cunha, Stimuli-responsive Funct. Materials & Dev., Soft Tissue Biomech. & Tissue Eng., Group Den Toonder, Microsystems, Institute for Complex Molecular Systems, ICMS Core, and EIRES Chem. for Sustainable Energy Systems

Subjects

soft robotics, Multidisciplinary, Computer science, Real-time computing, light-responsive polymers, Soft robotics, technology, industry, and agriculture, SDG 14 – Leven onder water, magnetic responsive polymers, QA76, Chemistry, TA, On demand, Physical Sciences, Robot, Slow response, SDG 14 - Life Below Water, TJ

Abstract

Significance Wirelessly controlled, multitasking soft devices active in aqueous environments are highly required for applications in microfluidics and organ-on-a-chip and as medical devices. Inspired by marine organisms, we present an approach to achieve such devices by utilizing stimuli-responsive material assemblies capable of untethered object manipulation in an enclosed aqueous environment. Our soft robot assembly integrates a magnetically controlled stem with a light-responsive gripper with unmatched speed, insensitivity to contaminants, and high control of actuation underwater at low light intensities. The independent device segments can be orthogonally controlled to realize different tasks such as attracting, capturing, and releasing targets in an aqueous environment, demonstrating the significance of actuator assemblies in the fabrication of multifunctional soft devices operating underwater., The development of light-responsive materials has captured scientific attention and advanced the development of wirelessly driven terrestrial soft robots. Marine organisms trigger inspiration to expand the paradigm of untethered soft robotics into aqueous environments. However, this expansion toward aquatic soft robots is hampered by the slow response of most light-driven polymers to low light intensities and by the lack of controlled multishape deformations. Herein, we present a surface-anchored artificial aquatic coral polyp composed of a magnetically driven stem and a light-driven gripper. Through magnetically driven motion, the polyp induces stirring and attracts suspended targets. The light-responsive gripper is sensitive to low light intensities and has programmable states and rapid and highly controlled actuation, allowing the polyp to capture or release targets on demand. The artificial polyp demonstrates that assemblies of stimuli-responsive materials in water utilizing coordinated motion can perform tasks not possible for single-component devices.

Published

2020

29. Hemodynamic loads distinctively impact the secretory profile of biomaterial-activated macrophages – implications for in situ vascular tissue engineering

Author

Suzanne E Koch, Nicholas A. Kurniawan, Carlijn V. C. Bouten, Tamar B Wissing, Bastiaan D. Ippel, Anthal I.P.M. Smits, Eline E. van Haaften, Soft Tissue Biomech. & Tissue Eng., Cell-Matrix Interact. Cardiov. Tissue Reg., Biomedical Materials and Chemistry, ICMS Affiliated, and ICMS Core

Subjects

THP-1 Cells, Polyesters, Biomedical Engineering, Macrophage polarization, Biocompatible Materials, 02 engineering and technology, Cell Line, 03 medical and health sciences, Paracrine signalling, Tissue engineering, Downregulation and upregulation, Humans, Macrophage, General Materials Science, Myofibroblasts, 030304 developmental biology, 0303 health sciences, Tissue Engineering, Tissue Scaffolds, Chemistry, Macrophages, Regeneration (biology), Hemodynamics, Biomaterial, Macrophage Activation, 021001 nanoscience & nanotechnology, Cell biology, Cell culture, Stress, Mechanical, 0210 nano-technology

Abstract

Biomaterials are increasingly used for in situ vascular tissue engineering, wherein resorbable fibrous scaffolds are implanted as temporary carriers to locally initiate vascular regeneration. Upon implantation, macrophages infiltrate and start degrading the scaffold, while simultaneously driving a healing cascade via the secretion of paracrine factors that direct the behavior of tissue-producing cells. This balance between neotissue formation and scaffold degradation must be maintained at all times to ensure graft functionality. However, the grafts are continuously exposed to hemodynamic loads, which can influence macrophage response in a hitherto unknown manner and thereby tilt this delicate balance. Here we aimed to unravel the effects of physiological levels of shear stress and cyclic stretch on biomaterial-activated macrophages, in terms of polarization, scaffold degradation and paracrine signaling to tissue-producing cells (i.e. (myo)fibroblasts). Human THP-1-derived macrophages were seeded in electrospun polycaprolactone bis-urea scaffolds and exposed to shear stress (∼1 Pa), cyclic stretch (∼1.04), or a combination thereof for 8 days. The results showed that macrophage polarization distinctly depended on the specific loading regime applied. In particular, hemodynamic loading decreased macrophage degradative activity, especially in conditions of cyclic stretch. Macrophage activation was enhanced upon exposure to shear stress, as evidenced from the upregulation of both pro- and anti-inflammatory cytokines. Exposure to the supernatant of these dynamically cultured macrophages was found to amplify the expression of tissue formation- and remodeling-related genes in (myo)fibroblasts statically cultured in comparable electrospun scaffolds. These results emphasize the importance of macrophage mechano-responsiveness in biomaterial-driven vascular regeneration.

Published

2020

30. Scaffold Geometry-Imposed Anisotropic Mechanical Loading Guides the Evolution of the Mechanical State of Engineered Cardiovascular Tissues in vitro

Author

L. H. L. Hermans, M. A. J. Van Kelle, P. J. A. Oomen, R .G. P. Lopata, S. Loerakker, C. V. C. Bouten, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., Photoacoustics & Ultrasound Laboratory Ehv, Modeling in Mechanobiology, ICMS Affiliated, and ICMS Core

Subjects

Histology, cardiovascular, growth, tissue engineering, scaffold geometry, Biomedical Engineering, Bioengineering, TP248.13-248.65, remodeling, Biotechnology

Abstract

Cardiovascular tissue engineering is a promising approach to develop grafts that, in contrast to current replacement grafts, have the capacity to grow and remodel like native tissues. This approach largely depends on cell-driven tissue growth and remodeling, which are highly complex processes that are difficult to control inside the scaffolds used for tissue engineering. For several tissue engineering approaches, adverse tissue growth and remodeling outcomes were reported, such as aneurysm formation in vascular grafts, and leaflet retraction in heart valve grafts. It is increasingly recognized that the outcome of tissue growth and remodeling, either physiological or pathological, depends at least partly on the establishment of a homeostatic mechanical state, where one or more mechanical quantities in a tissue are maintained in equilibrium. To design long-term functioning tissue engineering strategies, understanding how scaffold parameters such as geometry affect the mechanical state of a construct, and how this state guides tissue growth and remodeling, is therefore crucial. Here, we studied how anisotropic versus isotropic mechanical loading—as imposed by initial scaffold geometry—influences tissue growth, remodeling, and the evolution of the mechanical state and geometry of tissue-engineered cardiovascular constructs in vitro. Using a custom-built bioreactor platform and nondestructive mechanical testing, we monitored the mechanical and geometric changes of elliptical and circular, vascular cell-seeded, polycaprolactone-bisurea scaffolds during 14 days of dynamic loading. The elliptical and circular scaffold geometries were designed using finite element analysis, to induce anisotropic and isotropic dynamic loading, respectively, with similar maximum stretch when cultured in the bioreactor platform. We found that the initial scaffold geometry-induced (an)isotropic loading of the engineered constructs differentially dictated the evolution of their mechanical state and geometry over time, as well as their final structural organization. These findings demonstrate that controlling the initial mechanical state of tissue-engineered constructs via scaffold geometry can be used to influence tissue growth and remodeling and determine tissue outcomes.

