Your search keyword '"Sandra Loerakker"' showing total 24 results

1. Computational modeling for cardiovascular tissue engineering: the importance of including cell behavior in growth and remodeling algorithms

Author

Tommaso Ristori and S Sandra Loerakker

Subjects

Cell signaling, 0303 health sciences, Scaffold, Computational model, Computer science, Biomedical Engineering, Medicine (miscellaneous), Computational modeling, Bioengineering, Context (language use), 02 engineering and technology, Computational biology, 021001 nanoscience & nanotechnology, Experimental research, Biomaterials, 03 medical and health sciences, Tissue engineering, Cytoskeletal remodeling, 0210 nano-technology, Growth and remodeling, Migration, 030304 developmental biology

Abstract

Understanding cardiovascular growth and remodeling (G&R) is fundamental for designing robust cardiovascular tissue engineering strategies, which enable synthetic or biological scaffolds to transform into healthy living tissues after implantation. Computational modeling, particularly when integrated with experimental research, is key for advancing our understanding, predicting the in vivo evolution of engineered tissues, and efficiently optimizing scaffold designs. As cells are ultimately the drivers of G&R and known to change their behavior in response to mechanical cues, increasing efforts are currently undertaken to capture (mechano-mediated) cell behavior in computational models. In this selective review, we highlight some recent examples that are relevant in the context of cardiovascular tissue engineering and discuss the current and future biological and computational challenges for modeling cell-mediated G&R.

Published

2020

2. 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

3. Pressure-induced collagen degradation in arterial tissue as a potential mechanism for degenerative arterial disease progression

Author

Robert Gaul, Tommaso Ristori, S Sandra Loerakker, Carlijn V. C. Bouten, Caitríona Lally, D.R. Nolan, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., ICMS Affiliated, and ICMS Core

Subjects

Arterial disease, Biomedical Engineering, Strain (injury), 02 engineering and technology, Matrix (biology), Biomaterials, 03 medical and health sciences, Degradation, 0302 clinical medicine, medicine, Humans, Pressure-induced, Collagenases, Aneurysm formation, Potential mechanism, Collagen degradation, Chemistry, Structural integrity, 030206 dentistry, Arteries, 021001 nanoscience & nanotechnology, medicine.disease, Artery, Extracellular Matrix, medicine.anatomical_structure, Strain-dependent, Mechanics of Materials, Biophysics, Disease Progression, Collagen, 0210 nano-technology

Abstract

Collagen fibre degradation is a strain-dependent process, whereby the magnitude of experienced strain dictates the rate of enzymatic cleavage. Studies have identified conflicting findings as to whether strain inhibits or enhances collagen degradation, which may be explained by the tissue type and tissue scale investigated, as well as the strain range considered. The aim of this study is to identify, for the first time, the strain-dependent degradation response of intact arterial vessels experiencing physiological pressures and apply these findings to a computational model to better understand degenerative arterial diseases, such as aneurysms. To achieve this, a series of quasi-static pressure inflation experiments were carried out on intact arteries in the presence of purified bacterial collagenase at physiologically relevant pressures to investigate collagen matrix degradation in the vascular wall. A complementary computational model was developed to explore the complex role of pressure, non-collagenous matrix contribution, and collagen fibre crimp in the ultimate degradation response of the vessel. Pressure induced inflation-degradation results identified an increased rate of vessel expansion and reduced time to failure with increasing pressure in the vessels. Interestingly, our computational model was able to capture this same response, including the elevated rates of degradation which occur at low pressures. These findings highlight the critical role of strain in collagen degradation, particularly in cases of arterial disease, such as aneurysm formation, whereby structural integrity may be compromised.

Published

2020

4. Modelling The Combined Effects Of Collagen and Cyclic Strain On Cellular Orientation In Collagenous Tissues

Author

Nicholas A. Kurniawan, T. M. W. Notermans, Frank P. T. Baaijens, Jasper Foolen, S Sandra Loerakker, Tommaso Ristori, Carlijn V. C. Bouten, Institute for Complex Molecular Systems, Cell-Matrix Interact. Cardiov. Tissue Reg., Biomedical Engineering, Orthopaedic Biomechanics, and Soft Tissue Biomech. & Tissue Eng.

Subjects

0301 basic medicine, Cyclic strain, Multidisciplinary, Strain (chemistry), Chemistry, Orientation (computer vision), 0206 medical engineering, lcsh:R, lcsh:Medicine, 02 engineering and technology, Models, Biological, 020601 biomedical engineering, Article, Contact guidance, 03 medical and health sciences, 030104 developmental biology, Extracellular, Biophysics, Animals, Humans, Computer Simulation, lcsh:Q, Collagen, lcsh:Science

Abstract

Adherent cells are generally able to reorient in response to cyclic strain. In three-dimensional tissues, however, extracellular collagen can affect this cellular response. In this study, a computational model able to predict the combined effects of mechanical stimuli and collagen on cellular (re)orientation was developed. In particular, a recently proposed computational model (which only accounts for mechanical stimuli) was extended by considering two hypotheses on how collagen influences cellular (re)orientation: collagen contributes to cell alignment by providing topographical cues (contact guidance); or collagen causes a spatial obstruction for cellular reorientation (steric hindrance). In addition, we developed an evolution law to predict cell-induced collagen realignment. The hypotheses were tested by simulating bi- or uniaxially constrained cell-populated collagen gels with different collagen densities, subjected to immediate or delayed uniaxial cyclic strain with varying strain amplitudes. The simulation outcomes are in agreement with previous experimental reports. Taken together, our computational approach is a promising tool to understand and predict the remodeling of collagenous tissues, such as native or tissue-engineered arteries and heart valves.

Published

2018

5. Growth and remodeling play opposing roles during postnatal human heart valve development

Author

Pim J A Oomen, Ellen Kuhl, Carlijn V. C. Bouten, S Sandra Loerakker, Maria A. Holland, and Soft Tissue Biomech. & Tissue Eng.

Subjects

Adult, Adolescent, 0206 medical engineering, lcsh:Medicine, 02 engineering and technology, 030204 cardiovascular system & hematology, Biology, Cardiovascular, Article, Heart Valves/growth & development, 03 medical and health sciences, 0302 clinical medicine, Models, medicine, Humans, Heart valve, Ventricular remodeling, lcsh:Science, Postnatal human, Multidisciplinary, Ventricular Remodeling, Extramural, Mechanical models, lcsh:R, Models, Cardiovascular, Infant, Biological tissue, Middle Aged, medicine.disease, Heart Valves, 020601 biomedical engineering, Cell biology, medicine.anatomical_structure, lcsh:Q, Homeostasis

Abstract

Tissue growth and remodeling are known to govern mechanical homeostasis in biological tissue, but their relative contributions to homeostasis remain unclear. Here, we use mechanical models, fueled by experimental findings, to demonstrate that growth and remodeling have different effects on heart valve stretch homeostasis during physiological postnatal development. Two developmental stages were considered: early-stage (from infant to adolescent) and late-stage (from adolescent to adult) development. Our models indicated that growth and remodeling play opposing roles in preserving tissue stretch and with time. During early-stage development, excessive tissue stretch was decreased by tissue growth and increased by remodeling. In contrast, during late-stage development tissue stretch was decreased by remodeling and increased by growth. Our findings contribute to an improved understanding of native heart valve adaptation throughout life, and are highly relevant for the development of tissue-engineered heart valves.

