Your search keyword '"Extracellular Matrix chemistry"' showing total 5,500 results

1. Liquid crystalline collagen assemblies as substrates for directed alignment of human Schwann cells.

Author

Ghaiedi H, Pinzon Herrera LC, Alshafeay S, Harris L, Almodovar J, and Nayani K

Subjects

Humans, Collagen chemistry, Hydrogels chemistry, Extracellular Matrix chemistry, Extracellular Matrix metabolism, Collagen Type I chemistry, Collagen Type I metabolism, Schwann Cells cytology, Schwann Cells metabolism, Liquid Crystals chemistry

Abstract

Collagen is a key component of the extracellular matrix (ECM) and well-oriented domains of collagen are important for mimicking the local cell environment in vitro . While there has been significant attention directed towards the alignment of collagen, formation of large-scale oriented domains remains a key challenge. Type I collagen self-assembles to form liquid crystalline (LC) mesophases in acidic conditions at concentrations above 100 mg mL -1 . The LC mesophase provides an efficient platform for large-scale alignment and patterning of collagen coated substrates. However, there still exist challenges related to solubilizing and processing of collagen at such high concentrations in order to replicate the native ECM. In this contribution, we report on centimeter-scale alignment in collagen-coated glass substrates using solutions that are well below the LC-forming concentrations. Importantly, we are also able to extend this method to macroscopic 3-D LC-collagen hydrogels with programmed anisotropy within them to create a mimic of the native ECM. We show that the orientation and aspect ratio of human Schwann cells are strongly coupled with the alignment of the collagen substrate/hydrogel. We use a simple model to estimate the critical magnetic field strength needed for a given concentration of collagen to permit macroscopic alignment-enabling guidance for future studies on alignment of collagen at high concentrations.

Published

2024

2. Extracellular Matrix Limits Nanoparticle Diffusion and Cellular Uptake in a Tissue-Specific Manner.

Author

Cahn D, Stern A, Buckenmeyer M, Wolf M, and Duncan GA

Subjects

Diffusion, Animals, Humans, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Nanoparticles chemistry, Nanoparticles metabolism, Polyethylene Glycols chemistry

Abstract

Overexpression and remodeling of the extracellular matrix (ECM) in cancer and other diseases may significantly reduce the ability of nanoparticles to reach target sites, preventing the effective delivery of therapeutic cargo. Here, we evaluate how tissue-specific properties of the ECM affect nanoparticle diffusion using fluorescence video microscopy and cellular uptake via flow cytometry. In addition, we determined how poly(ethylene glycol) (PEG) chain length and branching influence the ability of PEGylated nanoparticles to overcome the ECM barrier from different tissues. We found that purified collagen, in the absence of other ECM proteins and polysaccharides, presented a greater barrier to nanoparticle diffusion compared to the decellularized ECM from the liver, lung, and small intestine submucosa. Nanoparticles with dense PEG coatings achieved up to ∼2000-fold enhancements in diffusion rate and cellular uptake up to ∼5-fold greater than non-PEGylated nanoparticles in the presence of the ECM. We also found nanoparticle mobility in the ECM varied significantly between tissue types, and the optimal nanoparticle PEGylation strategy to enhance ECM penetration was strongly dependent on ECM concentration. Overall, our data support the use of low molecular weight PEG coatings which provide an optimal balance of nanoparticle penetration through the ECM and uptake in target cells. However, tissue-specific enhancements in ECM penetration and cellular uptake were observed for nanoparticles bearing a branched PEG coating. These studies provide insights into tissue specific ECM barrier functions, which can facilitate the design of nanoparticles that effectively transport through target tissues, improving their therapeutic efficacy.

Published

2024

3. A simulated microgravity-oriented AIE probe-ECM hydrogel-integrated chip for cell culture and superoxide anion radical detection.

Author

Su Z, Liu B, Dai J, Han M, Lai JC, Wang S, Chen Y, Zhao Y, Zhang R, Ma H, Deng Y, and Li Z

Subjects

Humans, Extracellular Matrix chemistry, Cell Culture Techniques instrumentation, Weightlessness Simulation, Equipment Design, Fluorescent Dyes chemistry, Lab-On-A-Chip Devices, Weightlessness, Oxidative Stress, Superoxides analysis, Biosensing Techniques instrumentation, Biosensing Techniques methods, Hydrogels chemistry

Abstract

Human space activities have been continuously increasing. Astronauts experiencing spaceflight are faced with health problems caused by special space environments such as microgravity, and the investigation of cell injury is fundamental. The development of a platform capable of cell culture and injury detection is the prerequisite for the investigation. Constructing a platform suitable for special conditions in space life science research is the key issue. The ground-based investigation is an indispensable part of the research. Accordingly, a simulated microgravity (SMG)-oriented integrated chip platform capable of 3D cell culture and in situ visual detection of superoxide anion radical (O 2 •- ) is developed. SMG can cause oxidative stress in human cells, and O 2 •- is one of the signaling molecules. Thus, a O 2 •- -responsive aggregation-induced emission (AIE) probe is designed, which shows high selectivity and sensitivity to O 2 •- . Moreover, the probe exhibits abilities of long-term and wash-free staining to cells due to the AIE behavior, which is precious for space cell imaging. Meanwhile, a chip with a high-aspect-ratio chamber for adequate medium storage for the lack of the perfusion system during the SMG experiment and a cell culture chamber which can integrate the extracellular matrix (ECM) hydrogel for the bioinspired 3D cell culture is fabricated. In addition, a porous membrane is introduced between the chambers to prevent the hydrogel from separating during the SMG experiment. The afforded AIE probe-ECM hydrogel-integrated chip can achieve 3D culturing of U87-MG cells and in situ fluorescent detection of endogenous O 2 •- in the cells after long-term staining under SMG. The chip provides a powerful and potential platform for ground-based investigation in space life science and biomedical research., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024. Published by Elsevier B.V.)

Published

2024

4. Predicting anti-tumor efficacy of multi-functional nanomedicine on decellularized hepatocellular carcinoma-on-a-chip.

Author

Chen Y, Lin G, Wang Z, He J, Yang G, Lin Z, Gong C, Liu N, Li F, Tong D, Lin Y, Ding J, and Zhang J

Subjects

Humans, Hep G2 Cells, Animals, Liposomes chemistry, Extracellular Matrix chemistry, Extracellular Matrix drug effects, Ferric Compounds chemistry, Biosensing Techniques methods, Tumor Microenvironment drug effects, Antineoplastic Agents pharmacology, Antineoplastic Agents chemistry, Antineoplastic Agents therapeutic use, Liver Neoplasms drug therapy, Liver Neoplasms pathology, Carcinoma, Hepatocellular drug therapy, Carcinoma, Hepatocellular pathology, Carcinoma, Hepatocellular therapy, Doxorubicin pharmacology, Doxorubicin chemistry, Doxorubicin therapeutic use, Lab-On-A-Chip Devices, Nanomedicine methods

Abstract

Traditional hepatocellular carcinoma-chip models lack the cell structure and microenvironments necessary for high pathophysiological correlation, leading to low accuracy in predicting drug efficacy and high production costs. This study proposed a decellularized hepatocellular carcinoma-on-a-chip model to screen anti-tumor nanomedicine. In this model, human hepatocellular carcinoma (HepG2) and human normal liver cells (L02) were co-cultured on a three-dimensional (3D) decellularized extracellular matrix (dECM) in vitro to mimic the tumor microenvironments of human hepatocellular carcinoma in vivo. Additionally, a smart nanomedicine was developed by encapsulating doxorubicin (DOX) into the ferric oxide (Fe 3 O 4 )-incorporated liposome nanovesicle (NLV/Fe+DOX). NLV/Fe+DOX selectively killed 78.59% ± 6.78% of HepG2 cells through targeted delivery and synergistic chemo-chemodynamic-photothermal therapies, while the viability of surrounding L02 cells on the chip model retained high, at over 90.0%. The drug efficacy tested using this unique chip model correlated well with the results of cellular and animal experiments. In summary, our proposed hepatocellular carcinoma-chip model is a low-cost yet accurate drug-testing platform with significant potential for drug screening., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier B.V. All rights reserved.)

Published

2024

5. Design and Applications of Supramolecular Peptide Hydrogel as Artificial Extracellular Matrix.

Author

Li W, Li L, Hu J, Zhou D, and Su H

Subjects

Humans, Animals, Biocompatible Materials chemistry, Nanofibers chemistry, Extracellular Matrix chemistry, Hydrogels chemistry, Hydrogels pharmacology, Peptides chemistry, Peptides pharmacology, Tissue Engineering methods

Abstract

Supramolecular peptide hydrogels (SPHs) consist of peptides containing hydrogelators and functional epitopes, which can first self-assemble into nanofibers and then physically entangle together to form dynamic three-dimensional networks. Their porous structures, excellent bioactivity, and high dynamicity, similar to an extracellular matrix (ECM), have great potential in artificial ECM. The properties of the hydrogel are largely dependent on peptides. The noncovalent interactions among hydrogelators drive the formation of assemblies and further transition into hydrogels, while bioactive epitopes modulate cell-cell and cell-ECM interactions. Therefore, SPHs can support cell growth, making them ideal biomaterials for ECM mimics. This Review outlines the classical molecular design of SPHs from hydrogelators to functional epitopes and summarizes the recent advancements of SPHs as artificial ECMs in nervous system repair, wound healing, bone and cartilage regeneration, and organoid culture. This emerging SPH platform could provide an alternative strategy for developing more effective biomaterials for tissue engineering.