Published

2022

31. Editorial: Vascular and valvular tissue engineering: Treating and modeling vasculopathies and valvulopathies

Author

Anthal I. P. M. Smits, Laura Iop, Adrian H. Chester, Immunoengineering, and Soft Tissue Biomech. & Tissue Eng.

Subjects

biocompatibility, SDG 3 - Good Health and Well-being, cardiovascular disease, in vitro disease model, heart valve replacement, tissue engineering and regenerative medicine, cardiovascular development, SDG 3 – Goede gezondheid en welzijn, Cardiology and Cardiovascular Medicine, biomaterials, bioprosthetic heart valve

Published

2022

32. Substrate Stiffness Determines the Establishment of Apical-Basal Polarization in Renal Epithelial Cells but Not in Tubuloid-Derived Cells

Author

Hagelaars, Maria J., Yousef Yengej, Fjodor A., Verhaar, Marianne C., Rookmaaker, Maarten B., Loerakker, Sandra, Bouten, Carlijn V. C., Modeling in Mechanobiology, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., ICMS Affiliated, and ICMS Core

Subjects

Histology, SDG 3 - Good Health and Well-being, Biomedical Engineering, Bioengineering, SDG 3 – Goede gezondheid en welzijn, Biotechnology

Abstract

Mechanical guidance of tissue morphogenesis is an emerging method of regenerative medicine that can be employed to steer functional kidney architecture for the purpose of bioartificial kidney design or renal tissue engineering strategies. In kidney morphogenesis, apical-basal polarization of renal epithelial cells is paramount for tubule formation and subsequent tissue functions like excretion and resorption. In kidney epithelium, polarization is initiated by integrin-mediated cell-matrix adhesion at the cell membrane. Cellular mechanobiology research has indicated that this integrin-mediated adhesion is responsive to matrix stiffness, raising the possibility to use matrix stiffness as a handle to steer cell polarization. Herein, we evaluate apical-basal polarization in response to 2D substates of different stiffness (1, 10, 50 kPa and glass) in Madin Darby Canine Kidney cells (MDCKs), a classic canine-derived cell model of epithelial polarization, and in tubuloid-derived cells, established from human primary cells derived from adult kidney tissue. Our results show that sub-physiological (1 kPa) substrate stiffness with low integrin-based adhesion induces polarization in MDCKs, while MDCKs on supraphysiological (>10 kPa) stiffness remain unpolarized. Inhibition of integrin, indeed, allows for polarization on the supraphysiological substrates, suggesting that increased cellular adhesion on stiff substrates opposes polarization. In contrast, tubuloid-derived cells do not establish apical-basal polarization on 2D substrates, irrespective of substrate stiffness, despite their ability to polarize in 3D environments. Further analysis implies that the 2D cultured tubuloid-derived cells have a diminished mechanosensitive capacity when presented with different substrate stiffnesses due to immature focal adhesions and the absence of a connection between focal adhesions and the cytoskeleton. Overall, this study demonstrates that apical-basal polarization is a complex process, where cell type, the extracellular environment, and both the mechanical and chemical aspects in cell-matrix interactions performed by integrins play a role.

Published

2021

33. Probing Single-Cell Macrophage Polarization and Heterogeneity Using Thermo-Reversible Hydrogels in Droplet-Based Microfluidics

Author

B. M. Tiemeijer, M. W. D. Sweep, J. J. F. Sleeboom, K. J. Steps, J. F. van Sprang, P. De Almeida, R. Hammink, P. H. J. Kouwer, A. I. P. M. Smits, J. Tel, Immunoengineering, Biomedical Engineering, Microsystems, Group Den Toonder, Biomedical Materials and Chemistry, Soft Tissue Biomech. & Tissue Eng., ICMS Affiliated, and ICMS Core

Subjects

Histology, cytokine secretion, Systems Chemistry, Microfluidics, Biomedical Engineering, Macrophage polarization, Bioengineering, PHENOTYPE, Single-cell analysis, cellular heterogeneity, polyisocyanide, Spectroscopy and Catalysis, single-cell analysis, Viability assay, MODULATION, PLASTICITY, high-throughput, Original Research, Science & Technology, droplet microfluidics, Chemistry, flow cytometry, Bioengineering and Biotechnology, Juxtacrine signalling, Multidisciplinary Sciences, Biotechnology & Applied Microbiology, Cell culture, inflammation, Self-healing hydrogels, Biophysics, Science & Technology - Other Topics, Cytokine secretion, Life Sciences & Biomedicine, TP248.13-248.65, Biotechnology, RESPONSES

Abstract

Human immune cells intrinsically exist as heterogenous populations. To understand cellular heterogeneity, both cell culture and analysis should be executed with single-cell resolution to eliminate juxtacrine and paracrine interactions, as these can lead to a homogenized cell response, obscuring unique cellular behavior. Droplet microfluidics has emerged as a potent tool to culture and stimulate single cells at high throughput. However, when studying adherent cells at single-cell level, it is imperative to provide a substrate for the cells to adhere to, as suspension culture conditions can negatively affect biological function and behavior. Therefore, we combined a droplet-based microfluidic platform with a thermo-reversible polyisocyanide (PIC) hydrogel, which allowed for robust droplet formation at low temperatures, whilst ensuring catalyzer-free droplet gelation and easy cell recovery after culture for downstream analysis. With this approach, we probed the heterogeneity of highly adherent human macrophages under both pro-inflammatory M1 and anti-inflammatory M2 polarization conditions. We showed that co-encapsulation of multiple cells enhanced cell polarization compared to single cells, indicating that cellular communication is a potent driver of macrophage polarization. Additionally, we highlight that culturing single macrophages in PIC hydrogel droplets displayed higher cell viability and enhanced M2 polarization compared to single macrophages cultured in suspension. Remarkably, combining phenotypical and functional analysis on single cultured macrophages revealed a subset of cells in a persistent M1 state, which were undetectable in conventional bulk cultures. Taken together, combining droplet-based microfluidics with hydrogels is a versatile and powerful tool to study the biological function of adherent cell types at single-cell resolution with high throughput. ispartof: FRONTIERS IN BIOENGINEERING AND BIOTECHNOLOGY vol:9 ispartof: location:Switzerland status: published