Published

2018

6. Increased Cell Traction-Induced Prestress in Dynamically Cultured Microtissues

Author

Mathieu A. J. van Kelle, Nilam Khalil, Jasper Foolen, Sandra Loerakker, Carlijn V. C. Bouten, Institute for Complex Molecular Systems, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., and Orthopaedic Biomechanics

Subjects

0301 basic medicine, Histology, Cantilever, Materials science, Micrometer scale, Cell traction, lcsh:Biotechnology, medicine.medical_treatment, Biomedical Engineering, Prestress, Bioengineering, Tissue-engineering, 02 engineering and technology, 03 medical and health sciences, In vitro, Tissue engineering, lcsh:TP248.13-248.65, medicine, Static loading, Original Research, Cyclic stretching, Bioengineering and Biotechnology, Traction (orthopedics), 021001 nanoscience & nanotechnology, 030104 developmental biology, Dynamic loading, Experiments, 0210 nano-technology, Microtissue, Biotechnology, Biomedical engineering

Abstract

Prestress is a phenomenon present in many cardiovascular tissues and has profound implications on their in vivo functionality. For instance, the in vivo mechanical properties are altered by the presence of prestress, and prestress also influences tissue growth and remodeling processes. The development of tissue prestress typically originates from complex growth and remodeling phenomena which yet remain to be elucidated. One particularly interesting mechanism in which prestress develops is by active traction forces generated by cells embedded in the tissue by means of their actin stress fibers. In order to understand how these traction forces influence tissue prestress, many have used microfabricated, high-throughput, micrometer scale setups to culture microtissues which actively generate prestress to specially designed cantilevers. By measuring the displacement of these cantilevers, the prestress response to all kinds of perturbations can be monitored. In the present study, such a microfabricated tissue gauge platform was combined with the commercially available Flexcell system to facilitate dynamic cyclic stretching of microtissues. First, the setup was validated to quantify the dynamic microtissue stretch applied during the experiments. Next, the microtissues were subjected to a dynamic loading regime for 24 h. After this interval, the prestress increased to levels over twice as high compared to static controls. The prestress in these tissues was completely abated when a ROCK-inhibitor was added, showing that the development of this prestress can be completely attributed to the cell-generated traction forces. Finally, after switching the microtissues back to static loading conditions, or when removing the ROCK-inhibitor, prestress magnitudes were restored to original values. These findings show that intrinsic cell-generated prestress is a highly controlled parameter, where the actin stress fibers serve as a mechanostat to regulate this prestress. Since almost all cardiovascular tissues are exposed to a dynamic loading regime, these findings have important implications for the mechanical testing of these tissues, or when designing cardiovascular tissue engineering therapies.

Published

2019

7. Cellular Contact Guidance Emerges from Gap Avoidance

Author

Vikram Deshpande, Siamak Soleymani Shishvan, Antonetta B.C. Buskermolen, Mark C. van Turnhout, Carlijn V. C. Bouten, Nicholas A. Kurniawan, S Sandra Loerakker, Tommaso Ristori, Dylan Mostert, Soft Tissue Biomech. & Tissue Eng., Cell-Matrix Interact. Cardiov. Tissue Reg., ICMS Affiliated, and ICMS Core

Subjects

Length scale, microcontact printing, General Physics and Astronomy, 02 engineering and technology, Protein patterning, Parallel, Article, Contact guidance, Focal adhesion, stress fibers, 03 medical and health sciences, General Materials Science, focal adhesion, Cell shape, protein patterning, 030304 developmental biology, Physics, 0303 health sciences, General Engineering, cell adhesion, General Chemistry, Statistical mechanics, 021001 nanoscience & nanotechnology, cell alignment, lcsh:QC1-999, contact guidance, General Energy, Morphometric analysis, substrate anisotropy, statistical mechanics, cell organization, 0210 nano-technology, Biological system, lcsh:Physics

Abstract

Summary In the presence of anisotropic biochemical or topographical patterns, cells tend to align in the direction of these cues—a widely reported phenomenon known as “contact guidance.” To investigate the origins of contact guidance, here, we created substrates micropatterned with parallel lines of fibronectin with dimensions spanning multiple orders of magnitude. Quantitative morphometric analysis of our experimental data reveals two regimes of contact guidance governed by the length scale of the cues that cannot be explained by enforced alignment of focal adhesions. Adopting computational simulations of cell remodeling on inhomogeneous substrates based on a statistical mechanics framework for living cells, we show that contact guidance emerges from anisotropic cell shape fluctuation and “gap avoidance,” i.e., the energetic penalty of cell adhesions on non-adhesive gaps. Our findings therefore point to general biophysical mechanisms underlying cellular contact guidance, without the necessity of invoking specific molecular pathways., Graphical Abstract, Highlights Cells exhibit an optimum alignment (contact guidance) to substrate micropatterns Contact guidance does not require constrained alignment of focal adhesions Statistical mechanics model reveals the energetic role of non-adhesive gaps The non-adhesive gap size determines the degree of cell alignment, Buskermolen et al. report that cells align to substrate micropatterns in a highly length-scale-dependent manner. This alignment emerges from energetically favorable cell elongation and “gap avoidance”: minimization of cellular adhesions on non-adhesive gaps. This finding points to biophysically driven mechanisms underlying cellular contact guidance without necessarily invoking specific molecular pathways.

Published

2020

8. Vimentin regulates Notch signaling strength and arterial remodeling in response to hemodynamic stress

Author

Nicole C. A. van Engeland, Kayla J. Bayless, Tommaso Ristori, Adolfo Rivero-Müller, Eriika Savontaus, Salla Nuutinen, Saku Ruohonen, Carlijn V. C. Bouten, John E. Eriksson, Cecilia Sahlgren, Freddy Suarez Rodriguez, R. C. H. Driessen, Marika Sjöqvist, Suvi T. Ruohonen, Camille L. Duran, Oscar M. J. A. Stassen, S Sandra Loerakker, Daniel Antfolk, Soft Tissue Biomech. & Tissue Eng., and Cell-Matrix Interact. Cardiov. Tissue Reg.