Published

2024

6. Scalable fabrication of porous membrane incorporating human extracellular matrix-like collagen for guided bone regeneration.

Author

Wang Q, Zhou F, Qiu T, Liu Y, Luo W, Wang Z, Li H, Xiao E, Wei Q, and Wu Y

Subjects

Humans, Porosity, Animals, Rats, Rats, Sprague-Dawley, Membranes, Artificial, Biocompatible Materials chemistry, Biocompatible Materials pharmacology, Surface Properties, Guided Tissue Regeneration methods, Male, Cell Proliferation drug effects, Osteogenesis drug effects, Bone Regeneration drug effects, Collagen chemistry, Extracellular Matrix chemistry, Extracellular Matrix metabolism, Polyesters chemistry

Abstract

Guided bone regeneration (GBR) is an extensively used technique for the treatment of maxillofacial bone defects and bone mass deficiency in clinical practice. However, to date, studies on membranes for GBR have not achieved the combination of suitable properties and cost-effective membrane production. Herein, we developed a polycaprolactone/human extracellular matrix-like collagen (PCL/hCol) membrane with an asymmetric porous structure via the nonsolvent-induced phase separation (NIPS) method, which is a highly efficient procedure with simple operation, scalable fabrication and low cost. This membrane possessed a porous rough surface, which is conducive to cell attachment and proliferation for guiding osteogenesis, together with a relatively smooth surface with micropores, which allows the passage of nutrients and is unfavorable for the adhesion of cells, thus preventing fibroblast invasion and overall meeting the demands for GBR. Besides, we evaluated the characteristics and biological properties of the membrane and compared them with those of commercially available membranes. Results showed that the PCL/hCol membrane exhibited excellent mechanical properties, degradation characteristics, barrier function, biocompatibility and osteoinductive potential. Furthermore, our in vivo study demonstrated the promotive effect of the PCL/hCol membrane on bone formation in rat calvarial defects. Taken together, our NIPS-prepared PCL/hCol membrane with promising properties and production advantages offers a new perspective for its development and potential use in GBR application.

Published

2024

7. Tuning porosity of macroporous hydrogels enables rapid rates of stress relaxation and promotes cell expansion and migration.

Author

Nerger BA, Kashyap K, Deveney BT, Lou J, Hanan BF, Liu Q, Khalil A, Lungjangwa T, Cheriyan M, Gupta A, Jaenisch R, Weitz DA, Mahadevan L, and Mooney DJ

Subjects

Porosity, Humans, Extracellular Matrix chemistry, Animals, Spheroids, Cellular cytology, Serum Albumin, Bovine chemistry, Stress, Mechanical, Cell Proliferation, Hydrogels chemistry, Cell Movement, Alginates chemistry

Abstract

Extracellular matrix (ECM) viscoelasticity broadly regulates cell behavior. While hydrogels can approximate the viscoelasticity of native ECM, it remains challenging to recapitulate the rapid stress relaxation observed in many tissues without limiting the mechanical stability of the hydrogel. Here, we develop macroporous alginate hydrogels that have an order of magnitude increase in the rate of stress relaxation as compared to bulk hydrogels. The increased rate of stress relaxation occurs across a wide range of polymer molecular weights (MWs), which enables the use of high MW polymer for improved mechanical stability of the hydrogel. The rate of stress relaxation in macroporous hydrogels depends on the volume fraction of pores and the concentration of bovine serum albumin, which is added to the hydrogels to stabilize the macroporous structure during gelation. Relative to cell spheroids encapsulated in bulk hydrogels, spheroids in macroporous hydrogels have a significantly larger area and smaller circularity because of increased cell migration. A computational model provides a framework for the relationship between the macroporous architecture and morphogenesis of encapsulated spheroids that is consistent with experimental observations. Taken together, these findings elucidate the relationship between macroporous hydrogel architecture and stress relaxation and help to inform the design of macroporous hydrogels for materials-based cell therapies., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

8. Standalone single- and bi-layered human skin 3D models supported by recombinant silk feature native spatial organization.

Author

Gkouma S, Bhalla N, Frapard S, Jönsson A, Gürbüz H, Dogan AA, Giacomello S, Duvfa M, Ståhl PL, Widhe M, and Hedhammar M

Subjects

Humans, Skin, Artificial, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Tissue Engineering, Models, Biological, Tissue Scaffolds chemistry, Keratinocytes cytology, Keratinocytes metabolism, Animals, Silk chemistry, Skin metabolism, Skin cytology, Recombinant Proteins metabolism, Recombinant Proteins chemistry

Abstract

Physiologically relevant human skin models that include key skin cell types can be used for in vitro drug testing, skin pathology studies, or clinical applications such as skin grafts. However, there is still no golden standard for such a model. We investigated the potential of a recombinant functionalized spider silk protein, FN-silk, for the construction of a dermal, an epidermal, and a bilayered skin equivalent (BSE). Specifically, two formats of FN-silk (i.e. 3D network and nanomembrane) were evaluated. The 3D network was used as an elastic ECM-like support for the dermis, and the thin, permeable nanomembrane was used as a basement membrane to support the epidermal epithelium. Immunofluorescence microscopy and spatially resolved transcriptomics analysis demonstrated the secretion of key ECM components and the formation of microvascular-like structures. Furthermore, the epidermal layer exhibited clear stratification and the formation of a cornified layer, resulting in a tight physiologic epithelial barrier. Our findings indicate that the presented FN-silk-based skin models can be proposed as physiologically relevant standalone epidermal or dermal models, as well as a combined BSE., (Creative Commons Attribution license.)

Published

2024

9. Characterization of Extracellular Matrix Derived From Porcine Organs Decellularized Using Different Methods.

Author

Dhandapani V, Boabekoa P, Borduas M, and Vermette P

Subjects

Animals, Swine, Extracellular Matrix chemistry, Pancreas cytology, Pancreas metabolism, DNA metabolism, DNA chemistry, Tissue Scaffolds chemistry, Glycosaminoglycans metabolism, Glycosaminoglycans chemistry, Decellularized Extracellular Matrix chemistry

Abstract

Regenerative medicine has extended the capacity of medicine to a point where tissues and organs could potentially be manufactured. This could resolve issues associated with organ transplantation. The extracellular matrix (ECM) provides a supportive scaffold and biochemical cues allowing cells to attach, proliferate, and differentiate. The ECM is composed of different fibrous proteins and proteoglycans. The extensive value of ECM lies in its dynamic microenvironment that aids in cell proliferation, differentiation, and regulation of intercellular communication. In this study, four methods were applied to decellularize porcine organs. The ECMs were characterized by histological methods illustrating the absence of nuclei and the presence of glycosaminoglycans (GAGs) and collagen. Hematoxylin and eosin analysis of native pancreas revealed necrosis by auto-digestion, also supported by a reduced dsDNA content, and could have led to the destruction of Type IV collagen, laminins, and other proteins in the resulting ECMs, as confirmed by mass spectrometry. DNA quantification of ECM revealed residual dsDNA contents lower than those of the native organs. Bicinchoninic acid (BCA) assay showed a difference in protein content between organs. Mass spectrometry coupled with proteomic analysis highlighted a significant difference in the protein composition. The number of different proteins, in some cases with more than 2700, in the produced ECM depended on the applied decellularization technique. Polarization microscopy indicated differences in the orientation of collagen fibers. This study provides a multimodal approach to characterize ECMs produced using different decellularization techniques, aiding in finding a balance between maintaining the ultrastructure and composition of ECM, while removing cellular components., (© 2024 The Author(s). Journal of Biomedical Materials Research Part B: Applied Biomaterials published by Wiley Periodicals LLC.)

Published

2024

10. Advances and impact of human amniotic membrane and human amniotic-based materials in wound healing application.

Author

Heydari P, Mojahedi M, Javaherchi P, Sharifi M, and Kharazi AZ

Subjects

Humans, Biocompatible Materials chemistry, Hydrogels chemistry, Animals, Extracellular Matrix chemistry, Wound Healing drug effects, Amnion chemistry

Abstract

Wound healing is a complicated process, especially when surgical, traumatic, burn, or pathological injury occurs, which requires different kinds of dressing covers including hydrogels, hydrocolloids, alginates foams and films for treatment. The human amniotic membrane (hAM) is a biodegradable extracellular matrix with unique and tailorable physicochemical and biological properties, generated by the membrane itself or other cells that are located on the membrane surface. It is noted as a promising aid for wound healing and tissue regeneration due to the release of growth factors and cytokines, and its antibacterial and immunosuppressive properties. Moreover, hAM has optimal physical, biological, and mechanical properties, which makes it a much better option as a regenerative skin treatment than existing alternative materials. In addition, this layer has a structure with different layers and cells with different functions, which act as a regenerative geometry and reservoir of bioactive substances and cells for wound healing. In the present work, the structural and biological features of hAM are introduced as well as the application of this layer in different forms of composites to enhance wound healing. Future studies are recommended to detect possible further functionalization to enhance the hAM effectiveness on wound healing., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier B.V. All rights reserved.)

Published

2024

11. Simultaneous co-assembly of collagen and glycosaminoglycans to build a biomimetic extracellular matrix for bone regeneration.