Published

2021

34. Engineering the Dynamics of Cell Adhesion Cues in Supramolecular Hydrogels for Facile Control over Cell Encapsulation and Behavior

Author

Patricia Y. W. Dankers, Maartje M. C. Bastings, Simone I. S. Hendrikse, Johnick F. van Sprang, Dan Jing Wu, Freek J. M. Hoeben, Henk M. Janssen, Sergio Spaans, Maaike J. G. Schotman, Mani Diba, Biomedical Materials and Chemistry, Soft Tissue Biomech. & Tissue Eng., Protein Engineering, Biomedical Engineering, Macro-Organic Chemistry, Macromolecular and Organic Chemistry, and ICMS Core

Subjects

Materials science, Supramolecular chemistry, Nanotechnology, Pyrimidinones, macromolecular substances, cell encapsulation, Polyethylene Glycols, Extracellular matrix, Cell Adhesion, Molecule, Humans, General Materials Science, dynamic hydrogels, Cell encapsulation, Cell adhesion, molecular exchange dynamics, Fluorescent Dyes, chemistry.chemical_classification, Mechanical Engineering, Stem Cells, technology, industry, and agriculture, Hydrogels, Polymer, Extracellular Matrix, chemistry, Mechanics of Materials, supramolecular biomaterials, Self-healing hydrogels, Surface modification, Blood Vessels, synthetic extracellular matrix, Fluorescence Recovery After Photobleaching

Abstract

The extracellular matrix (ECM) forms through hierarchical assembly of small and larger polymeric molecules into a transient, hydrogel-like fibrous network that provides mechanical support and biochemical cues to cells. Synthetic, fibrous supramolecular networks formed via non-covalent assembly of various molecules are therefore potential candidates as synthetic mimics of the natural ECM, provided that functionalization with biochemical cues is effective. Here, combinations of slow and fast exchanging molecules that self-assemble into supramolecular fibers are employed to form transient hydrogel networks with tunable dynamic behavior. Obtained results prove that modulating the ratio between these molecules dictates the extent of dynamic behavior of the hydrogels at both the molecular and the network level, which is proposed to enable effective incorporation of cell-adhesive functionalities in these materials. Excitingly, the dynamic nature of the supramolecular components in this system can be conveniently employed to formulate multicomponent supramolecular hydrogels for easy culturing and encapsulation of single cells, spheroids, and organoids. Importantly, these findings highlight the significance of molecular design and exchange dynamics for the application of supramolecular hydrogels as synthetic ECM mimics.

Published

2021

35. Radiation Induces Valvular Interstitial Cell Calcific Response in an in vitro Model of Calcific Aortic Valve Disease

Author

Manon Meerman, Rob Driessen, Nicole C. A. van Engeland, Irith Bergsma, Jacco L. G. Steenhuijsen, David Kozono, Elena Aikawa, Jesper Hjortnaes, Carlijn V. C. Bouten, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., and ICMS Core

Subjects

Pathology, medicine.medical_specialty, medicine.medical_treatment, extracellular matrix, in vitro modeling, Cardiovascular Medicine, Matrix (biology), Cell morphology, Interstitial cell, Ionizing radiation, Extracellular matrix, medicine, Diseases of the circulatory (Cardiovascular) system, Fibroblast, radiotherapy, Original Research, business.industry, aortic valve disease, medicine.disease, Radiation therapy, medicine.anatomical_structure, RC666-701, Cardiology and Cardiovascular Medicine, business, valvular interstitial cells, Calcification

Abstract

Background: Mediastinal ionizing radiotherapy is associated with an increased risk of valvular disease, which demonstrates pathological hallmarks similar to calcific aortic valve disease (CAVD). Despite advances in radiotherapy techniques, the prevalence of comorbidities such as radiation-associated valvular disease is still increasing due to improved survival of patients receiving radiotherapy. However, the mechanisms of radiation-associated valvular disease are largely unknown. CAVD is considered to be an actively regulated disease process, mainly controlled by valvular interstitial cells (VICs). We hypothesize that radiation exposure catalyzes the calcific response of VICs and, therefore, contributes to the development of radiation-associated valvular disease.Methods and Results: To delineate the relationship between radiation and VIC behavior (morphology, calcification, and matrix turnover), two different in vitro models were established: (1) VICs were cultured two-dimensional (2D) on coverslips in control medium (CM) or osteogenic medium (OM) and irradiated with 0, 2, 4, 8, or 16 Gray (Gy); and (2) three-dimensional (3D) hydrogel system was designed, loaded with VICs and exposed to 0, 4, or 16 Gy of radiation. In both models, a dose-dependent decrease in cell viability and proliferation was observed in CM and OM. Radiation exposure caused myofibroblast-like morphological changes and differentiation of VICs, as characterized by decreased αSMA expression. Calcification, as defined by increased alkaline phosphatase activity, was mostly present in the 2D irradiated VICs exposed to 4 Gy, while after exposure to higher doses VICs acquired a unique giant fibroblast-like cell morphology. Finally, matrix turnover was significantly affected by radiation exposure in the 3D irradiated VICs, as shown by decreased collagen staining and increased MMP-2 and MMP-9 activity.Conclusions: The presented work demonstrates that radiation exposure enhances the calcific response in VICs, a hallmark of CAVD. In addition, high radiation exposure induces differentiation of VICs into a terminally differentiated giant-cell fibroblast. Further studies are essential to elucidate the underlying mechanisms of these radiation-induced valvular changes.

Published

2021

36. Distinct Effects of Heparin and Interleukin-4 Functionalization on Macrophage Polarization and In Situ Arterial Tissue Regeneration Using Resorbable Supramolecular Vascular Grafts in Rats

Author

Simone M. J. de Jong, Sylvia Dekker, Serena Buscone, Merle M. Krebber, Eva Brauchle, Emily B. Lurier, Koen R D Vaessen, Renee Duijvelshoff, Daniel A Carvajal-Berrio, Suzanne E Koch, Valentina Bonito, Carlijn V. C. Bouten, Patricia Y. W. Dankers, Anthal I.P.M. Smits, Marianne C. Verhaar, Tristan Mes, Katja Schenke-Layland, Anton W. Bosman, Julia Marzi, Soft Tissue Biomech. & Tissue Eng., Cell-Matrix Interact. Cardiov. Tissue Reg., Biomedical Materials and Chemistry, Macromolecular and Organic Chemistry, Macro-Organic Chemistry, ICMS Core, and ICMS Affiliated

Subjects

Scaffold, Pathology, medicine.medical_specialty, Intimal hyperplasia, Biomedical Engineering, Macrophage polarization, Pharmaceutical Science, immunomodulatory biomaterials, Raman microspectroscopy, supramolecular chemistry, Biomaterials, In vivo, medicine, Animals, Thrombus, Interleukin 4, Tissue Engineering, Tissue Scaffolds, Chemistry, Heparin, cardiovascular, Macrophages, in situ tissue engineering, medicine.disease, M2 Macrophage, Blood Vessel Prosthesis, Rats, biodegradable polymers, Interleukin-4, medicine.drug, tissue-engineered vascular graft (TEVG)