Subjects

0301 basic medicine, Transcriptional Activation, Vascular smooth muscle, Myocytes, Smooth Muscle, Notch signaling pathway, lcsh:Medicine, Vimentin, macromolecular substances, Vascular Remodeling, Article, Muscle, Smooth, Vascular, 03 medical and health sciences, Transactivation, Mice, 0302 clinical medicine, Stress, Physiological, Human Umbilical Vein Endothelial Cells, Animals, Humans, Intermediate filaments, Cytoskeleton, Intermediate filament, Cellular microbiology, lcsh:Science, Aorta, Mice, Knockout, Multidisciplinary, biology, Receptors, Notch, Chemistry, lcsh:R, Hemodynamics, Cell biology, 030104 developmental biology, biology.protein, Phosphorylation, lcsh:Q, Signal transduction, 030217 neurology & neurosurgery, Jagged-1 Protein, Cell signalling, Signal Transduction

Abstract

The intermediate filament (IF) cytoskeleton has been proposed to regulate morphogenic processes by integrating the cell fate signaling machinery with mechanical cues. Signaling between endothelial cells (ECs) and vascular smooth muscle cells (VSMCs) through the Notch pathway regulates arterial remodeling in response to changes in blood flow. Here we show that the IF-protein vimentin regulates Notch signaling strength and arterial remodeling in response to hemodynamic forces. Vimentin is important for Notch transactivation by ECs and vimentin knockout mice (VimKO) display disrupted VSMC differentiation and adverse remodeling in aortic explants and in vivo. Shear stress increases Jagged1 levels and Notch activation in a vimentin-dependent manner. Shear stress induces phosphorylation of vimentin at serine 38 and phosphorylated vimentin interacts with Jagged1 and increases Notch activation potential. Reduced Jagged1-Notch transactivation strength disrupts lateral signal induction through the arterial wall leading to adverse remodeling. Taken together we demonstrate that vimentin forms a central part of a mechanochemical transduction pathway that regulates multilayer communication and structural homeostasis of the arterial wall.

Published

2019

9. Predicting and understanding collagen remodeling in human native heart valves during early development

Author

Carlijn V. C. Bouten, Frank P. T. Baaijens, S Sandra Loerakker, Tommaso Ristori, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., and Institute for Complex Molecular Systems

Subjects

0301 basic medicine, Cell traction, 0206 medical engineering, Biomedical Engineering, Mechanical stimuli, Embryonic Development, 02 engineering and technology, Biochemistry, Contact guidance, Biomaterials, 03 medical and health sciences, Fetus, Collagen/metabolism, Humans, Computer Simulation, Semilunar valves, Child, Preschool, Molecular Biology, Heart Valves/embryology, Collagen degradation, Chemistry, Native heart valve, Fetus/metabolism, Human heart, Computational modeling, General Medicine, 020601 biomedical engineering, Heart Valves, 030104 developmental biology, Child, Preschool, Collagen metabolism, Biophysics, Collagen, Collagen remodeling, Biotechnology

Abstract

The hemodynamic functionality of heart valves strongly depends on the distribution of collagen fibers, which are their main load-bearing constituents. It is known that collagen networks remodel in response to mechanical stimuli. Yet, the complex interplay between external load and collagen remodeling is poorly understood. In this study, we adopted a computational approach to simulate collagen remodeling occurring in native fetal and pediatric heart valves. The computational model accounted for several biological phenomena: cellular (re)orientation in response to both mechanical stimuli and topographical cues provided by collagen fibers; collagen deposition and traction forces along the main cellular direction; collagen degradation decreasing with stretch; and cell-mediated collagen prestretch. Importantly, the computational results were well in agreement with previous experimental data for all simulated heart valves. Simulations performed by varying some of the computational parameters suggest that cellular forces and (re)orientation in response to mechanical stimuli may be fundamental mechanisms for the emergence of the circumferential collagen alignment usually observed in native heart valves. On the other hand, the tendency of cells to coalign with collagen fibers is essential to maintain and reinforce that circumferential alignment during development. Statement of Significance: The hemodynamic functionality of heart valves is strongly influenced by the alignment of load-bearing collagen fibers. Currently, the mechanisms that are responsible for the development of the circumferential collagen alignment in native heart valves are not fully understood. In the present study, cell-mediated remodeling of native human heart valves during early development was computationally simulated to understand the impact of individual mechanisms on collagen alignment. Our simulations successfully predicted the degree of collagen alignment observed in native fetal and pediatric semilunar valves. The computational results suggest that the circumferential collagen alignment arises from cell traction and cellular (re)orientation in response to mechanical stimuli, and with increasing age is reinforced by the tendency of cells to co-align with pre-existing collagen fibers.

Published

2018

10. Strain mediated enzymatic degradation of arterial tissue: Insights into the role of the non-collagenous tissue matrix and collagen crimp

Author

Carlijn V. C. Bouten, Tommaso Ristori, D.R. Nolan, Caitríona Lally, S Sandra Loerakker, Robert Gaul, Soft Tissue Biomech. & Tissue Eng., Cardiovascular Biomechanics, and Institute for Complex Molecular Systems

Subjects

0301 basic medicine, Arterial tissue, Light, Swine, 0206 medical engineering, Collagenase, Biomedical Engineering, 02 engineering and technology, Matrix (biology), Stress, Biochemistry, Extracellular Matrix/chemistry, Numerical model, Scattering, Biomaterials, 03 medical and health sciences, medicine, Stress relaxation, Animals, Scattering, Radiation, Carotid Arteries/physiology, Collagenases, Molecular Biology, Process (anatomy), Radiation, Collagenases/chemistry, Strain (chemistry), Chemistry, Soft tissue, General Medicine, Mechanical, 020601 biomedical engineering, Elasticity, Extracellular Matrix, Biomechanical Phenomena, Carotid Arteries, 030104 developmental biology, Strain dependent degradation, Biophysics, Crimp, Degradation (geology), Collagen fibre degradation, Collagen, Stress, Mechanical, Biotechnology, medicine.drug, Collagen/chemistry

Abstract

Collagen fibre remodelling is a strain dependent process which is stimulated by the degradation of existing collagen. To date, literature has focussed on strain dependent degradation of pure collagen or structurally simple collagenous tissues, often overlooking degradation within more complex, heterogenous soft tissues. The aim of this study is to identify, for the first time, the strain dependent degradation behaviour and mechanical factors influencing collagen degradation in arterial tissue using a combined experimental and numerical approach. To achieve this, structural analysis was carried out using small angle light scattering to determine the fibre level response due to strain induced degradation. Next, strain dependent degradation rates were determined from stress relaxation experiments in the presence of crude and purified collagenase to determine the tissue level degradation response. Finally, a 1D theoretical model was developed, incorporating matrix stiffness and a gradient of collagen fibre crimp to decouple the mechanism behind strain dependent arterial degradation. SALS structural analysis identified a strain mediated degradation response in arterial tissue at the fibre level not dissimilar to that found in literature for pure collagen. Interestingly, two distinctly different strain mediated degradation responses were identified experimentally at the tissue level, not seen in other collagenous tissues. Our model was able to accurately predict these experimental findings, but only once the load bearing matrix, its degradation response and the gradient of collagen fibre crimp across the arterial wall were incorporated. These findings highlight the critical role that the various tissue constituents play in the degradation response of arterial tissue. Statement of Significance Collagen fibre architecture is the dominant load bearing component of arterial tissue. Remodelling of this architecture is a strain dependent process stimulated by the degradation of existing collagen. Despite this, degradation of arterial tissue and in particular, arterial collagen, is not fully understood or studied. In the current study, we identified for the first time, the strain dependent degradation response of arterial tissue, which has not been observed in other collagenous tissues in literature. We hypothesised that this unique degradation response was due to the complex structure observed in arterial tissue. Based on this hypothesis, we developed a novel numerical model capable of explaining this unique degradation response which may provide critical insights into disease development and aid in the design of interventional medical devices.