Author

Zhang Y, Zhou X, Liu Q, Shen M, Liu Y, and Zhang X

Subjects

Animals, Hyaluronic Acid chemistry, Biomimetic Materials chemistry, Cell Differentiation, Molecular Docking Simulation, Tissue Engineering methods, Biomimetics methods, Bone Regeneration drug effects, Collagen chemistry, Collagen metabolism, Glycosaminoglycans chemistry, Glycosaminoglycans metabolism, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Tissue Scaffolds chemistry, Osteogenesis drug effects, Mesenchymal Stem Cells metabolism, Mesenchymal Stem Cells cytology

Abstract

Glycosaminoglycans (GAGs), also known as shape modules, are considered junctions that help define the shape of collagen matrix and further promote mineralization during osteogenesis. Many attempts have been made to immobilize GAGs on assembled collagen to modify the latter's surface state. However, it remains unclear how GAGs spontaneously identify collagen molecules during fibrillogenesis in vivo. Understanding the relationship between GAGs and collagen from both the bone physiology and materials science perspectives is of fundamental interest. Here, we introduced hyaluronic acid (HA, a main member of GAGs) during collagen self-assembly, in a process called modification cooperating with self-assembly (MCS). The molecular docking and morphological studies revealed that HA can help define collagen monomer deposition and thus promote fibrillogenesis through steric hindrance or by directly forming hydrogen bonds. Meanwhile, HA acts as a templating chaperone (TC) to increase the local mineral concentration within intrafibrillar channels but does not initiate nucleation, thus improving the crystallinity of formed apatite. The scaffolds synthesized through MCS model significantly improved the physicochemical stability and mechanical strength of collagen-based scaffolds. The optimized scaffolds promoted in-situ osteogenesis by stimulating the osteogenic differentiation of bone mesenchymal stem cells, either in an osteogenic medium, or after implantation into critical calvarial defects. This study provides novel insights towards evolving engineering scaffolds from inert supports to functional substitutes., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interest or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier B.V. All rights reserved.)

Published

2024

12. Biodegradable Piezoelectric-Conductive Integrated Hydrogel Scaffold for Repair of Osteochondral Defects.

Author

Liu D, Wang X, Gao C, Zhang Z, Wang Q, Pei Y, Wang H, Tang Y, Li K, Yu Y, Cai Q, and Zhang X

Subjects

Animals, Swine, Chondrogenesis drug effects, Electric Conductivity, Biocompatible Materials chemistry, Biocompatible Materials pharmacology, Tissue Engineering methods, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Cartilage cytology, Tissue Scaffolds chemistry, Mesenchymal Stem Cells cytology, Hydrogels chemistry, Cell Differentiation drug effects, Osteogenesis drug effects

Abstract

Osteochondral injury is a prevalent condition for which no specific treatment is currently available. This study presents a piezoelectric-conductive scaffold composed of a piezoelectric cartilage-decellularized extracellular matrix (dECM) and piezoelectric-conductive modified gelatin (Gel-PC). The piezoelectricity of the scaffold is achieved through the modification of diphenylalanine (FF) assembly on the pore surface, while the conductive properties of scaffold are achieved by the incorporating poly(3,4-ethylenedioxythiophene). In vitro experiments demonstrate that bone marrow mesenchymal stem cells (BMSCs) undergo biphasic division during differentiation. In vivo studies using a Parma pig model of osteochondral defects demonstrate that the piezoelectric-conductive scaffold exhibits superior reparative efficacy. Notably, the generation of electrical stimulation is linked to joint movement. During joint activity, mechanical forces compress the scaffold, leading to deformation and the subsequent generation of an electric potential difference. The positive charges accumulated on the upper layer of the scaffold attract BMSCs, promoting their migration to the upper layer and chondrogenic differentiation. Meanwhile, the negative charges in the lower layer induce the osteogenic differentiation of BMSCs. Overall, this piezoelectric-conducive scaffold provides a promising platform for the effective repair of osteochondral defects., (© 2024 Wiley‐VCH GmbH.)

Published

2024

13. Stepwise Stiffening/Softening of and Cell Recovery from Reversibly Formulated Hydrogel Interpenetrating Networks.

Author

Kopyeva I, Goldner EC, Hoye JW, Yang S, Regier MC, Bradford JC, Vera KR, Bretherton RC, Robinson JL, and DeForest CA

Subjects

Humans, Caco-2 Cells, Biocompatible Materials chemistry, Biocompatible Materials pharmacology, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Hydrogels chemistry, Mesenchymal Stem Cells cytology, Mesenchymal Stem Cells metabolism, Polyethylene Glycols chemistry

Abstract

Biomechanical contributions of the extracellular matrix underpin cell growth and proliferation, differentiation, signal transduction, and other fate decisions. As such, biomaterials whose mechanics can be spatiotemporally altered- particularly in a reversible manner- are extremely valuable for studying these mechanobiological phenomena. Herein, a poly(ethylene glycol) (PEG)-based hydrogel model consisting of two interpenetrating step-growth networks is introduced that are independently formed via largely orthogonal bioorthogonal chemistries and sequentially degraded with distinct recombinant sortases, affording reversibly tunable stiffness ranges that span healthy and diseased soft tissues (e.g., 500 Pa-6 kPa) alongside terminal cell recovery for pooled and/or single-cell analysis in a near "biologically invisible" manner. Spatiotemporal control of gelation within the primary supporting network is achieved via mask-based and two-photon lithography; these stiffened patterned regions can be subsequently returned to the original soft state following sortase-based secondary network degradation. Using this approach, the effects of 4D-triggered network mechanical changes on human mesenchymal stem cell morphology and Hippo signaling, as well as Caco-2 colorectal cancer cell mechanomemory using transcriptomics and metabolic assays are investigated. This platform is expected to be of broad utility for studying and directing mechanobiological phenomena, patterned cell fate, and disease resolution in softer matrices., (© 2024 Wiley‐VCH GmbH.)

Published

2024

14. Engineered Protein Hydrogels as Biomimetic Cellular Scaffolds.

Author

Liu Y, Gilchrist AE, and Heilshorn SC

Subjects

Humans, Animals, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Proteins chemistry, Proteins metabolism, Tissue Engineering methods, Hydrogels chemistry, Protein Engineering methods, Biomimetic Materials chemistry, Tissue Scaffolds chemistry

Abstract

The biochemical and biophysical properties of the extracellular matrix (ECM) play a pivotal role in regulating cellular behaviors such as proliferation, migration, and differentiation. Engineered protein-based hydrogels, with highly tunable multifunctional properties, have the potential to replicate key features of the native ECM. Formed by self-assembly or crosslinking, engineered protein-based hydrogels can induce a range of cell behaviors through bioactive and functional domains incorporated into the polymer backbone. Using recombinant techniques, the amino acid sequence of the protein backbone can be designed with precise control over the chain-length, folded structure, and cell-interaction sites. In this review, the modular design of engineered protein-based hydrogels from both a molecular- and network-level perspective are discussed, and summarize recent progress and case studies to highlight the diverse strategies used to construct biomimetic scaffolds. This review focuses on amino acid sequences that form structural blocks, bioactive blocks, and stimuli-responsive blocks designed into the protein backbone for highly precise and tunable control of scaffold properties. Both physical and chemical methods to stabilize dynamic protein networks with defined structure and bioactivity for cell culture applications are discussed. Finally, a discussion of future directions of engineered protein-based hydrogels as biomimetic cellular scaffolds is concluded., (© 2024 Wiley‐VCH GmbH.)

Published

2024

15. Electrohydrodynamic Direct-Writing Micro/Nanofibrous Architectures: Principle, Materials, and Biomedical Applications.

Author

Liu Z, Jia J, Lei Q, Wei Y, Hu Y, Lian X, Zhao L, Xie X, Bai H, He X, Si L, Livermore C, Kuang R, Zhang Y, Wang J, Yu Z, Ma X, and Huang D

Subjects

Humans, Biocompatible Materials chemistry, Tissue Engineering methods, Tissue Scaffolds chemistry, Extracellular Matrix chemistry, Animals, Hydrodynamics, Nanofibers chemistry

Abstract

Electrohydrodynamic (EHD) direct-writing has recently gained attention as a highly promising additive manufacturing strategy for fabricating intricate micro/nanoscale architectures. This technique is particularly well-suited for mimicking the extracellular matrix (ECM) present in biological tissue, which serves a vital function in facilitating cell colonization, migration, and growth. The integration of EHD direct-writing with other techniques has been employed to enhance the biological performance of scaffolds, and significant advancements have been made in the development of tailored scaffold architectures and constituents to meet the specific requirements of various biomedical applications. Here, a comprehensive overview of EHD direct-writing is provided, including its underlying principles, demonstrated materials systems, and biomedical applications. A brief chronology of EHD direct-writing is provided, along with an examination of the observed phenomena that occur during the printing process. The impact of biomaterial selection and architectural topographic cues on biological performance is also highlighted. Finally, the major limitations associated with EHD direct-writing are discussed., (© 2024 Wiley‐VCH GmbH.)

Published

2024

16. Harnessing the Regenerative Potential of Purified Bovine Dental Pulp and Dentin Extracellular Matrices in a Chitosan/Alginate Hydrogel.