Abstract

Two of the greatest challenges for successful application of small-diameter in situ tissue-engineered vascular grafts are 1) preventing thrombus formation and 2) harnessing the inflammatory response to the graft to guide functional tissue regeneration. This study evaluates the in vivo performance of electrospun resorbable elastomeric vascular grafts, dual-functionalized with anti-thrombogenic heparin (hep) and anti-inflammatory interleukin 4 (IL-4) using a supramolecular approach. The regenerative capacity of IL-4/hep, hep-only, and bare grafts is investigated as interposition graft in the rat abdominal aorta, with follow-up at key timepoints in the healing cascade (1, 3, 7 days, and 3 months). Routine analyses are augmented with Raman microspectroscopy, in order to acquire the local molecular fingerprints of the resorbing scaffold and developing tissue. Thrombosis is found not to be a confounding factor in any of the groups. Hep-only-functionalized grafts resulted in adverse tissue remodeling, with cases of local intimal hyperplasia. This is negated with the addition of IL-4, which promoted M2 macrophage polarization and more mature neotissue formation. This study shows that with bioactive functionalization, the early inflammatory response can be modulated and affect the composition of neotissue. Nevertheless, variability between graft outcomes is observed within each group, warranting further evaluation in light of clinical translation.

Published

2021

37. An automated real-time microfluidic platform to probe single NK cell heterogeneity and cytotoxicity on-chip

Author

Ayla M. Hokke, Klaus Eyer, Jurjen Tel, Nikita Subedi, Carlijn V. C. Bouten, Laura C. Van Eyndhoven, Lars Houben, Mark C. van Turnhout, Immunoengineering, Biomedical Engineering, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., and ICMS Core

Subjects

Cytotoxicity, Immunologic, Cell type, Science, Cell, Population, Immunology, Microfluidics, SDG 3 – Goede gezondheid en welzijn, Article, Single-cell analysis, SDG 3 - Good Health and Well-being, Lab-On-A-Chip Devices, Cell death and immune response, medicine, Humans, Cytotoxicity, education, Cells, Cultured, Automation, Laboratory, education.field_of_study, Multidisciplinary, Chemistry, Effector, Cell biology, Killer Cells, Natural, medicine.anatomical_structure, Cancer cell, Medicine, Single-Cell Analysis, K562 Cells, K562 cells

Abstract

Cytotoxicity is a vital effector mechanism used by immune cells to combat pathogens and cancer cells. While conventional cytotoxicity assays rely on averaged end-point measures, crucial insights on the dynamics and heterogeneity of effector and target cell interactions cannot be extracted, emphasizing the need for dynamic single-cell analysis. Here, we present a fully automated droplet-based microfluidic platform that allowed the real-time monitoring of effector-target cell interactions and killing, allowing the screening of over 60,000 droplets identifying 2000 individual cellular interactions monitored over 10 h. During the course of incubation, we observed that the dynamics of cytotoxicity within the Natural Killer (NK) cell population varies significantly over the time. Around 20% of the total NK cells in droplets showed positive cytotoxicity against paired K562 cells, most of which was exhibited within first 4 h of cellular interaction. Using our single cell analysis platform, we demonstrated that the population of NK cells is composed of individual cells with different strength in their effector functions, a behavior masked in conventional studies. Moreover, the versatility of our platform will allow the dynamic and resolved study of interactions between immune cell types and the finding and characterization of functional sub-populations, opening novel ways towards both fundamental and translational research., Scientific Reports, 11 (1), ISSN:2045-2322

Published

2021

38. Computational modelling to reduce outcome variability in tissue-engineered heart valves: Could computational models become a pre-requisite for the broad clinical translation of tissue-engineered heart valves?

Author

Visser, Valery L., Zaytseva, Polina, Motta, Sarah E., Loerakker, Sandra, Hoerstrup, Simon P., Emmert, Maximilian Y., ICMS Affiliated, Soft Tissue Biomech. & Tissue Eng., and Institute for Complex Molecular Systems

Published

2021

39. A computational model to predict cell traction-mediated prestretch in the mitral valve

Author

Manuel K. Rausch, Ellen Kuhl, M. A.J. van Kelle, S Sandra Loerakker, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., and Institute for Complex Molecular Systems

Subjects

mitral valve, Materials science, Cell traction, Finite Element Analysis, 0206 medical engineering, Traction (engineering), finite element method, Biomedical Engineering, Bioengineering, Model parameters, 02 engineering and technology, Systematic variation, 03 medical and health sciences, 0302 clinical medicine, cell-traction forces, Mitral valve, medicine, Computer Simulation, Boundary constraints, Physiological values, Models, Cardiovascular, 030229 sport sciences, General Medicine, Mechanics, 020601 biomedical engineering, Elasticity, Biomechanical Phenomena, Computer Science Applications, Human-Computer Interaction, medicine.anatomical_structure, Anisotropy, Prestretch, Stress, Mechanical

Abstract

Prestretch is observed in many soft biological tissues, directly influencing the mechanical behavior of the tissue in question. The development of this prestretch occurs through complex growth and remodeling phenomena, which yet remain to be elucidated. In the present study it was investigated whether local cell-mediated traction forces can explain the development of global anisotropic tissue prestretch in the mitral valve. Towards this end, a model predicting actin stress fiber-generated traction forces was implemented in a finite element framework of the mitral valve. The overall predicted magnitude of prestretch induced valvular contraction after release of in vivo boundary constraints was in good agreement with data reported on valvular retraction after excision from the heart. Next, by using a systematic variation of model parameters and structural properties, a more anisotropic prestretch development in the valve could be obtained, which was also similar to physiological values. In conclusion, this study shows that cell-generated traction forces could explain prestretch magnitude and anisotropy in the mitral valve.

Published

2019

40. Cyclic Strain Affects Macrophage Cytokine Secretion and Extracellular Matrix Turnover in Electrospun Scaffolds

Author

Anthal I.P.M. Smits, Bente J. de Kort, Valentina Bonito, Carlijn V. C. Bouten, Departmental Office BMT, Cell-Matrix Interact. Cardiov. Tissue Reg., and Soft Tissue Biomech. & Tissue Eng.