Published

2018

11. The mechanical contribution of vimentin to cellular stress generation

Author

Cees W. J. Oomens, Carlijn V. C. Bouten, Giulia Weissenberger, Inge A. E. W. van Loosdregt, Marc P.F.H.L. van Maris, S Sandra Loerakker, Oscar M. J. A. Stassen, Biomedical Engineering, Mechanics of Materials, Soft Tissue Biomech. & Tissue Eng., and Group Geers

Subjects

0301 basic medicine, Stress fiber, Finite Element Analysis, Biomedical Engineering, Vimentin, macromolecular substances, Stress, Microtubules, Stress (mechanics), Focal adhesion, 03 medical and health sciences, stress fibers, Gene Knockout Techniques, Mice, 0302 clinical medicine, Physiology (medical), fibroblasts, Animals, Cytoskeleton, Intermediate filament, Actin, Vimentin/deficiency, Focal Adhesions, biology, Chemistry, Focal Adhesions/metabolism, Adhesion, Mechanical, Actins, Biomechanical Phenomena, adhesion, 030104 developmental biology, Phenotype, thin films, Fibroblasts/cytology, Microtubules/metabolism, Actins/metabolism, 030220 oncology & carcinogenesis, modeling stiffness, Biophysics, biology.protein, Anisotropy, Stress, Mechanical

Abstract

Contractile stress generation by adherent cells is largely determined by the interplay of forces within their cytoskeleton. It is known that actin stress fibers, connected to focal adhesions, provide contractile stress generation, while microtubules and intermediate filaments provide cells compressive stiffness. Recent studies have shown the importance of the interplay between the stress fibers and the intermediate filament vimentin. Therefore, the effect of the interplay between the stress fibers and vimentin on stress generation was quantified in this study. We hypothesized that net stress generation comprises the stress fiber contraction combined with the vimentin resistance. We expected an increased net stress in vimentin knockout (VimKO) mouse embryonic fibroblasts (MEFs) compared to their wild-type (vimentin wild-type (VimWT)) counterparts, due to the decreased resistance against stress fiber contractility. To test this, the net stress generation by VimKO and VimWT MEFs was determined using the thin film method combined with sample-specific finite element modeling. Additionally, focal adhesion and stress fiber organization were examined via immunofluorescent staining. Net stress generation of VimKO MEFs was three-fold higher compared to VimWT MEFs. No differences in focal adhesion size or stress fiber organization and orientation were found between the two cell types. This suggests that the increased net stress generation in VimKO MEFs was caused by the absence of the resistance that vimentin provides against stress fiber contraction. Taken together, these data suggest that vimentin resists the stress fiber contractility, as hypothesized, thus indicating the importance of vimentin in regulating cellular stress generation by adherent cells.

Published

2018

12. Efficient computational simulation of actin stress fiber remodeling

Author

Cwj Cees Oomens, C Christine Obbink-Huizer, Frank Frank Baaijens, Tommaso Ristori, S Sandra Loerakker, and Soft Tissue Biomech. & Tissue Eng.

Subjects

0301 basic medicine, Cyclic strain, Stress fiber, cyclic strain, Computer science, Quantitative Biology::Tissues and Organs, 0206 medical engineering, Biomedical Engineering, Mechanical engineering, Bioengineering, 02 engineering and technology, Actin stress fiber remodeling, Computational simulation, 03 medical and health sciences, Stress Fibers, Computer Simulation, Actin, Tissue Engineering, analytical approximation, General Medicine, 020601 biomedical engineering, Actins, Computer Science Applications, Numerical integration, Human-Computer Interaction, ODE system with periodic coefficients, 030104 developmental biology, Anisotropy, Collagen, Biological system, Order of magnitude

Abstract

Understanding collagen and stress fiber remodeling is essential for the development of engineered tissues with good functionality. These processes are complex, highly interrelated, and occur over different time scales. As a result, excessive computational costs are required to computationally predict the final organization of these fibers in response to dynamic mechanical conditions. In this study, an analytical approximation of a stress fiber remodeling evolution law was derived. A comparison of the developed technique with the direct numerical integration of the evolution law showed relatively small differences in results, and the proposed method is one to two orders of magnitude faster.

Published

2016

13. Improved Geometry of Decellularized Tissue Engineered Heart Valves to Prevent Leaflet Retraction

Author

Dave J.P. Bax, Anita Anita Driessen-Mol, Frank P. T. Baaijens, Simon P. Hoerstrup, Bart Sanders, Emanuela S. Fioretta, S Sandra Loerakker, University of Zurich, Sanders, Bart, and Soft Tissue Biomech. & Tissue Eng.

Subjects

Materials science, 0206 medical engineering, Biomedical Engineering, Bioreactor, 2204 Biomedical Engineering, 610 Medicine & health, Geometry, 02 engineering and technology, 030204 cardiovascular system & hematology, Article, Extracellular matrix, 03 medical and health sciences, 0302 clinical medicine, Tissue engineering, Humans, Heart valve replacement, Decellularization, Tissue engineered, Leaflet (botany), Tissue Engineering, Computational modeling, 11359 Institute for Regenerative Medicine (IREM), Human cell, 020601 biomedical engineering, Heart Valves, Valvular insufficiency, Biomechanical Phenomena, Heart Valve Prosthesis, Repopulation, Collagen, Biomedical engineering

Abstract

Recent studies on decellularized tissue engineered heart valves (DTEHVs) showed rapid host cell repopulation and increased valvular insufficiency developing over time, associated with leaflet shortening. A possible explanation for this result was found using computational simulations, which revealed radial leaflet compression in the original valvular geometry when subjected to physiological pressure conditions. Therefore, an improved geometry was suggested to enable radial leaflet extension to counteract for host cell mediated retraction. In this study, we propose a solution to impose this new geometry by using a constraining bioreactor insert during culture. Human cell based DTEHVs (n = 5) were produced as such, resulting in an enlarged coaptation area and profound belly curvature. Extracellular matrix was homogeneously distributed, with circumferential collagen alignment in the coaptation region and global tissue anisotropy. Based on in vitro functionality experiments, these DTEHVs showed competent hydrodynamic functionality under physiological pulmonary conditions and were fatigue resistant, with stable functionality up to 16 weeks in vivo simulation. Based on implemented mechanical data, our computational models revealed a considerable decrease in radial tissue compression with the obtained geometrical adjustments. Therefore, these improved DTEHV are expected to be less prone to host cell mediated leaflet retraction and will remain competent after implantation.