Author

Gould ML, Downes NJ, Woolley AG, Hussaini HM, Ratnayake JT, Ali MA, Friedlander LT, and Cooper PR

Subjects

Cattle, Animals, Humans, Hexuronic Acids chemistry, Hexuronic Acids pharmacology, Regeneration drug effects, Cells, Cultured, Cell Proliferation drug effects, Dental Pulp cytology, Chitosan chemistry, Chitosan pharmacology, Hydrogels chemistry, Hydrogels pharmacology, Alginates chemistry, Alginates pharmacology, Dentin chemistry, Dentin metabolism, Extracellular Matrix metabolism, Extracellular Matrix chemistry

Abstract

When a tooth is diseased or damaged through caries, bioactive molecules are liberated from the pulp and dentin as part of the natural response to injury and these are key molecules for stimulating stem cell responses for tissue repair. Incorporation of these extracellular-matrix (ECM)-derived molecules into a hydrogel model can mimic in vivo conditions to enable dentin-pulp complex regeneration. Here, a chitosan/alginate (C/A) hydrogel is developed to sequester bovine ECM extracts. Human dental pulp cells (hDPCs) are cultured with these constructs and proliferation and cytotoxicity assays confirm that these C/A hydrogels are bioactive. Sequential z-axis fluorescent imaging visualizes hDPCs protruding into the hydrogel as it degraded. Alizarin red S staining shows that hDPCs cultured with the hydrogels display increased calcium-ion deposition, with dentin ECM stimulating the highest levels. Alkaline phosphatase activity is increased, as is expression of transforming growth factor-beta as demonstrated using immunocytochemistry. Directional analysis following phase contrast kinetic image capture demonstrates that both dentin and pulp ECM molecules act as chemoattractants for hDPCs. Data from this study demonstrate that purified ECM from dental pulp and dentin when delivered in a C/A hydrogel stimulates dental tissue repair processes in vitro., (© 2024 The Author(s). Macromolecular Bioscience published by Wiley‐VCH GmbH.)

Published

2024

17. Cardiac Matrix-Derived Granular Hydrogel Enhances Cell Function in 3D Culture.

Author

Shaik R, Brown J, Xu J, Lamichhane R, Wang Y, Hong Y, and Zhang G

Subjects

Humans, Animals, Swine, Cell Culture Techniques, Three Dimensional, Fibrin chemistry, Extracellular Matrix chemistry, Extracellular Matrix metabolism, Myocardium cytology, Myocardium metabolism, Spheroids, Cellular drug effects, Spheroids, Cellular cytology, Neovascularization, Physiologic drug effects, Hydrogels chemistry, Hydrogels pharmacology, Mesenchymal Stem Cells cytology, Mesenchymal Stem Cells drug effects, Mesenchymal Stem Cells metabolism, Human Umbilical Vein Endothelial Cells, Cell Survival drug effects

Abstract

Hydrogels derived from decellularized porcine myocardial matrix have demonstrated significant potential as therapeutic delivery platforms for promoting cardiac repair after injury. Our previous study developed a fibrin-enriched cardiac matrix hydrogel to enhance its angiogenic capacities. However, the bulk hydrogel structure may limit their full potential in cell delivery. Recently, granular hydrogels have emerged as a promising class of biomaterials, offering unique features such as a highly interconnected porous structure that facilitates nutrient diffusion and enhances cell viability. Several techniques have been developed for fabricating various types of granular hydrogels, among which extrusion fragmentation is particularly appealing due to its adaptability to many types of hydrogels, low cost, and high scalability. In this study, we first confirmed the effects of the bulk cardiac matrix hydrogel on the viability of encapsulated human umbilical vein endothelial cells and human mesenchymal stem cells. We then tested the feasibility of producing granular hydrogels from both cardiac matrix and fibrin-enriched cardiac matrix through cellular cross-linking of microgels fabricated by extrusion fragmentation. Afterward, we examined the roles of the produced granular hydrogels in the embedded cells and cell spheroids. Our in vitro data demonstrate that cardiac matrix-derived granular hydrogels support optimal viability of encapsulated cells and promote sprouting of human mesenchymal stem cell spheroids. Additionally, granular hydrogel derived from fibrin-enriched cardiac matrix accelerates angiogenic sprouting of embedded human mesenchymal stem cell spheroids. The results obtained from this study lay an important foundation for the future exploration of using cardiac matrix-derived granular hydrogels for cardiac cell therapy.

Published

2024

18. Extracellular Vesicle Mobility in Collagen I Hydrogels Is Influenced by Matrix-Binding Integrins.

Author

Tam NW, Becker A, Mangiarotti A, Cipitria A, and Dimova R

Subjects

Humans, Oligopeptides chemistry, Oligopeptides pharmacology, Oligopeptides metabolism, Extracellular Vesicles metabolism, Extracellular Vesicles chemistry, Hydrogels chemistry, Collagen Type I chemistry, Collagen Type I metabolism, Integrins metabolism, Integrins chemistry, Extracellular Matrix metabolism, Extracellular Matrix chemistry

Abstract

Extracellular vesicles (EVs) are a diverse population of membrane structures produced and released by cells into the extracellular space for the intercellular trafficking of cargo molecules. They are implicated in various biological processes, including angiogenesis, immunomodulation, and cancer cell signaling. While much research has focused on their biogenesis or their effects on recipient cells, less is understood about how EVs are capable of traversing diverse tissue environments and crossing biological barriers. Their interactions with extracellular matrix components are of particular interest, as such interactions govern diffusivity and mobility, providing a potential basis for organotropism. To start to untangle how EV-matrix interactions affect diffusivity, we use high speed epifluorescence microscopy, single particle tracking, and confocal reflectance microscopy to analyze particle mobility and localization in extracellular matrix-mimicking hydrogels composed of collagen I. EVs are compared with synthetic liposomes and extruded plasma membrane vesicles to better understand the importance of membrane composition on these interactions. By treating EVs with trypsin to digest surface proteins, we determine that proteins are primarily responsible for EV immobilization in collagen I hydrogels. We next use a synthetic peptide competitive inhibitor to narrow down the identity of the proteins involved to argynylglycylaspartic acid (RGD) motif-binding integrins, which interact with unincorporated or denatured nonfibrillar collagen. Moreover, the effect of integrin inhibition with RGD peptides has strong implications for the use of RGD-peptide-based drugs to treat certain cancers, as integrin inhibition appears to increase EV mobility, improving their ability to infiltrate tissue-like environments.

Published

2024

19. Engineering anisotropic tissue analogues: harnessing synergistic potential of extrusion-based bioprinting and extracellular matrix-based bioink.

Author

Bera AK, Rizvi MS, Kn V, and Pati F

Subjects

Anisotropy, Animals, Humans, Ink, Printing, Three-Dimensional, Bioprinting methods, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Tissue Engineering methods, Tissue Scaffolds chemistry

Abstract

In the realm of tissue engineering, replicating the intricate alignment of cells and the extracellular matrix (ECM) found in native tissue has long been a challenge. Most recent studies have relied on complex multi-step processes to approximate native tissue alignment. To address this challenge, we introduce a novel, single-step method for constructing highly aligned fibrous structures within multi-modular three-dimensional conglomerates. Our approach harnesses the synergistic potential of extrusion-based bioprinting and the fibrillogenesis kinetics of collagen-rich decellularized ECM. We have identified three key parameters governing ECM microfiber alignment during extrusion-based bioprinting: applied shear stress, stretching or extensional force, and post-print deformation. By carefully manipulating these parameters, we have successfully created highly aligned fibrous structures within multi-modular three-dimensional conglomerates. Our technique offers an efficient solution and has been validated by computational modeling. Comprehensive analyses confirm the efficacy across various scenarios, including encapsulated, top-seeded, and migratory cells. Notably, we have demonstrated the versatility and effectiveness of our approach by bioprinting highly aligned cardiac tissue patches, which show further maturation evidenced by the expression of Troponin-T and Myo-D differentiation factor needed for contractility and myotube formation, respectively. In summary, our streamlined approach offers a robust solution for creating anisotropic tissue analogues with precise ECM organization., (© 2024 IOP Publishing Ltd. All rights, including for text and data mining, AI training, and similar technologies, are reserved.)

Published

2024

20. 3D bioprinting of an intervertebral disc tissue analogue with a highly aligned annulus fibrosus via suspended layer additive manufacture.

Author

Moxon SR, McMurran Z, Kibble MJ, Domingos M, Gough JE, and Richardson SM

Subjects

Animals, Tissue Scaffolds chemistry, Tissue Engineering, Nucleus Pulposus cytology, Nucleus Pulposus metabolism, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Hydrogels chemistry, Annulus Fibrosus, Bioprinting, Printing, Three-Dimensional, Intervertebral Disc cytology

Abstract

Intervertebral disc (IVD) function is achieved through integration of its two component regions: the nucleus pulposus (NP) and the annulus fibrosus (AF). The NP is soft (0.3-5 kPa), gelatinous and populated by spherical NP cells in a polysaccharide-rich extracellular matrix (ECM). The AF is much stiffer (∼100 kPa) and contains layers of elongated AF cells in an aligned, fibrous ECM. Degeneration of the disc is a common problem with age being a major risk factor. Progression of IVD degeneration leads to chronic pain and can result in permanent disability. The development of therapeutic solutions for IVD degeneration is impaired by a lack of in vitro models of the disc that are capable of replicating the fundamental structure and biology of the tissue. This study aims to investigate if a newly developed suspended hydrogel bioprinting system (termed SLAM) could be employed to fabricate IVD analogues with integrated structural and compositional features similar to native tissue. Bioprinted IVD analogues were fabricated to recapitulate structural, morphological and biological components present in the native tissue. The constructs replicated key structural components of native tissue with the presence of a central, polysaccharide-rich NP surrounded by organised, aligned collagen fibres in the AF. Cell tracking, actin and matrix staining demonstrated that embedded NP and AF cells exhibited morphologies and phenotypes analogous to what is observed in vivo with elongated, aligned AF cells and spherical NP cells that deposited HA into the surrounding environment. Critically, it was also observed that the NP and AF regions contained a defined cellular and material interface and segregated regions of the two cell types, thus mimicking the highly regulated structure of the IVD., (Creative Commons Attribution license.)