Subjects

Male, Adult, Cyclic strain, In situ, extracellular matrix, macrophage polarization, 0206 medical engineering, Biomedical Engineering, Macrophage polarization, Fluorescent Antibody Technique, Bioengineering, tissue regeneration, 02 engineering and technology, immunomodulation, Biochemistry, biomechanics, Biomaterials, Extracellular matrix, Young Adult, Tissue Scaffolds/chemistry, 03 medical and health sciences, Tissue engineering, Macrophages/metabolism, Tissue Engineering/methods, Humans, Macrophage, 030304 developmental biology, 0303 health sciences, Tissue Engineering, Tissue Scaffolds, Chemistry, Macrophages, Cytokines/metabolism, in situ tissue engineering, Extracellular Matrix/metabolism, Middle Aged, 020601 biomedical engineering, Cell biology, Cytokines, Cytokine secretion

Abstract

Controlling macrophage behavior has become a high-potential target strategy for regenerative therapies, such as in situ tissue engineering (TE). In situ TE is an approach, in which acellular resorbable synthetic scaffolds are used, to induce endogenous tissue regeneration. However, little is known regarding the effect of the biomechanical environment on the macrophage response to a scaffold. Therefore, the aim of this study was to assess the effect of cyclic strains (0%, 8%, and 14% strain) on primary human macrophage polarization in electrospun scaffolds with two different fiber diameters in the micrometer range (4 μm or 13 μm). High strains led to a proinflammatory profile in terms of gene expression, expression of surface proteins, and cytokine secretion. These results were consistent for scaffolds with small and large fiber diameters, indicating that the effect of cyclic strain was not affected by the different scaffold microstructures. Notably, macrophages were identified as direct contributors of early secretion of extracellular matrix proteins, including elastin, which was deposited in a strain-dependent manner. These findings are instrumental for the rational design of scaffolds for in situ TE and underline that immunomodulatory scaffolds for biomechanically loaded applications should be mechanically tailored, for example, in terms of stiffness and compliance, to support a desirable proregenerative macrophage phenotype. Electrospun elastomeric scaffolds are being used for a variety of in situ tissue engineering applications, in which biomechanical loads play a dominant in vivo role, such as cardiovascular replacements (e.g., heart valve and blood vessel prostheses) and pelvic floor reconstruction. The findings of this study underline that immunomodulatory scaffolds for biomechanically loaded applications should be mechanically tailored, for example, in terms of stiffness and compliance, to support a desirable proregenerative macrophage phenotype. Moreover, this research contributes to the general understanding of pathophysiological macrophage phenotypes in cyclically strained tissues (e.g., atherosclerotic plaques), and their role in tissue regeneration and degeneration.

Published

2019

41. The degradation and performance of electrospun supramolecular vascular scaffolds examined upon in vitro enzymatic exposure

Author

E.E. van Haaften, Henk M. Janssen, Patricia Y. W. Dankers, Anthal I.P.M. Smits, Serge H. M. Söntjens, Renee Duijvelshoff, Bastiaan D. Ippel, M.H.C.J. van Houtem, Nicholas A. Kurniawan, Carlijn V. C. Bouten, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., Institute for Complex Molecular Systems, Biomedical Materials and Chemistry, and Macromolecular and Organic Chemistry

Subjects

Scaffold, Vascular damage Radboud Institute for Health Sciences [Radboudumc 16], 0206 medical engineering, Biomedical Engineering, Bulk and surface erosion, 02 engineering and technology, Vascular graft, Biochemistry, Biomaterials, Tissue engineering, Materials Testing, Molecular Biology, Vascular tissue, chemistry.chemical_classification, Calorimetry, Differential Scanning, Tissue Scaffolds, Electrospinning, Temperature, Reproducibility of Results, General Medicine, Polymer, Microporous material, Lipase, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, Blood Vessel Prosthesis, Molecular Weight, Supramolecular polymers, chemistry, Chemical engineering, Degradation (geology), 0210 nano-technology, Biotechnology

Abstract

Contains fulltext : 215330.pdf (Publisher’s version ) (Closed access) To maintain functionality during in situ vascular regeneration, the rate of implant degradation should be closely balanced by neo-tissue formation. It is unknown, however, how the implant's functionality is affected by the degradation of the polymers it is composed of. We therefore examined the macro- and microscopic features as well as the mechanical performance of vascular scaffolds upon in vitro enzymatic degradation. Three candidate biomaterials with supramolecularly interacting bis-urea (BU) hard blocks ('slow-degrading' polycarbonate-BU (PC-BU), 'intermediate-degrading' polycarbonate-ester-BU (PC(e)-BU), and 'fast-degrading' polycaprolactone-ester-BU (PCL-BU)) were synthesized and electrospun into microporous scaffolds. These materials possess a sequence-controlled macromolecular structure, so their susceptibility to degradation is tunable by controlling the nature of the polymer backbone. The scaffolds were incubated in lipase and monitored for changes in physical, chemical, and mechanical properties. Remarkably, comparing PC-BU to PC(e)-BU, we observed that small changes in macromolecular structure led to significant differences in degradation kinetics. All three scaffold types degraded via surface erosion, which was accompanied by fiber swelling for PC-BU scaffolds, and some bulk degradation and a collapsing network for PCL-BU scaffolds. For the PC-BU and PC(e)-BU scaffolds this resulted in retention of mechanical properties, whereas for the PCL-BU scaffolds this resulted in stiffening. Our in vitro study demonstrates that vascular scaffolds, electrospun from sequence-controlled supramolecular materials with varying ester contents, not only display different susceptibilities to degradation, but also degrade via different mechanisms. STATEMENT OF SIGNIFICANCE: One of the key elements to successfully engineer vascular tissues in situ, is to balance the rate of implant degradation and neo-tissue formation. Due to their tunable properties, supramolecular polymers can be customized into attractive biomaterials for vascular tissue engineering. Here, we have exploited this tunability and prepared a set of polymers with different susceptibility to degradation. The polymers, which were electrospun into microporous scaffolds, displayed not only different susceptibilities to degradation, but also obeyed different degradation mechanisms. This study illustrates how the class of supramolecular polymers continues to represent a promising group of materials for tissue engineering approaches.

Published

2019

42. Influence of the Assembly State on the Functionality of a Supramolecular Jagged1-Mimicking Peptide Additive

Author

Patricia Y. W. Dankers, Oscar M. J. A. Stassen, Matilde Putti, Maaike J. G. Schotman, Cecilia Sahlgren, Biomedical Materials and Chemistry, Cell-Matrix Interact. Cardiov. Tissue Reg., and Soft Tissue Biomech. & Tissue Eng.