Published

2015

14. Mechanosensitivity of Jagged–Notch signaling can induce a switch-type behavior in vascular homeostasis

Author

Cecilia Sahlgren, Fleur M. ter Huurne, Oscar M. J. A. Stassen, Marcelo Boareto, S Sandra Loerakker, Carlijn V. C. Bouten, Institute for Complex Molecular Systems, Soft Tissue Biomech. & Tissue Eng., Cell-Matrix Interact. Cardiov. Tissue Reg., and Biomedical Engineering

Subjects

0301 basic medicine, Notch, Vascular smooth muscle, Vascular homeostasis, Myocytes, Smooth Muscle, Video Recording, Notch signaling pathway, Hemodynamics, Cell Cycle Proteins, Ligands, Mechanotransduction, Cellular, Models, Biological, Muscle, Smooth, Vascular, Mechanosensitivity, 03 medical and health sciences, Basic Helix-Loop-Helix Transcription Factors, Morphogenesis, Humans, Homeostasis, ta318, Computer Simulation, Receptor, Notch3, Hemodynamic forces, Aged, Multidisciplinary, Mechanical load, Chemistry, Endothelial Cells, Correction, Arteries, Middle Aged, Vascular geometry, Cell biology, Repressor Proteins, 030104 developmental biology, Gene Expression Regulation, Transcription Factor HES-1, Stress, Mechanical, Jagged, Jagged-1 Protein, Muscle Contraction

Abstract

Hemodynamic forces and Notch signaling are both known as key regulators of arterial remodeling and homeostasis. However, how these two factors integrate in vascular morphogenesis and homeostasis is unclear. Here, we combined experiments and modeling to evaluate the impact of the integration of mechanics and Notch signaling on vascular homeostasis. Vascular smooth muscle cells (VSMCs) were cyclically stretched on flexible membranes, as quantified via video tracking, demonstrating that the expression of Jagged1, Notch3, and target genes was down-regulated with strain. The data were incorporated in a computational framework of Notch signaling in the vascular wall, where the mechanical load was defined by the vascular geometry and blood pressure. Upon increasing wall thickness, the model predicted a switch-type behavior of the Notch signaling state with a steep transition of synthetic toward contractile VSMCs at a certain transition thickness. These thicknesses varied per investigated arterial location and were in good agreement with human anatomical data, thereby suggesting that the Notch response to hemodynamics plays an important role in the establishment of vascular homeostasis., Proceedings of the National Academy of Sciences of the United States of America, 115 (16), ISSN:0027-8424, ISSN:1091-6490

Published

2018

15. Nondestructive mechanical characterization of developing biological tissues using inflation testing

Author

Carlijn V. C. Bouten, S Sandra Loerakker, Pim J A Oomen, M. A.J. van Kelle, Cees W. J. Oomens, and Soft Tissue Biomech. & Tissue Eng.

Subjects

0301 basic medicine, Materials science, Mechanical characterization, 0206 medical engineering, Finite Element Analysis, Biomedical Engineering, Inverse analysis, 02 engineering and technology, Stress, Displacement (vector), Biomechanical Phenomena, Biomaterials, 03 medical and health sciences, Bioreactors, Ultrasound, Materials Testing, Tissue Engineering/methods, Inverse method, Tensile testing, Ultrasonography, Tissue Engineering, Soft tissues, Mechanical, 020601 biomedical engineering, Finite element method, Characterization (materials science), 030104 developmental biology, Mechanics of Materials, Stress, Mechanical, Material properties, Growth and remodeling, Biomedical engineering

Abstract

One of the hallmarks of biological soft tissues is their capacity to grow and remodel in response to changes in their environment. Although it is well-accepted that these processes occur at least partly to maintain a mechanical homeostasis, it remains unclear which mechanical constituent(s) determine(s) mechanical homeostasis. In the current study a nondestructive mechanical test and a two-step inverse analysis method were developed and validated to nondestructively estimate the mechanical properties of biological tissue during tissue culture. Nondestructive mechanical testing was achieved by performing an inflation test on tissues that were cultured inside a bioreactor, while the tissue displacement and thickness were nondestructively measured using ultrasound. The material parameters were estimated by an inverse finite element scheme, which was preceded by an analytical estimation step to rapidly obtain an initial estimate that already approximated the final solution. The efficiency and accuracy of the two-step inverse method was demonstrated on virtual experiments of several material types with known parameters. PDMS samples were used to demonstrate the method's feasibility, where it was shown that the proposed method yielded similar results to tensile testing. Finally, the method was applied to estimate the material properties of tissue-engineered constructs. Via this method, the evolution of mechanical properties during tissue growth and remodeling can now be monitored in a well-controlled system. The outcomes can be used to determine various mechanical constituents and to assess their contribution to mechanical homeostasis.

Published

2017

16. A Bioreactor to Identify the Driving Mechanical Stimuli of Tissue Growth and Remodeling

Author

Mathieu A.J. van Kelle, Marcel C. M. Rutten, Marloes W J T Janssen-van den Broek, Jurgen A Bulsink, Pim J A Oomen, Richard G.P. Lopata, S Sandra Loerakker, Carlijn V. C. Bouten, Soft Tissue Biomech. & Tissue Eng., Institute for Complex Molecular Systems, and Cardiovascular Biomechanics

Subjects

0301 basic medicine, Materials science, 0206 medical engineering, Biomedical Engineering, Cell Culture Techniques, Medicine (miscellaneous), Bioengineering, 02 engineering and technology, Mechanotransduction, Cellular, biomechanics, Extracellular matrix, 03 medical and health sciences, Tissue culture, bioreactor, Bioreactors, Tissue engineering, Bulge test, Bioreactor, Humans, Myofibroblasts, Tissue Engineering, Biomechanics, 020601 biomedical engineering, Extracellular Matrix, 030104 developmental biology, Cell culture, Ultrasound imaging, Biomedical engineering, growth and remodeling

Abstract

Tissue growth and remodeling are essential processes that should ensure long-term functionality of tissue-engineered (TE) constructs. Even though it is widely recognized that these processes strongly depend on mechanical stimuli, the underlying mechanisms of mechanically induced growth and remodeling are only partially understood. It is generally accepted that cells sense mechanical changes and respond by altering their surroundings, by means of extracellular matrix growth and remodeling, in an attempt to return to a certain preferred mechanical homeostatic state. However, the exact mechanical cues that trigger cells to synthesize and remodel their environment remain unclear. To identify the driving mechanical stimuli of these processes, it is critical to be able to temporarily follow the mechanical state of developing tissues under physiological loading conditions. Therefore, a novel "versatile tissue growth and remodeling" (Vertigro) bioreactor was developed that is capable of tissue culture and mechanical stimulation for a prolonged time period, while simultaneously performing mechanical testing. The Vertigro's unique two-chamber design allows easy, sterile handling of circular 3D TE constructs in a dedicated culture chamber, while a separate pressure chamber facilitates a pressure-driven dynamic loading regime during culture. As a proof-of-concept, temporal changes in the mechanical state of cultured tissues were quantified using nondestructive mechanical testing by means of a classical bulge test, in which the tissue displacement was tracked using ultrasound imaging. To demonstrate the successful development of the bioreactor system, compositional, structural, and geometrical changes were qualitatively and quantitatively assessed using a series of standard analysis techniques. With this bioreactor and associated mechanical analysis technique, a powerful toolbox has been developed to quantitatively study and identify the driving mechanical stimuli of engineered tissue growth and remodeling.