Published

2024

21. Embedded Bioprinting of Tumor-Scale Pancreatic Cancer-Stroma 3D Models for Preclinical Drug Screening.

Author

Monteiro MV, Rocha M, Carvalho MT, Freitas I, Amaral AJR, Sousa FL, Gaspar VM, and Mano JF

Subjects

Humans, Cell Line, Tumor, Gemcitabine, Carcinoma, Pancreatic Ductal drug therapy, Carcinoma, Pancreatic Ductal pathology, Hyaluronic Acid chemistry, Hyaluronic Acid pharmacology, Drug Screening Assays, Antitumor, Methacrylates chemistry, Antineoplastic Agents pharmacology, Antineoplastic Agents chemistry, Gelatin chemistry, Drug Evaluation, Preclinical, Deoxycytidine analogs & derivatives, Deoxycytidine chemistry, Deoxycytidine pharmacology, Stromal Cells drug effects, Stromal Cells pathology, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Extracellular Matrix drug effects, Pancreatic Neoplasms pathology, Pancreatic Neoplasms drug therapy, Bioprinting, Printing, Three-Dimensional, Tumor Microenvironment drug effects

Abstract

The establishment of organotypic preclinical models that accurately resemble the native tumor microenvironment at an anatomic human scale is highly desirable to level up in vitro platforms potential for screening candidate therapies. The bioengineering of anatomic-scaled three-dimensional (3D) models that emulate native tumor scale while recapitulating their cellular and matrix components remains, however, to be fully realized. In this focus, herein, we leveraged embedded 3D bioprinting for biofabricating pancreatic ductal adenocarcinoma (PDAC) in vitro models combining gelatin-methacryloyl and hyaluronic acid methacrylate extracellular matrix (ECM)-mimetic biomaterials with human pancreatic cancer cells and cancer-associated fibroblasts to generate in vitro models capable of emulating native tumor size (∼6 mm) and stromal elements. By using a viscoelastic continuous polymeric supporting bath, tumor-scale 3D models were rapidly generated (∼50 constructs/h) and easily recovered following in-bath visible light photocrosslinking. As a proof-of-concept, tissue-scale constructs displaying physiomimetic designs were biofabricated. These models also encompass the incorporation of a stromal compartment to better emulate the cellular components of the PDAC native tumor microenvironment (TME) and its stratified spatial organization. Cell-laden tumor-size constructs remained viable for up to 14 days and were responsive to Gemcitabine in a dose-dependent mode. Cancer-stroma models also exhibited increased drug resistance compared to their monotypic counterparts, highlighting the key role of stromal cells in chemotherapeutic resistance. Overall, we report for the first time the freeform biofabrication of PDAC models exhibiting anatomic scale, different structural complexities, and engineered cancer-stromal compartments, being highly valuable for preclinical screening of therapeutics.

Published

2024

22. Rapid low-cost assembly of modular microvessel-on-a-chip with benchtop xurography.

Author

Agarwal SS, Cortes-Medina M, Holter JC, Avendano A, Tinapple JW, Barlage JM, Menyhert MM, Onua LM, and Song JW

Subjects

Humans, Human Umbilical Vein Endothelial Cells, Equipment Design, Microfluidic Analytical Techniques instrumentation, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Microvessels cytology, Microvessels physiology, Lab-On-A-Chip Devices, Dimethylpolysiloxanes chemistry

Abstract

Blood and lymphatic vessels in the body are central to molecular and cellular transport, tissue repair, and pathophysiology. Several approaches have been employed for engineering microfabricated blood and lymphatic vessels in vitro , yet traditionally these approaches require specialized equipment, facilities, and research training beyond the capabilities of many biomedical laboratories. Here we present xurography as an inexpensive, accessible, and versatile rapid prototyping technique for engineering cylindrical and lumenized microvessels. Using a benchtop xurographer, or a cutting plotter, we fabricated modular multi-layer poly(dimethylsiloxane) (PDMS)-based microphysiological systems (MPS) that house endothelial-lined microvessels approximately 260 μm in diameter embedded within a user-defined 3-D extracellular matrix (ECM). We validated the vascularized MPS (or vessel-on-a-chip) by quantifying changes in blood vessel permeability due to the pro-angiogenic chemokine CXCL12. Moreover, we demonstrated the reconfigurable versatility of this approach by engineering a total of four distinct vessel-ECM arrangements, which were obtained by only minor adjustments to a few steps of the fabrication process. Several of these arrangements, such as ones that incorporate close-ended vessel structures and spatially distinct ECM compartments along the same microvessel, have not been widely achieved with other microfabrication strategies. Therefore, we anticipate that our low-cost and easy-to-implement fabrication approach will facilitate broader adoption of MPS with customizable vascular architectures and ECM components while reducing the turnaround time required for iterative designs.

Published

2024

23. A Nontoxic and Biocompatible Method for Augmenting Mechanical Strength of Acellular Matrix by Silk Fibroin Impregnation.

Author

Puthiya Veettil J, Sasikumar Lolitha D, Ramesan RM, Parameswaran R, and Payanam Ramachandra U

Subjects

Animals, Swine, Particle Size, Tensile Strength, Extracellular Matrix chemistry, Extracellular Matrix metabolism, Humans, Fibroins chemistry, Biocompatible Materials chemistry, Biocompatible Materials pharmacology, Materials Testing, Tissue Scaffolds chemistry

Abstract

Biological scaffolds are plagued by poor biomechanical properties and untimely degradation. These limitations have yet to be addressed without compromising their biocompatibility. It is desirable to avoid inflammation and have degradation with concomitant host collagen deposition or even site-appropriate in situ regeneration for the successful outcome of an implanted biological scaffold. This work aims to achieve this by utilizing a biocompatible method to modify acellular scaffolds by impregnating alkaline-catalyzed citric acid (CA) cross-linking between the extracellular matrix proteins and silk fibroin (SF)/SF-gelatin (SFG) blends. Combinatorial detergent decellularization was employed to prepare a decellularized porcine liver scaffold (DPL). After proving the decellularization efficiency, the scaffold underwent modification by vacuum impregnation with CA containing SF (SF100DPL) and SFG blends (SFG5050DPL and SFG3070DPL) following pre-cross-linking, drying, and post-cross-linking. The subsequent strength augmentation was demonstrated by significant improvement in tensile strength from 2.4 ± 0.4 MPa (DPL) to, 3.8 ± 0.7 MPa (SF100DPL), 3.4 ± 0.7 MPa (SFG5050DPL), and 3.5 ± 0.2 MPa (SFG3070DPL); Young's modulus from 8.7 ± 1.8 MPa (DPL) to 20 ± 1.9 MPa (SF100DPL), 13.3 ± 2.6 MPa (SFG5050DPL), and 16 ± 1.2 MPa (SFG3070DPL); and suture retention strength from 0.9 ± 0.08 MPa (DPL) to 2.3 ± 0.2 MPa (SF100DPL), 2.8 ± 1.2 MPa (SFG5050DPL), and 2.6 ± 0.9 MPa (SFG3070DPL). The degradation resistance of the modified scaffolds was also markedly improved. Being cytocompatible, its ability to incite tolerable inflammatory and immune responses was confirmed by rat subcutaneous implantation for 14, 30, and 90 days, in terms of inflammatory cell infiltration, neoangiogenesis, and in vitro cytokine release to assess B-cell and T-cell activation. Such ECM composite scaffolds with appropriate strength and biocompatibility offer great promise in soft tissue repair applications such as skin grafting.