Subjects

chemistry.chemical_classification, 0303 health sciences, Chemistry, Hydrogen bond, Atomic force microscopy, General Chemical Engineering, Supramolecular chemistry, technology, industry, and agriculture, Peptide, 02 engineering and technology, General Chemistry, Solid material, 021001 nanoscience & nanotechnology, Combinatorial chemistry, lcsh:Chemistry, 03 medical and health sciences, chemistry.chemical_compound, lcsh:QD1-999, Polycaprolactone, Surface modification, 0210 nano-technology, Peptide sequence, 030304 developmental biology

Abstract

Expanding the bioactivation toolbox of supramolecular materials is of utmost relevance for their broad applicability in regenerative medicines. This study explores the functionality of a peptide mimic of the Notch ligand Jagged1 in a supramolecular system that is based on hydrogen bonding ureido-pyrimidinone (UPy) units. The functionality of the peptide is studied when formulated as an additive in a supramolecular solid material and as a self-assembled system in solution. UPy conjugation of the DSL JAG1 peptide sequence allows for the supramolecular functionalization of UPy-modified polycaprolactone, an elastomeric material, with UPy-DSL JAG1 . Surface presentation of the UPy-DSL JAG1 peptide was confirmed by atomic force microscopy and X-ray photoelectron spectroscopy analyses, but no enhancement of Notch activity was detected in cells presenting Notch1 and Notch3 receptors. Nevertheless, a significant increase in Notch-signaling activity was observed when DSL JAG1 peptides were administered in the soluble form, indicating that the activity of DSL JAG1 is preserved after UPy functionalization but not after immobilization on a supramolecular solid material. Interestingly, an enhanced activity in solution of the UPy conjugate was detected compared with the unconjugated DSL JAG1 peptide, suggesting that the self-assembly of supramolecular aggregates in solution ameliorates the functionality of the molecules in a biological context.

Published

2019

43. Myoglobin and troponin concentrations are increased in early stage deep tissue injury

Author

Willeke A. Traa, Dan L. Bader, Cees W. J. Oomens, Gustav J. Strijkers, ACS - Atherosclerosis & ischemic syndromes, Amsterdam Neuroscience - Brain Imaging, ACS - Heart failure & arrhythmias, Biomedical Engineering and Physics, AMS - Sports & Work, and Soft Tissue Biomech. & Tissue Eng.

Subjects

Pathology, medicine.medical_specialty, Biomedical Engineering, 02 engineering and technology, Urine, Deep tissue injury, Biomaterials, Rats, Sprague-Dawley, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Magnetic resonance imaging, Tibialis anterior muscle, Blood plasma, medicine, Animals, Skeletal muscle damage, Stage (cooking), Pressure ulcers, Pressure Ulcer, medicine.diagnostic_test, biology, business.industry, Myoglobin, 030206 dentistry, 021001 nanoscience & nanotechnology, Troponin, Rats, chemistry, Mechanics of Materials, biology.protein, Biomarker (medicine), Female, 0210 nano-technology, business, Biomarkers

Abstract

Pressure-induced deep tissue injury is a form of pressure ulcer which is difficult to detect and diagnose at an early stage, before the wound has severely progressed and becomes visible at the skin surface. At the present time, no such detection technique is available. To test the hypothesis that muscle damage biomarkers can be indicative of the development of deep tissue injury after sustained mechanical loading, an indentation test was performed for 2 h on the tibialis anterior muscle of rats. Myoglobin and troponin were analysed in blood plasma and urine over a period of 5 days. The damage as detected by the biomarkers was compared to damage as observed with T 2 MRI to validate the response. We found that myoglobin and troponin levels in blood increased due to the damage. Myoglobin was also increased in urine. The amount of damage observed with MRI immediately after loading had a strong correlation with the maximal biomarker levels: troponin in blood r s = 0.94; myoglobin in blood r s = 0.75; and myoglobin in urine r s = 0.57. This study suggests that muscle damage markers measured in blood and urine could serve as early diagnosis for pressure induced deep tissue injury.

Published

2019

44. Investigating the influence of intermittent and continuous mechanical loading on skin through non-invasive sampling of IL-1α

Author

Cees W. J. Oomens, Peter Worsley, J.F.J. Soetens, Dan L. Bader, and Soft Tissue Biomech. & Tissue Eng.

Subjects

Adult, Male, Pressure Ulcer/etiology, Dermatology, Stress, Pathology and Forensic Medicine, 030207 dermatology & venereal diseases, 03 medical and health sciences, 0302 clinical medicine, Refractory, Interleukin-1alpha, Healthy volunteers, Individual data, Tissue damage, Humans, Medicine, Non invasive sampling, Skin, Aged, Pressure Ulcer, 030504 nursing, business.industry, Skin response, Skin/injuries, Middle Aged, Mechanical, Regimen, Anesthesia, Female, Stress, Mechanical, Interleukin-1alpha/analysis, 0305 other medical science, business, Healthcare system

Abstract

Pressure ulcers (PUs) are a major burden to both patients, carers and the healthcare system. It is therefore important to identify patients at risk and detect pressure ulcers at an early stage of their development. The pro-inflammatory cytokine IL-1α is a promising indicator of tissue damage. The aim of this study was to compare the temporal skin response, by means of IL-1α expression, to different loading regimens and to investigate the presence of individual variability. The sacrum of eleven healthy volunteers was subjected to two different loading protocols. After a baseline measurement, the left and right side of the sacrum were subjected to continuous and intermittent loading regimen, respectively, at a pressure of 100 mmHg. Data was collected every 20 min, allowing for a total experimental time of 140 min. Sebum, collected at ambient conditions using Sebutape, was analyzed for the pro-inflammatory cytokine IL-1α. Most robust results were obtained using a baseline normalization approach on individual data. The IL-1α level significantly changed upon load application and removal ( p 0.05 ) for both loading regimens. Highest IL-1α ratio increase, 3.7-fold, was observed for 1 h continuous loading. During the refractory periods for both loading regimen the IL-1α levels were still found to be up-regulated compared to baseline ( p 0.05 ). The IL-1α level increased significantly for the two initial loading periods ( p 0.05 ), but stabilized during the final loading period for both loading regimens. Large individual variability in IL-1α ratio was observed in the responses, with median values of 1.91 (range 1.49–3.08), and 2.52 (range 1.96–4.29), for intermittent and continuous loading, respectively, although the differences were not statistically significant. Cluster analysis revealed the presence of two distinct sub-populations, with either a low or high response to the applied loading regimen. The measurement after the first loading period proved to be representative for the subsequent measurements on each site. This study revealed that trends in normalized IL-1α provided an early indicator for tissue status following periods of mechanical loading and refractory unloaded conditions. Additionally, the observed individual variability in the response potentially identifies patients at risk of developing PUs.