Published

2017

17. Computational modeling guides tissue-engineered heart valve design for long-term in vivo performance in a translational sheep model

Author

Simon P. Hoerstrup, Frank P. T. Baaijens, Leon Bruder, Bart Sanders, Felix Berger, Petra E. Dijkman, Kerstin Brakmann, Emanuela S. Fioretta, Hendrik Spriestersbach, Sarah E. Motta, Valentina Lintas, S Sandra Loerakker, Laura Frese, Maximilian Y. Emmert, Boris Schmitt, University of Zurich, Hoerstrup, Simon P, Institute for Complex Molecular Systems, and Soft Tissue Biomech. & Tissue Eng.

Subjects

Time Factors, Vascular/physiology, 02 engineering and technology, 2700 General Medicine, 030204 cardiovascular system & hematology, Translational Research, Biomedical, 0302 clinical medicine, Heart valve tissue engineering, Models, Tissue Engineering/methods, Translational Medical Research, Heart Valve Prosthesis Implantation, valvular heart disease, General Medicine, 11359 Institute for Regenerative Medicine (IREM), Magnetic Resonance Imaging, medicine.anatomical_structure, Actins/metabolism, Heart Valve Prosthesis, Models, Animal, Female, Pulmonary Valve/physiology, Endothelium, Vascular/physiology, 0206 medical engineering, 610 Medicine & health, Prosthesis Design, Transcatheter Aortic Valve Replacement, 03 medical and health sciences, In vivo, medicine, Animals, Computer Simulation, Heart valve, Endothelium, Pulmonary Valve, Tissue engineered, Sheep, Tissue Engineering, business.industry, Animal, Regeneration (biology), Hemodynamics, medicine.disease, 020601 biomedical engineering, Actins, 10020 Clinic for Cardiac Surgery, Pulmonary valve, Implant, Endothelium, Vascular, business, Biomedical engineering

Abstract

Valvular heart disease is a major cause of morbidity and mortality worldwide. Current heart valve prostheses have considerable clinical limitations due to their artificial, nonliving nature without regenerative capacity. To overcome these limitations, heart valve tissue engineering (TE) aiming to develop living, native-like heart valves with self-repair, remodeling, and regeneration capacity has been suggested as next-generation technology. A major roadblock to clinically relevant, safe, and robust TE solutions has been the high complexity and variability inherent to bioengineering approaches that rely on cell-driven tissue remodeling. For heart valve TE, this has limited long-term performance in vivo because of uncontrolled tissue remodeling phenomena, such as valve leaflet shortening, which often translates into valve failure regardless of the bioengineering methodology used to develop the implant. We tested the hypothesis that integration of a computationally inspired heart valve design into our TE methodologies could guide tissue remodeling toward long-term functionality in tissue-engineered heart valves (TEHVs). In a clinically and regulatory relevant sheep model, TEHVs implanted as pulmonary valve replacements using minimally invasive techniques were monitored for 1 year via multimodal in vivo imaging and comprehensive tissue remodeling assessments. TEHVs exhibited good preserved long-term in vivo performance and remodeling comparable to native heart valves, as predicted by and consistent with computational modeling. TEHV failure could be predicted for nonphysiological pressure loading. Beyond previous studies, this work suggests the relevance of an integrated in silico, in vitro, and in vivo bioengineering approach as a basis for the safe and efficient clinical translation of TEHVs.

Published

2017

18. Tissue alignment enhances remodeling potential of tendon-derived cells - Lessons from a novel microtissue model of tendon scarring

Author

Jess G. Snedeker, Stefania L. Wunderli, Jasper Foolen, S Sandra Loerakker, Orthopaedic Biomechanics, Soft Tissue Biomech. & Tissue Eng., University of Zurich, and Snedeker, Jess G

Subjects

0301 basic medicine, Cells, 0206 medical engineering, 610 Medicine & health, 02 engineering and technology, Matrix (biology), Matrix metalloproteinase, Models, Biological, Tendon Injuries/metabolism, Extracellular matrix, Tendons, 03 medical and health sciences, Cicatrix, Mice, Models, Tendon Injuries, ddc:570, 1312 Molecular Biology, medicine, Animals, Molecular Biology, Process (anatomy), Actin, Cells, Cultured, Wound Healing, Cultured, Tissue Scaffolds, Chemistry, Anatomy, Biological, medicine.disease, Life sciences, 020601 biomedical engineering, Actins, Tendon, Cell biology, Tendons/cytology, 030104 developmental biology, medicine.anatomical_structure, Actins/metabolism, Cicatrix/metabolism, 10046 Balgrist University Hospital, Swiss Spinal Cord Injury Center, Tendinopathy, Wound healing

Abstract

Tendinopathy is a widespread and unresolved clinical challenge, in which associated pain and hampered mobility present a major cause for work-related disability. Tendinopathy associates with a change from a healthy tissue with aligned extracellular matrix (ECM) and highly polarized cells that are connected head-to-tail, towards a diseased tissue with a disorganized ECM and randomly distributed cells, scar-like features that are commonly attributed to poor innate regenerative capacity of the tissue. A fundamental clinical dilemma with this scarring process is whether treatment strategies should focus on healing the affected (disorganized) tissue or strengthen the remaining healthy (anisotropic) tissue. The question was thus asked whether the intrinsic remodeling capacity of tendon-derived cells depends on the organization of the 3D extracellular matrix (isotropic vs anisotropic). Progress in this field is hampered by the lack of suitable in vitro tissue platforms. We aimed at filling this critical gap by creating and exploiting a next generation tissue platform that mimics aspects of the tendon scarring process; cellular response to a gradient in tissue organization from isotropic (scarred/non-aligned) to highly anisotropic (unscarred/aligned) was studied, as was a transient change from isotropic towards highly anisotropic. Strikingly, cells residing in an ‘unscarred’ anisotropic tissue indicated superior remodeling capacity (increased gene expression levels of collagen, matrix metalloproteinases MMPs, tissue inhibitors of MMPs), when compared to their ‘scarred’ isotropic counterparts. A numerical model then supported the hypothesis that cellular remodeling capacity may correlate to cellular alignment strength. This in turn may have improved cellular communication, and could thus relate to the more pronounced connexin43 gap junctions observed in anisotropic tissues. In conclusion, increased tissue anisotropy was observed to enhance the cellular potential for functional remodeling of the matrix. This may explain the poor regenerative capacity of tenocytes in chronic tendinopathy, where the pathological process has resulted in ECM disorganization. Additionally, it lends support to treatment strategies that focus on strengthening the remaining healthy tissue, rather than regenerating scarred tissue., Matrix Biology, 65, ISSN:0945-053X, ISSN:1569-1802