Published

2024

24. Characterization of pediatric porcine pulmonary valves as a model for tissue engineered heart valves.

Author

Parvin Nejad S, Mirani B, Mirzaei Z, and Simmons CA

Subjects

Animals, Swine, Heart Valve Prosthesis, Humans, Tensile Strength, Pulmonary Valve cytology, Tissue Engineering methods, Extracellular Matrix metabolism, Extracellular Matrix chemistry

Abstract

Heart valve tissue engineering holds the potential to transform the surgical management of congenital heart defects affecting the pediatric pulmonary valve (PV) by offering a viable valve replacement. While aiming to recapitulate the native valve, the minimum requirement for tissue engineered heart valves (TEHVs) has historically been adequate mechanical function at implantation. However, long-term in situ functionality of TEHVs remains elusive, suggesting that a closer approximation of the native valve is required. The realization of biomimetic engineered pediatric PV is impeded by insufficient characterization of healthy pediatric tissue. In this study, we comprehensively characterized the planar biaxial tensile behaviour, extracellular matrix (ECM) composition and organization, and valvular interstitial cell (VIC) phenotypes of PVs from piglets to provide benchmarks for TEHVs. The piglet PV possessed an anisotropic and non-linear tension-strain profile from which material constants for a predictive constitutive model were derived. The ECM of the piglet PV possessed a trilayer organization populated by collagen, glycosaminoglycans, and elastin. Biochemical quantification of ECM content normalized to wet weight and DNA content of PV tissue revealed homogeneous distribution across sampled regions of the leaflet. Finally, VICs in the piglet PV were primarily quiescent vimentin-expressing fibroblasts, with a small proportion of activated α-smooth muscle actin-expressing myofibroblasts. Overall, piglet PV properties were consistent with those reported anecdotally for pediatric human PVs and distinct from those of adult porcine and human PVs, supporting the utility of the properties determined here to inform the design of tissue engineered pediatric PVs. STATEMENT OF SIGNIFICANCE: Heart valve tissue engineering has the potential to transform treatment for children born with defective pulmonary valves by providing living replacement tissue that can grow with the child. The design of tissue engineered heart valves is best informed by native valve properties, but native pediatric pulmonary valves have not been fully described to date. Here, we provide comprehensive characterization of the planar biaxial tensile behaviour, extracellular matrix composition and organization, and valvular interstitial cell phenotypes of pulmonary valves from piglets as a model for the native human pediatric valve. Together, these findings provide standards that inform engineered heart valve design towards generation of biomimetic pediatric pulmonary valves., Competing Interests: Declaration of competing interests The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Craig Simmons reports financial support was provided by Canadian Institutes of Health Research. Craig Simmons and Bahram Mirani report financial support was provided by Natural Sciences and Engineering Research Council of Canada. Shouka Parvin Nejad and Zahra Mirzaei declare they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2024

25. Rapidly Degrading Hydrogels to Support Biofabrication and 3D Bioprinting Using Cartilage Microtissues.

Author

Kronemberger GS, Spagnuolo FD, Karam AS, Chattahy K, Storey KJ, and Kelly DJ

Subjects

Animals, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Tissue Scaffolds chemistry, Glycosaminoglycans metabolism, Hydrogels chemistry, Printing, Three-Dimensional, Bioprinting methods, Tissue Engineering methods, Alginates chemistry, Cartilage metabolism, Cartilage cytology

Abstract

In recent years, there has been increased interest in the use of cellular spheroids, microtissues, and organoids as biological building blocks to engineer functional tissues and organs. Such microtissues are typically formed by the self-assembly of cellular aggregates and the subsequent deposition of a tissue-specific extracellular matrix (ECM). Biofabrication and 3D bioprinting strategies using microtissues may require the development of supporting hydrogels and bioinks to spatially localize such biological building blocks in 3D space and hence enable the engineering of geometrically defined tissues. Therefore, the aim of this work was to engineer scaled-up, geometrically defined cartilage grafts by combining multiple cartilage microtissues within a rapidly degrading oxidized alginate (OA) supporting hydrogel and maintaining these constructs in dynamic culture conditions. To this end, cartilage microtissues were first independently matured for either 2 or 4 days and then combined in the presence or absence of a supporting OA hydrogel. Over 6 weeks in static culture, constructs engineered using microtissues that were matured independently for 2 days generated higher amounts of glycosaminoglycans (GAGs) compared to those matured for 4 days. Histological analysis revealed intense staining for GAGs and negative staining for calcium deposits in constructs generated by using the supporting OA hydrogel. Less physical contraction was also observed in constructs generated in the presence of the supporting gel; however, the remnants of individual microtissues were more observable, suggesting that even the presence of a rapidly degrading hydrogel may delay the fusion and/or the remodeling of the individual microtissues. Dynamic culture conditions were found to modulate ECM synthesis following the OA hydrogel encapsulation. We also assessed the feasibility of 3D bioprinting of cartilage microtissues within OA based bioinks. It was observed that the microtissues remained viable after extrusion-based bioprinting and were able to fuse after 48 h, particularly when high microtissue densities were used, ultimately generating a cartilage tissue that was rich in GAGs and negative for calcium deposits. Therefore, this work supports the use of OA as a supporting hydrogel/bioink when using microtissues as biological building blocks in diverse biofabrication and 3D bioprinting platforms.

Published

2024

26. Engineering a Biomimetic Glomerular Filtration Barrier: Coculturing Endothelial Podocytes on Kidney ECM-Bacterial Cellulose Membrane Hybrid.

Author

Kiranmai G, Alam A, Chameettachal S, Khandelwal M, and Pati F

Subjects

Animals, Humans, Tissue Engineering, Kidney, Coculture Techniques, Biomimetic Materials chemistry, Goats, Tissue Scaffolds chemistry, Cellulose chemistry, Podocytes metabolism, Podocytes cytology, Glomerular Filtration Barrier metabolism, Glomerular Filtration Barrier chemistry, Extracellular Matrix chemistry, Extracellular Matrix metabolism

Abstract

A novel avenue for advancing our understanding of kidney disease mechanisms and developing targeted therapeutics lies in overcoming the limitations of the existing in vitro models. Traditional animal models, while useful, do not fully capture the intricacies of human kidney physiology and pathophysiology. Tissue engineering offers a promising solution, yet current models often fall short in replicating the complex microarchitecture and biochemical milieu of the kidney. To address this challenge, we propose the development of a sophisticated in vitro glomerular filtration barrier (GFB) utilizing advanced biomaterials and a kidney decellularized extracellular matrix (kdECM). In our approach, we employ a bacterial cellulose membrane (BC) as a scaffold, providing a robust framework for cell growth and interaction. Coating this scaffold with kdECM hydrogel derived from caprine kidney tissue via a detergent-free decellularization method ensures the preservation of vital extracellular matrix proteins crucial for cellular compatibility and signaling. Our engineered GFB not only supports the growth of endothelial and podocyte cells but also exhibits the presence of key markers such as CD31 and nephrin, indicating successful cellular integration. Furthermore, the expression of collagen IV, an essential extracellular matrix (ECM) protein, validates the fidelity of our model in simulating cellular interactions within a kdECM matrix. Additionally, we assessed the filtration efficiency of the developed GFB model using albumin, a standard protein, to evaluate its performance under conditions that closely mimic the native physiological environment. This innovative approach, which faithfully recapitulates the native microenvironment of the glomerulus, holds immense promise for elucidating kidney disease mechanisms, conducting permeability studies, and advancing personalized therapeutic strategies. By leveraging cutting-edge biomaterials and tissue-specific coculture technology, this study can be further extended to develop GFB for the treatment of renal diseases, ultimately improving patient outcomes and quality of life.

Published

2024

27. Hyaluronan-Based Hydrogels for 3D Modeling of Tumor Tissues.

Author

Alsharabasy AM and Pandit A

Subjects

Humans, Animals, Tumor Microenvironment, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Models, Biological, Hyaluronic Acid chemistry, Hydrogels chemistry, Neoplasms pathology, Neoplasms metabolism

Abstract

Although routine two-dimensional (2D) cell culture techniques have advanced basic cancer research owing to their simplicity, cost-effectiveness, and reproducibility, they have limitations that necessitate the development of advanced three-dimensional (3D) tumor models that better recapitulate the tumor microenvironment. Various biomaterials have been used to establish these 3D models, enabling the study of cancer cell behavior within different matrices. Hyaluronic acid (HA), a key component of the extracellular matrix (ECM) in tumor tissues, has been widely studied and employed in the development of multiple cancer models. This review first examines the role of HA in tumors, including its function as an ECM component and regulator of signaling pathways that affect tumor progression. It then explores HA-based models for various cancers, focusing on HA as a central component of the 3D matrix and its mobilization within the matrix for targeted studies of cell behavior and drug testing. The tumor models discussed included those for breast cancer, glioblastoma, fibrosarcoma, gastric cancer, hepatocellular carcinoma, and melanoma. The review concludes with a discussion of future prospects for developing more robust and high-throughput HA-based models to more accurately mimic the tumor microenvironment and improve drug testing. Impact Statement This review underscores the transformative potential of hyaluronic acid (HA)-based hydrogels in developing advanced tumor models. By exploring HA's dual role as a critical extracellular matrix component and a regulator of cancer cell dynamics, we highlight its unique contributions to replicating the tumor microenvironment. The recent advancements in HA-based models provide new opportunities for more accurate studies of cancer cell behavior and drug responses. Looking ahead, these innovations pave the way for high-throughput, biomimetic platforms that could revolutionize drug testing and accelerate the discovery of effective cancer therapies.

Published

2024

28. Composition Tuning of Semi-Open Cell Carriers via Phase Freeze-Shrink Self-Molding.

Author

Wei Y, Zhang F, Li J, Qi Z, Wang JH, and Wang Z

Subjects

Humans, Freezing, Gelatin chemistry, Hyaluronic Acid chemistry, Hyaluronan Receptors metabolism, Extracellular Matrix chemistry, Extracellular Matrix metabolism, Polysaccharides chemistry, Methacrylates chemistry, Polyethylene Glycols chemistry

Abstract

Extracellular matrix (ECM)-mimicking microsized cell carriers featuring a semi-isolated chamber facilitate the study of cellular heterogeneity as well as intercellular communication. However, the semiopen shaping of the designated gel mixture remains unattainable with current methods. We report an oil-phase freeze-shrink self-molding mechanism for generating size- and composition-tunable cradle-shaped microgels (microcradles) from water-in-oil droplets. The universality of this shape transition principle is demonstrated with six types of polysaccharides dispersed in a poly(ethylene glycol) diacrylate (PEGDA) or methacrylate gelatin (GelMA) matrix. By doping the microcradles with the major ECM component, hyaluronic acid sodium, we demonstrate a label-free selective culture of CD44 receptor-rich cells and the formation of cell spheroids within 3 days. This cryo-induced cradle-shaping strategy enables the functionalization of microcarriers for selective cell culture, thereby allowing them to be used for intercellular communication, drug delivery, and the construction of structural units for osteogenesis and 3D printing.