Published

2019

45. Computationally guided in-vitro vascular growth model reveals causal link between flow oscillations and disorganized neotissue

Author

Carlijn V. C. Bouten, Wouter Huberts, Eline E. van Haaften, Sjeng Quicken, Nicholas A. Kurniawan, RS: Carim - H07 Cardiovascular System Dynamics, Biomedische Technologie, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., Institute for Complex Molecular Systems, Cardiovascular Biomechanics, ICMS Core, and ICMS Affiliated

Subjects

0301 basic medicine, Scaffold, QH301-705.5, 030232 urology & nephrology, Medicine (miscellaneous), Context (language use), WALL SHEAR-STRESS, In Vitro Techniques, General Biochemistry, Genetics and Molecular Biology, Article, Monocytes, 03 medical and health sciences, 0302 clinical medicine, Collagen network, medicine, Shear stress, Computational models, Humans, Computer Simulation, Biology (General), Myofibroblasts, Process (anatomy), ARTERIOVENOUS-FISTULAS, Cells, Cultured, Neointimal hyperplasia, Cardiovascular models, Hyperplasia, Chemistry, Regeneration (biology), Graft Occlusion, Vascular, medicine.disease, In vitro, COLLAGEN, Cell biology, Circulation, surgical procedures, operative, 030104 developmental biology, SIMULATION, Stress, Mechanical, General Agricultural and Biological Sciences

Abstract

Disturbed shear stress is thought to be the driving factor of neointimal hyperplasia in blood vessels and grafts, for example in hemodialysis conduits. Despite the common occurrence of neointimal hyperplasia, however, the mechanistic role of shear stress is unclear. This is especially problematic in the context of in situ scaffold-guided vascular regeneration, a process strongly driven by the scaffold mechanical environment. To address this issue, we herein introduce an integrated numerical-experimental approach to reconstruct the graft–host response and interrogate the mechanoregulation in dialysis grafts. Starting from patient data, we numerically analyze the biomechanics at the vein–graft anastomosis of a hemodialysis conduit. Using this biomechanical data, we show in an in vitro vascular growth model that oscillatory shear stress, in the presence of cyclic strain, favors neotissue development by reducing the secretion of remodeling markers by vascular cells and promoting the formation of a dense and disorganized collagen network. These findings identify scaffold-based shielding of cells from oscillatory shear stress as a potential handle to inhibit neointimal hyperplasia in grafts., van Haaften et al. show numerical-experimental approach to reconstruct the graft–host response. They interrogate the mechanoregulation in dialysis grafts to solve the disturbed shear stress problem, which can be a cause of neointimal hyperplasia in blood vessels and grafts.

Published

2021

46. Human pluripotent stem cell-derived cardiomyocytes align under cyclic strain when guided by cardiac fibroblasts

Author

Dylan Mostert, Bart Groenen, Leda Klouda, Robert Passier, Marie-Jose Goumans, Nicholas A. Kurniawan, Carlijn V. C. Bouten, TechMed Centre, Applied Stem Cell Technology, Cell-Matrix Interact. Cardiov. Tissue Reg., Biomedical Engineering, ICMS Affiliated, and Soft Tissue Biomech. & Tissue Eng.

Subjects

Cell type, Contraction (grammar), Chemistry, Disease progression, Cell, Biomedical Engineering, Biophysics, Bioengineering, Human myocardium, In vitro, Cell biology, Biomaterials, Extracellular matrix, medicine.anatomical_structure, Cardiac fibroblast, medicine

Abstract

The human myocardium is a mechanically active tissue typified by the anisotropic organization of cells and extracellular matrix (ECM). Upon injury, the composition of the myocardium changes, resulting in disruption of tissue organization and loss of coordinated contraction. Understanding how anisotropic organization in the adult myocardium is shaped and disrupted by environmental cues is thus critical, not only for unravelling the processes taking place during disease progression, but also for developing regenerative strategies to recover tissue function. Here, we decoupled in vitro the two major physical cues that are inherent in the myocardium: structural ECM and mechanical strain. We show that patterned ECM proteins control the orientation of the two main cell types in the myocardium: human cardiac fibroblasts (cFBs) and cardiomyocytes (hiPSC-CMs), despite their different mechanosensing machinery. Uniaxial cyclic strain, mimicking the local anisotropic deformation of the myocardium, did not affect hiPSC-CMs orientation. It did however induce a reorientation of cFBs, perpendicular to the strain direction, albeit this strain-avoidance response was overruled in the presence of anisotropic structural cues. These findings reveal that the mechanoresponsiveness of cFBs may be a critical handle in controlling myocardial tissue structure and function. To test this, we co-cultured hiPSC-CMs and cFBs in varying cell ratios to reconstruct normal and pathological myocardium. Contrary to the hiPSC-CM monoculture, the co-cultures adopted an anisotropic organization under uniaxial cyclic strain, regardless of the cell ratio. Together, these results identify the cFBs as a therapeutic target to mechanically restore structural organization of the tissue in cardiac regenerative therapies. SIGNIFICANCE STATEMENTUpon cardiac injury, adverse remodeling commonly leads to loss of the anisotropy that is typically found in human adult myocardium. Understanding the role of biophysical cues in shaping and disrupting the anisotropic tissue organization is essential to aid in the progress of cardiac regenerative strategies. Here, we report that the mechanoresponsiveness of cardiomyocytes (hiPSC-CMs) and cardiac fibroblasts (cFBs) differs significantly, resulting in a strain-induced reorganization response for cFBs but not for hiPSC-CMs. In co-culture with varying cell ratios of cFBs and hiPSC-CMs, the co-cultures adopted an anisotropic organization upon cyclic strain administration. Thus, our study proposes the mechanoresponse of cFBs, a cell type often overlooked in cardiac regenerative strategies, as a handle to restore myocardial architecture and function.

Published

2021

47. Advanced In Vitro Modeling to Study the Paradox of Mechanically Induced Cardiac Fibrosis

Author

Carlijn V. C. Bouten, Pieter A. Doevendans, Jesper Hjortnaes, Joost P.G. Sluijter, Jeroen M. Stein, Dimitri E P Muylaert, Ali Khademhosseini, Thomas C. Bracco Gartner, Willem J.L. Suyker, Soft Tissue Biomech. & Tissue Eng., Cell-Matrix Interact. Cardiov. Tissue Reg., and ICMS Core

Subjects

Myocardium/pathology, medicine.medical_specialty, Cardiac fibrosis, Biomedical Engineering, Medicine (miscellaneous), Bioengineering, Mechanotransduction, Cellular, Cardiac fibroblast, Internal medicine, disease modeling, medicine, Humans, Mechanotransduction, Myofibroblasts, organs-on-chips, mechanotransduction, business.industry, cardiac fibroblast, medicine.disease, Fibrosis, In vitro, Fibroblasts/pathology, Heart failure, cardiovascular system, Cardiology, Myocardial fibrosis, myocardial fibrosis, Cellular, business

Abstract

In heart failure, cardiac fibrosis is the result of an adverse remodeling process. Collagen is continuously synthesized in the myocardium in an ongoing attempt of the heart to repair itself. The resulting collagen depositions act counterproductively, causing diastolic dysfunction and disturbing electrical conduction. Efforts to treat cardiac fibrosis specifically have not been successful and the molecular etiology is only partially understood. The differentiation of quiescent cardiac fibroblasts to extracellular matrix-depositing myofibroblasts is a hallmark of cardiac fibrosis and a key aspect of the adverse remodeling process. This conversion is induced by a complex interplay of biochemical signals and mechanical stimuli. Tissue-engineered 3D models to study cardiac fibroblast behavior in vitro indicate that cyclic strain can activate a myofibroblast phenotype. This raises the question how fibroblast quiescence is maintained in the healthy myocardium, despite continuous stimulation of ultimately profibrotic mechanotransductive pathways. In this review, we will discuss the convergence of biochemical and mechanical differentiation signals of myofibroblasts, and hypothesize how these affect this paradoxical quiescence.Impact statementMechanotransduction pathways of cardiac fibroblasts seem to ultimately be profibrotic in nature, but in healthy human myocardium, cardiac fibroblasts remain quiescent, despite continuous mechanical stimulation. We propose three hypotheses that could explain this paradoxical state of affairs. Furthermore, we provide suggestions for future research, which should lead to a better understanding of fibroblast quiescence and activation, and ultimately to new strategies for the prevention and treatment of cardiac fibrosis and heart failure.