Published

2017

19. Initial scaffold thickness affects the emergence of a geometrical and mechanical equilibrium in engineered cardiovascular tissues

Author

Richard G.P. Lopata, W. J.T. Janssen-van den Broek, Carlijn V. C. Bouten, Pim J A Oomen, S Sandra Loerakker, M. A.J. van Kelle, Institute for Complex Molecular Systems, Cell-Matrix Interact. Cardiov. Tissue Reg., Soft Tissue Biomech. & Tissue Eng., and Cardiovascular Biomechanics

Subjects

Scaffold, Mechanical equilibrium, Materials science, Thermodynamic equilibrium, growth, 0206 medical engineering, Biomedical Engineering, Biophysics, Bioengineering, Tissue-engineering, 02 engineering and technology, 030204 cardiovascular system & hematology, Biochemistry, law.invention, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, Tissue engineering, law, Humans, Two sample, Myofibroblasts, Life Sciences–Engineering interface, Stable state, Tissue Engineering, Tissue Scaffolds, cardiovascular, Remodelling, Models, Cardiovascular, Arteries, Heart Valves, 020601 biomedical engineering, Dynamic loading, Mechanical stability, Biotechnology, Biomedical engineering

Abstract

In situ cardiovascular tissue-engineering can potentially address the shortcomings of the current replacement therapies, in particular, their inability to grow and remodel. In native tissues, it is widely accepted that physiological growth and remodelling occur to maintain a homeostatic mechanical state to conserve its function, regardless of changes in the mechanical environment. A similar homeostatic state should be reached for tissue-engineered (TE) prostheses to ensure proper functioning. For in situ tissue-engineering approaches obtaining such a state greatly relies on the initial scaffold design parameters. In this study, it is investigated if the simple scaffold design parameter initial thickness, influences the emergence of a mechanical and geometrical equilibrium state in in vitro TE constructs, which resemble thin cardiovascular tissues such as heart valves and arteries. Towards this end, two sample groups with different initial thicknesses of myofibroblast-seeded polycaprolactone-bisurea constructs were cultured for three weeks under dynamic loading conditions, while tracking geometrical and mechanical changes temporally using non-destructive ultrasound imaging. A mechanical equilibrium was reached in both groups, although at different magnitudes of the investigated mechanical quantities. Interestingly, a geometrically stable state was only established in the thicker constructs, while the thinner constructs’ length continuously increased. This demonstrates that reaching geometrical and mechanical stability in TE constructs is highly dependent on functional scaffold design.

Published

2018

20. Effects of Valve Geometry and Tissue Anisotropy on the Radial Stretch and Coaptation Area of Tissue-Engineered Heart Valves

Author

Frank Frank Baaijens, G Giulia Argento, Cwj Cees Oomens, S Sandra Loerakker, University of Zurich, Loerakker, S, and Soft Tissue Biomech. & Tissue Eng.

Subjects

Pulmonary Diastolic Pressure, Materials science, 0206 medical engineering, Finite Element Analysis, Biophysics, Biomedical Engineering, 2204 Biomedical Engineering, Geometry, 610 Medicine & health, 02 engineering and technology, Regurgitation (circulation), 030204 cardiovascular system & hematology, 03 medical and health sciences, 0302 clinical medicine, 2732 Orthopedics and Sports Medicine, Tissue scaffolds, Tissue engineering, Humans, Leaflet retraction, Orthopedics and Sports Medicine, Finite element modeling, Anisotropy, Bioprosthesis, Tissue engineered, Deformation (mechanics), Tissue Engineering, Tissue Scaffolds, Rehabilitation, Models, Cardiovascular, 020601 biomedical engineering, Heart Valves, Finite element method, Valvular insufficiency, Biomechanical Phenomena, 10020 Clinic for Cardiac Surgery, Ventricular failure, 2742 Rehabilitation, Constitutive modeling, Heart Valve Prosthesis, Collagen, Material properties, 1304 Biophysics, Biomedical engineering

Abstract

Tissue engineering represents a promising technique to overcome the limitations of the current valve replacements, since it allows for creating living autologous heart valves that have the potential to grow and remodel. However, also this approach still faces a number of challenges. One particular problem is regurgitation, caused by cell-mediated tissue retraction or the mismatch in geometrical and material properties between tissue-engineered heart valves (TEHVs) and their native counterparts. The goal of the present study was to assess the influence of valve geometry and tissue anisotropy on the deformation profile and closed configuration of TEHVs. To achieve this aim, a range of finite element models incorporating different valve shapes was developed, and the constitutive behavior of the tissue was modeled using an established computational framework, where the degree of anisotropy was varied between values representative of TEHVs and native valves. The results of this study suggest that valve geometry and tissue anisotropy are both important to maximize the radial strains and thereby the coaptation area. Additionally, the minimum degree of anisotropy that is required to obtain positive radial strains was shown to depend on the valve shape and the pressure to which the valves are exposed. Exposure to pulmonary diastolic pressure only yielded positive radial strains if the anisotropy was comparable to the native situation, whereas considerably less anisotropy was required if the valves were exposed to aortic diastolic pressure.

Published

2013

21. A computational analysis of cell-mediated compaction and collagen remodeling in tissue-engineered heart valves

Author

Tommaso Ristori, Frank Frank Baaijens, S Sandra Loerakker, and Soft Tissue Biomech. & Tissue Eng.

Subjects

0301 basic medicine, medicine.medical_specialty, Materials science, 0206 medical engineering, Biomedical Engineering, 02 engineering and technology, Cell traction, Valvular insufficiency, Biomaterials, 03 medical and health sciences, Heart valve tissue engineering, Tissue engineering, Internal medicine, medicine.artery, Collagen network, medicine, Humans, Process (anatomy), Aorta, Tissue Engineering, Models, Cardiovascular, Computational Biology, Computational modeling, Heart Valves, 020601 biomedical engineering, 030104 developmental biology, Blood pressure, Mechanics of Materials, Heart Valve Prosthesis, Cardiology, Aortic pressure, cardiovascular system, Collagen, Collagen remodeling

Abstract

One of the most critical problems in heart valve tissue engineering is the progressive development of valvular insufficiency due to leaflet retraction. Understanding the underlying mechanisms of this process is crucial for developing tissue-engineered heart valves (TEHVs) that maintain their functionality in the long term. In the present study, we adopted a computational approach to predict the remodeling process in TEHVs subjected to dynamic pulmonary and aortic pressure conditions, and to assess the risk of valvular insufficiency. In addition, we investigated the importance of the intrinsic cell contractility on the final outcome of the remodeling process. For valves implanted in the aortic position, the model predictions suggest that valvular insufficiency is not likely to occur as the blood pressure is high enough to prevent the development of leaflet retraction. In addition, the collagen network was always predicted to remodel towards a circumferentially aligned network, which is corresponding to the native situation. In contrast, for valves implanted in the pulmonary position, our model predicted that there is a high risk for the development of valvular insufficiency, unless the cell contractility is very low. Conversely, the development of a circumferential collagen network was only predicted at these pressure conditions when cell contractility was high. Overall, these results, therefore, suggest that tissue remodeling at aortic pressure conditions is much more stable and favorable compared to tissue remodeling at pulmonary pressure conditions.