Published

2024

29. Novel shish-kebab structured nanofibrous decorating chitosan unidirectional scaffolds to mimic extracellular matrix for tissue engineering.

Author

Feng PY and Jing X

Subjects

Mice, Animals, Porosity, Cell Proliferation drug effects, Cell Survival drug effects, Biomimetic Materials chemistry, 3T3 Cells, Biocompatible Materials chemistry, Biocompatible Materials pharmacology, Chitosan chemistry, Tissue Engineering, Tissue Scaffolds chemistry, Nanofibers chemistry, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Polyesters chemistry

Abstract

Electrospun nanofibrous scaffolds are renowned for their ability to mimic the microstructure of the extracellular matrix (ECM). However, they often fail to replicate the geometry of target tissues, and the biocompatibility of these scaffolds those made from synthetic polymers is always limited due to the lack of cell binding sites. To address these issues, we proposed an innovative approach that combined unidirectional freeze-drying and electrospinning. During this process, electrospun polycaprolactone (PCL) nanofibers were chopped into nanofibrils, which range in size up to several hundred micrometers, and were incorporated into the chitosan scaffolds via unidirectional freeze-drying. In these scaffolds, the chitosan phase was responsible for maintaining the structural integrity at the macroscale, while the embedded nanofibers enhanced the surface topography at the microscale. The resulting scaffolds exhibited a high porosity of 90% and an impressive water uptake capacity of 2500%. Furthermore, 3T3 fibroblast cells showed strong interactions with the scaffolds, characterized by high rates of cell proliferation and viability. The cells also displayed significant orientation along the direction of the pores, suggesting that the scaffolds effectively guided cellular growth., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier Ltd. All rights reserved.)

Published

2024

30. Tailored environments for directed mesenchymal stromal cell proliferation and differentiation using decellularized extracellular matrices in conjunction with substrate modulus.

Author

Yang MC, Chin IL, Fang H, Drack A, Nour S, Choi YS, O'Connor AJ, Greening DW, Kalionis B, and Heath DE

Subjects

Osteogenesis, Animals, Humans, Elastic Modulus, YAP-Signaling Proteins, Acrylic Resins chemistry, Mesenchymal Stem Cells cytology, Mesenchymal Stem Cells metabolism, Extracellular Matrix chemistry, Extracellular Matrix metabolism, Cell Proliferation, Cell Differentiation

Abstract

Decellularised extracellular matrix (dECM) produced by mesenchymal stromal cells (MSCs) is a promising biomaterial for improving the ex vivo expansion of MSCs. The dECMs are often deposited on high modulus surfaces such as tissue culture plastic or glass, and subsequent differentiation assays often bias towards osteogenesis. We tested the hypothesis that dECM deposited on substrates of varying modulus will produce cell culture environments that are tailored to promote the proliferation and/or lineage-specific differentiation of MSCs. dECM was produced on type I collagen-functionalised polyacrylamide hydrogels with discrete moduli (∼4, 10, and 40 kPa) or in a linear gradient of modulus that spans the same range, and the substrates were used as culture surfaces for MSCs. Fluorescence spectroscopy and mass spectrometry characterization revealed structural compositional changes in the dECM as a function of substrate modulus. Softer substrates (4 kPa) with dECM supported the largest number of MSCs after 7 days (∼1.6-fold increase compared to glass). Additionally, osteogenic differentiation was greatest on high modulus substrates (40 kPa and glass) with dECM. Nuclear translocation of YAP1 was observed on all surfaces with a modulus of 10 kPa or greater and may be a driver for the increased osteogenesis on the high modulus surfaces. These data demonstrate that dECM technology can be integrated with environmental parameters such as substrate modulus to improve/tailor MSC proliferation and differentiation during ex vivo culture. These results have potential impact in the improved expansion of MSCs for tailored therapeutic applications and in the development of advanced tissue engineering scaffolds. STATEMENT OF SIGNIFICANCE: Mesenchymal stromal cells (MSCs) are extensively used in tissue engineering and regenerative medicine due to their ability to proliferate, differentiate, and modulate the immune environment. Controlling MSC behavior is critical for advances in the field. Decellularised extracellular matrix (dECM) can maintain MSC properties in culture, increase their proliferation rate and capacity, and enhance their stimulated differentiation. Substrate stiffness is another key driver of cell function, and previous reports have primarily looked at dECM deposition and function on stiff substrates such as glass. Herein, we produce dECM on substrates of varying stiffness to create tailored environments that enhance desired MSC properties such as proliferation and differentiation. Additionally, we complete mechanistic studies including quantitative mass spec of the ECM to understand the biological function., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2024

31. Elastogenesis in Focus: Navigating Elastic Fibers Synthesis for Advanced Dermal Biomaterial Formulation.

Author

Krymchenko R, Coşar Kutluoğlu G, van Hout N, Manikowski D, Doberenz C, van Kuppevelt TH, and Daamen WF

Subjects

Humans, Animals, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Elasticity, Skin, Artificial, Tissue Engineering methods, Elastin chemistry, Elastin metabolism, Biocompatible Materials chemistry, Elastic Tissue metabolism, Elastic Tissue chemistry

Abstract

Elastin, a fibrous extracellular matrix (ECM) protein, is the main component of elastic fibers that are involved in tissues' elasticity and resilience, enabling them to undergo reversible extensibility and to endure repetitive mechanical stress. After wounding, it is challenging to regenerate elastic fibers and biomaterials developed thus far have struggled to induce its biosynthesis. This review provides a comprehensive summary of elastic fibers synthesis at the cellular level and its implications for biomaterial formulation, with a particular focus on dermal substitutes. The review delves into the intricate process of elastogenesis by cells and investigates potential triggers for elastogenesis encompassing elastin-related compounds, ECM components, and other molecules for their potential role in inducing elastin formation. Understanding of the elastogenic processes is essential for developing biomaterials that trigger not only the synthesis of the elastin protein, but also the formation of a functional and branched elastic fiber network., (© 2024 The Author(s). Advanced Healthcare Materials published by Wiley‐VCH GmbH.)

Published

2024

32. Advancing Synthetic Hydrogels through Nature-Inspired Materials Chemistry.

Author

Soliman BG, Nguyen AK, Gooding JJ, and Kilian KA

Subjects

Animals, Humans, Biomimetic Materials chemistry, Biocompatible Materials chemistry, Hydrogels chemistry, Extracellular Matrix chemistry, Extracellular Matrix metabolism, Tissue Engineering methods

Abstract

Synthetic extracellular matrix (ECM) mimics that can recapitulate the complex biochemical and mechanical nature of native tissues are needed for advanced models of development and disease. Biomedical research has heavily relied on the use of animal-derived biomaterials, which is now impeding their translational potential and convoluting the biological insights gleaned from in vitro tissue models. Natural hydrogels have long served as a convenient and effective cell culture tool, but advances in materials chemistry and fabrication techniques now present promising new avenues for creating xenogenic-free ECM substitutes appropriate for organotypic models and microphysiological systems. However, significant challenges remain in creating synthetic matrices that can approximate the structural sophistication, biochemical complexity, and dynamic functionality of native tissues. This review summarizes key properties of the native ECM, and discusses recent approaches used to systematically decouple and tune these properties in synthetic matrices. The importance of dynamic ECM mechanics, such as viscoelasticity and matrix plasticity, is also discussed, particularly within the context of organoid and engineered tissue matrices. Emerging design strategies to mimic these dynamic mechanical properties are reviewed, such as multi-network hydrogels, supramolecular chemistry, and hydrogels assembled from biological monomers., (© 2024 The Author(s). Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

33. Innovative Substrate Design with Basement Membrane Components for Enhanced Endothelial Cell Function and Endothelization.

Author

Snyder Y and Jana S

Subjects

Humans, Animals, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Human Umbilical Vein Endothelial Cells metabolism, Tissue Engineering methods, Nitric Oxide metabolism, Laminin chemistry, Laminin metabolism, Fibroblasts metabolism, Fibroblasts cytology, Basement Membrane metabolism, Cell Proliferation, Endothelial Cells metabolism, Endothelial Cells cytology

Abstract

Enhancing endothelial cell growth on small-diameter vascular grafts produced from decellularized tissues or synthetic substrates is pivotal for preventing thrombosis. While optimized decellularization protocols can preserve the structure and many components of the extracellular matrix (ECM), the process can still lead to the loss of crucial basement membrane proteins, such as laminin, collagen IV, and perlecan, which are pivotal for endothelial cell adherence and functional growth. This loss can result in poor endothelialization and endothelial cell activation causing thrombosis and intimal hyperplasia. To address this, the basement membrane's ECM is emulated on fiber substrates, providing a more physiological environment for endothelial cells. Thus, fibroblasts are cultured on fiber substrates to produce an ECM membrane substrate (EMMS) with basement membrane proteins. The EMMS then underwent antigen removal (AR) treatment to eliminate antigens from the membrane while preserving essential proteins and producing an AR-treated membrane substrate (AMS). Subsequently, human endothelial cells cultured on the AMS exhibited superior proliferation, nitric oxide production, and increased expression of endothelial markers of quiescence/homeostasis, along with autophagy and antithrombotic factors, compared to those on the decellularized aortic tissue. This strategy showed the potential of pre-endowing fiber substrates with a basement membrane to enable better endothelization., (© 2024 Wiley‐VCH GmbH.)