Published

2021

48. Renal Epithelial Cell Responses to Supramolecular Thermoplastic Elastomeric Concave and Convex Structures

Author

Patricia Y. W. Dankers, Nicholas A. Kurniawan, Ronald C. van Gaal, Rogier P. R. S. Miltenburg, Carlijn V. C. Bouten, Soft Tissue Biomech. & Tissue Eng., Biomedical Engineering, Cell-Matrix Interact. Cardiov. Tissue Reg., Biomedical Materials and Chemistry, ICMS Core, and ICMS Affiliated

Subjects

Materials science, Thermoplastic, Cell seeding, Supramolecular chemistry, 02 engineering and technology, Elastomer, curvatures, 03 medical and health sciences, chemistry.chemical_compound, Live cell imaging, Renal epithelial cell, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, polarization, Polydimethylsiloxane, Mechanical Engineering, Regular polygon, supramolecular materials, 021001 nanoscience & nanotechnology, epithelial cells, body regions, chemistry, Mechanics of Materials, Biophysics, 0210 nano-technology, biomaterials

Abstract

The nephron naturally provides a concave conformation for epithelial cells, yet biomedical applications such as bioartificial kidney can employ convex seeding. Frequently glass or polydimethylsiloxane are utilized as base materials to study renal epithelial cell response to curvatures. Insights on relevant materials for biomedical applications remain limited. Here it is investigated how human immortalized renal proximal tubule epithelial cells (RPTEC) respond to a range of concave and convex curvatures made from a bis-urea modified polycaprolactone material. Solvent cast chips containing a 50–500 µm diameter range of both concave and convex semicylindrical structures are successfully produced. Concave structures are completely covered by cells under all conditions. Yet cell layers present gaps on the summits of convex structures; the relative gap size enlarges as the diameter decreased. Increased proliferation time and cell seeding density allow for cells to overcome summit avoidance and nearly engulf convex structures. Interestingly, sample inversion also results in gap closure on convex structures during live imaging. Polarization of RPTECs is more prominent on concave compared to convex structures. These findings suggest that biomedical applications such as the bioartificial kidney should focus on concave seeding of cells to acquire more functional cell monolayers.

Published

2021

49. In Situ Remodeling Overrules Bioinspired Scaffold Architecture of Supramolecular Elastomeric Tissue-Engineered Heart Valves

Author

Daphne van Geemen, Bas R van Klarenbosch, Anthal I.P.M. Smits, Tristan Mes, Carlijn V. C. Bouten, Jan Willem van Rijswijk, Maarten J. Cramer, Anton W. Bosman, J. Kluin, Marieke Brugmans, M. Uiterwijk, Sylvia Dekker, Emily B. Lurier, Paul F. Gründeman, Elena Aikawa, Andrea Di Luca, Soft Tissue Biomech. & Tissue Eng., Cell-Matrix Interact. Cardiov. Tissue Reg., Macromolecular and Organic Chemistry, ICMS Affiliated, ICMS Core, Graduate School, ACS - Atherosclerosis & ischemic syndromes, Cardiothoracic Surgery, and ACS - Heart failure & arrhythmias

Subjects

0301 basic medicine, In situ, biomimicry, Materials science, aTEHV, anisotropic tissue-engineered heart valve, cell biology/structural biology, 030204 cardiovascular system & hematology, Elastomer, 03 medical and health sciences, 0302 clinical medicine, Tissue engineering, medicine, SEM, scanning electron microscopy, TEHV, tissue-engineered heart valve, Heart valve replacement, Heart valve, Scaffold architecture, Tissue engineered, valvular heart disease, in situ tissue engineering, medicine.disease, GPC, gel permeation chromatography, contact guidance, 030104 developmental biology, medicine.anatomical_structure, TTE, transthoracic echocardiography, rTEHV, random tissue-engineered heart valve, Preclinical Research, Cardiology and Cardiovascular Medicine, bioinspired architecture, heart valves, Editorial Comment, Biomedical engineering

Abstract

Visual Abstract, Highlights • The predefined fiber alignment in electrospun biodegradable heart valve scaffolds did not lead to consistent collagen organization in the predefined direction. • A tendency for higher regurgitation rate and peak gradient was seen in the aTEHVs. • Biaxial tensile tests on the explanted aTEHVs revealed loss of mechanical integrity of the circumferentially aligned fibers after 1 month. • Isotropic mechanical properties were seen in all explanted scaffolds at 6 and 12 months. • Valve-to-valve variability was observed, regardless of the study group, both on the macroscopic and microscopic levels., Summary In situ tissue engineering that uses resorbable synthetic heart valve scaffolds is an affordable and practical approach for heart valve replacement; therefore, it is attractive for clinical use. This study showed no consistent collagen organization in the predefined direction of electrospun scaffolds made from a resorbable supramolecular elastomer with random or circumferentially aligned fibers, after 12 months of implantation in sheep. These unexpected findings and the observed intervalvular variability highlight the need for a mechanistic understanding of the long-term in situ remodeling processes in large animal models to improve predictability of outcome toward robust and safe clinical application.

Published

2020

50. Correction to 'Protein Micropatterning in 2.5D

Author

Cas van der Putten, Antonetta B. C. Buskermolen, Maike Werner, Hannah F. M. Brouwer, Paul A. A Bartels, Patricia Y. W. Dankers, Carlijn V. C. Bouten, Nicholas A. Kurniawan, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., Biomedical Materials and Chemistry, ICMS Core, and ICMS Affiliated

Subjects

bacteria, General Materials Science, complex mixtures

Abstract

In the original version of this article, section Materials and Methods, Table 1 contains a mistake. In the description of "passivation with poly-L-lysine and mPEG-SVA", the concentration of poly-L-lysine should be 0.1 mg/mL. In the revised table below, this correct concentration is included. This correction does not alter any conclusions of this work. (Table presented).

Published

2022