22. Next-generation tissue-engineered heart valves with repair, remodelling and regeneration capacity

Author

Simon P. Hoerstrup, Emanuela S. Fioretta, Kevin Kit Parker, Maximilian Y. Emmert, Valentina Lintas, Volkmar Falk, Sarah E. Motta, S Sandra Loerakker, Frank P. T. Baaijens, University of Zurich, and Emmert, Maximilian Y

Subjects

0301 basic medicine, medicine.medical_specialty, Tissue engineered, Standard of care, business.industry, Regeneration (biology), valvular heart disease, 610 Medicine & health, 11359 Institute for Regenerative Medicine (IREM), 030204 cardiovascular system & hematology, medicine.disease, 2705 Cardiology and Cardiovascular Medicine, 3. Good health, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Heart valve tissue engineering, Valvular disease, medicine, Heart valve replacement, Heart valve, Cardiology and Cardiovascular Medicine, Intensive care medicine, business

Abstract

Valvular heart disease is a major cause of morbidity and mortality worldwide. Surgical valve repair or replacement has been the standard of care for patients with valvular heart disease for many decades, but transcatheter heart valve therapy has revolutionized the field in the past 15 years. However, despite the tremendous technical evolution of transcatheter heart valves, to date, the clinically available heart valve prostheses for surgical and transcatheter replacement have considerable limitations. The design of next-generation tissue-engineered heart valves (TEHVs) with repair, remodelling and regenerative capacity can address these limitations, and TEHVs could become a promising therapeutic alternative for patients with valvular disease. In this Review, we present a comprehensive overview of current clinically adopted heart valve replacement options, with a focus on transcatheter prostheses. We discuss the various concepts of heart valve tissue engineering underlying the design of next-generation TEHVs, focusing on off-the-shelf technologies. We also summarize the latest preclinical and clinical evidence for the use of these TEHVs and describe the current scientific, regulatory and clinical challenges associated with the safe and broad clinical translation of this technology.

23. Intrinsic Cell Stress is Independent of Organization in Engineered Cell Sheets

Author

Sylvia Dekker, Patrick W. Alford, S Sandra Loerakker, Carlijn V. C. Bouten, Cees W. J. Oomens, Inge A. E. W. van Loosdregt, Institute for Complex Molecular Systems, Soft Tissue Biomech. & Tissue Eng., and Cell-Matrix Interact. Cardiov. Tissue Reg.

Subjects

0301 basic medicine, Stress fiber, Mechanotransduction, Surface Properties, Cell alignment, Cell, Finite Element Analysis, Biomedical Engineering, Cell Communication, Mechanotransduction, Cellular, Models, Biological, Article, Contractility, 03 medical and health sciences, Tissue engineering, Stress Fibers, medicine, Humans, Dimethylpolysiloxanes, Myofibroblasts, Finite element modeling, Cell Shape, Actin, Cells, Cultured, biology, Tissue Engineering, Chemistry, Cardiovascular tissue engineering, Fibronectins, Fibronectin, 030104 developmental biology, medicine.anatomical_structure, biology.protein, Biophysics, Stress, Mechanical, Cardiology and Cardiovascular Medicine, Myofibroblast, Biomedical engineering

Abstract

Understanding cell contractility is of fundamental importance for cardiovascular tissue engineering, due to its major impact on the tissue’s mechanical properties as well as the development of permanent dimensional changes, e.g., by contraction or dilatation of the tissue. Previous attempts to quantify contractile cellular stresses mostly used strongly aligned monolayers of cells, which might not represent the actual organization in engineered cardiovascular tissues such as heart valves. In the present study, therefore, we investigated whether differences in organization affect the magnitude of intrinsic stress generated by individual myofibroblasts, a frequently used cell source for in vitro engineered heart valves. Four different monolayer organizations were created via micro-contact printing of fibronectin lines on thin PDMS films, ranging from strongly anisotropic to isotropic. Thin film curvature, cell density, and actin stress fiber distribution were quantified, and subsequently, intrinsic stress and contractility of the monolayers were determined by incorporating these data into sample-specific finite element models. Our data indicate that the intrinsic stress exerted by the monolayers in each group correlates with cell density. Additionally, after normalizing for cell density and accounting for differences in alignment, no consistent differences in intrinsic contractility were found between the different monolayer organizations, suggesting that the intrinsic stress exerted by individual myofibroblasts is independent of the organization. Consequently, this study emphasizes the importance of choosing proper architectural properties for scaffolds in cardiovascular tissue engineering, as these directly affect the stresses in the tissue, which play a crucial role in both the functionality and remodeling of (engineered) cardiovascular tissues.

24. Mechano-regulated cell–cell signaling in the context of cardiovascular tissue engineering

Author

Cecilia Sahlgren, Tommaso Ristori, Jordy G. M. van Asten, S Sandra Loerakker, and Cansu Karakaya

Subjects

Mechano-regulation, Cell, Context (language use), Cell Communication, 030204 cardiovascular system & hematology, Biology, Mechanobiology, 03 medical and health sciences, 0302 clinical medicine, Tissue engineering, medicine, Engineered tissue, 030304 developmental biology, 0303 health sciences, Tissue Engineering, Tissue organization, Mechanical Engineering, Mechano regulation, Computational modeling, Heart Valves, Biomechanical Phenomena, Cell–cell signaling, medicine.anatomical_structure, Modeling and Simulation, Cell-cell signaling, Neuroscience, Growth and remodeling, Signal Transduction, Biotechnology

Abstract

Cardiovascular tissue engineering (CVTE) aims to create living tissues, with the ability to grow and remodel, as replacements for diseased blood vessels and heart valves. Despite promising results, the (long-term) functionality of these engineered tissues still needs improvement to reach broad clinical application. The functionality of native tissues is ensured by their specific mechanical properties directly arising from tissue organization. We therefore hypothesize that establishing a native-like tissue organization is vital to overcome the limitations of current CVTE approaches. To achieve this aim, a better understanding of the growth and remodeling (G&R) mechanisms of cardiovascular tissues is necessary. Cells are the main mediators of tissue G&R, and their behavior is strongly influenced by both mechanical stimuli and cell–cell signaling. An increasing number of signaling pathways has also been identified as mechanosensitive. As such, they may have a key underlying role in regulating the G&R of tissues in response to mechanical stimuli. A more detailed understanding of mechano-regulated cell–cell signaling may thus be crucial to advance CVTE, as it could inspire new methods to control tissue G&R and improve the organization and functionality of engineered tissues, thereby accelerating clinical translation. In this review, we discuss the organization and biomechanics of native cardiovascular tissues; recent CVTE studies emphasizing the obtained engineered tissue organization; and the interplay between mechanical stimuli, cell behavior, and cell–cell signaling. In addition, we review past contributions of computational models in understanding and predicting mechano-regulated tissue G&R and cell–cell signaling to highlight their potential role in future CVTE strategies.