Published

2024

34. Imaging Diffusion and Stability of Single-Chain Polymeric Nanoparticles in a Multi-Gel Tumor-on-a-Chip Microfluidic Device.

Author

Deng L, Olea AR, Ortiz-Perez A, Sun B, Wang J, Pujals S, Palmans ARA, and Albertazzi L

Subjects

Humans, MCF-7 Cells, Polymers chemistry, Tumor Microenvironment, Extracellular Matrix chemistry, Extracellular Matrix metabolism, Collagen chemistry, Diffusion, Hyaluronic Acid chemistry, Lab-On-A-Chip Devices, Nanoparticles chemistry, Spheroids, Cellular

Abstract

The performance of single-chain polymeric nanoparticles (SCPNs) in biomedical applications highly depends on their conformational stability in cellular environments. Until now, such stability studies are limited to 2D cell culture models, which do not recapitulate the 3D tumor microenvironment well. Here, a microfluidic tumor-on-a-chip model is introduced that recreates the tumor milieu and allows in-depth insights into the diffusion, cellular uptake, and stability of SCPNs. The chip contains Matrigel/collagen-hyaluronic acid as extracellular matrix (ECM) models and is seeded with cancer cell MCF7 spheroids. With this 3D platform, it is assessed how the polymer's microstructure affects the SCPN's behavior when crossing the ECM, and evaluates SCPN internalization in 3D cancer cells. A library of SCPNs varying in microstructure is prepared. All SCPNs show efficient ECM penetration but their cellular uptake/stability behavior depends on the microstructure. Glucose-based nanoparticles display the highest spheroid uptake, followed by charged nanoparticles. Charged nanoparticles possess an open conformation while nanoparticles stabilized by internal hydrogen bonding retain a folded structure inside the tumor spheroids. The 3D microfluidic tumor-on-a-chip platform is an efficient tool to elucidate the interplay between polymer microstructure and SCPN's stability, a key factor for the rational design of nanoparticles for targeted biological applications., (© 2024 The Authors. Small Methods published by Wiley‐VCH GmbH.)

Published

2024

35. Extracellular Matrix-Surrogate Advanced Functional Composite Biomaterials for Tissue Repair and Regeneration.

Author

Vahidi M, Rizkalla AS, and Mequanint K

Subjects

Humans, Animals, Regeneration drug effects, Biomimetic Materials chemistry, Tissue Scaffolds chemistry, Extracellular Matrix chemistry, Extracellular Matrix metabolism, Biocompatible Materials chemistry, Tissue Engineering methods

Abstract

Native tissues, comprising multiple cell types and extracellular matrix components, are inherently composites. Mimicking the intricate structure, functionality, and dynamic properties of native composite tissues represents a significant frontier in biomaterials science and tissue engineering research. Biomimetic composite biomaterials combine the benefits of different components, such as polymers, ceramics, metals, and biomolecules, to create tissue-template materials that closely simulate the structure and functionality of native tissues. While the design of composite biomaterials and their in vitro testing are frequently reviewed, there is a considerable gap in whole animal studies that provides insight into the progress toward clinical translation. Herein, we provide an insightful critical review of advanced composite biomaterials applicable in several tissues. The incorporation of bioactive cues and signaling molecules into composite biomaterials to mimic the native microenvironment is discussed. Strategies for the spatiotemporal release of growth factors, cytokines, and extracellular matrix proteins are elucidated, highlighting their role in guiding cellular behavior, promoting tissue regeneration, and modulating immune responses. Advanced composite biomaterials design challenges, such as achieving optimal mechanical properties, improving long-term stability, and integrating multifunctionality into composite biomaterials and future directions, are discussed. We believe that this manuscript provides the reader with a timely perspective on composite biomaterials., (© 2024 The Author(s). Advanced Healthcare Materials published by Wiley‐VCH GmbH.)

Published

2024

36. Collagen-rich liver-derived extracellular matrix hydrogels augment survival and function of primary rat liver sinusoidal endothelial cells and hepatocytes.

Author

Wang J, Zhao F, Brouwer LA, Buist-Homan M, Wolters JC, Moshage H, and Harmsen MC

Subjects

Animals, Rats, Swine, Cells, Cultured, Male, Hydrogels chemistry, Hydrogels pharmacology, Hepatocytes metabolism, Hepatocytes drug effects, Hepatocytes cytology, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Endothelial Cells metabolism, Endothelial Cells cytology, Endothelial Cells drug effects, Cell Survival drug effects, Collagen chemistry, Collagen pharmacology, Collagen metabolism, Liver metabolism, Liver cytology

Abstract

Liver sinusoidal endothelial cells (LSECs) are key targets for addressing metabolic dysfunction-associated steatotic liver disease (MASLD). However, isolating and culturing primary LSECs is challenging due to rapid dedifferentiation, resulting in loss of function. The extracellular matrix (ECM) likely plays a crucial role in maintaining the fate and function of LSECs. In this study, we explored the influence of liver-ECM (L-ECM) on liver cells and developed culture conditions that maintain the differentiated function of liver cells in vitro for prolonged periods. Porcine liver-derived L-ECM, containing 34.9 % protein, 0.045 % glycosaminoglycans, and negligible residual DNA (41.2 ng/mg), was utilized to culture primary rat liver cells in generated hydrogels. Proteomic analyses and molecular weight distribution of proteins of solubilized L-ECM revealed the typical diverse ECM core matrisome, with abundant collagens. L-ECM hydrogels showed suitable stiffness and stress relaxation properties. Furthermore, we demonstrated that collagen-rich L-ECM hydrogels enhanced LSECs' and hepatocytes' viability, and reduced the dedifferentiation rate of LSECs. In addition, hepatocyte function was maintained longer by culture on L-ECM hydrogels compared to traditional culturing. These beneficial effects are likely attributed to the bioactive macromolecules including collagens, and mechanical and microarchitectural properties of the L-ECM hydrogels., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

37. Collagen as the extracellular matrix biomaterials in the arena of medical sciences.

Author

Sowbhagya R, Muktha H, Ramakrishnaiah TN, Surendra AS, Sushma SM, Tejaswini C, Roopini K, and Rajashekara S

Subjects

Humans, Animals, Tissue Scaffolds chemistry, Bone Regeneration drug effects, Dentistry, Biocompatible Materials chemistry, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Tissue Engineering, Wound Healing drug effects, Collagen chemistry, Collagen metabolism

Abstract

Collagen is a multipurpose material that has several applications in the health care, dental care, and pharmaceutical industries. Crosslinked compacted solids or lattice-like gels can be made from collagen. Biocompatibility, biodegradability, and wound-healing properties make collagen a popular scaffold material for cardiovascular, dentistry, and bone tissue engineering. Due to its essential role in the control of several of these processes, collagen has been employed as a wound-healing adjunct. It forms a major component of the extracellular matrix and regulates wound healing in its fibrillar or soluble forms. Collagen supports cardiovascular and other soft tissues. Oral wounds have been dressed with resorbable forms of collagen for closure of graft and extraction sites, and to aid healing. This present review is concentrated on the use of collagen in bone regeneration, wound healing, cardiovascular tissue engineering, and dentistry., Competing Interests: Declaration of Competing Interest The authors declare that they have no conflict of interest., (Copyright © 2024 Elsevier Ltd. All rights reserved.)

Published

2024

38. Zwitterionic Granular Hydrogel for Cartilage Tissue Engineering.

Author

Asadikorayem M, Surman F, Weber P, Weber D, and Zenobi-Wong M

Subjects

Humans, Methacrylates chemistry, Cell Proliferation drug effects, Extracellular Matrix chemistry, Extracellular Matrix metabolism, Cells, Cultured, Betaine chemistry, Betaine analogs & derivatives, Biocompatible Materials chemistry, Biocompatible Materials pharmacology, Cell Survival drug effects, Tissue Engineering methods, Hydrogels chemistry, Chondrocytes cytology, Chondrocytes metabolism, Cartilage cytology

Abstract

Zwitterionic hydrogels have high potential for cartilage tissue engineering due to their ultra-hydrophilicity, nonimmunogenicity, and superior antifouling properties. However, their application in this field has been limited so far, due to the lack of injectable zwitterionic hydrogels that allow for encapsulation of cells in a biocompatible manner. Herein, a novel strategy is developed to engineer cartilage employing zwitterionic granular hydrogels that are injectable, self-healing, in situ crosslinkable and allow for direct encapsulation of cells with biocompatibility. The granular hydrogel is produced by mechanical fragmentation of bulk photocrosslinked hydrogels made of zwitterionic carboxybetaine acrylamide (CBAA), or a mixture of CBAA and zwitterionic sulfobetaine methacrylate (SBMA). The produced microgels are enzymatically crosslinkable using horseradish peroxidase, to quickly stabilize the construct, resulting in a microporous hydrogel. Encapsulated human primary chondrocytes are highly viable and able to proliferate, migrate, and produce cartilaginous extracellular matrix (ECM) in the zwitterionic granular hydrogel. It is also shown that by increasing hydrogel porosity and incorporation of SBMA, cell proliferation and ECM secretion are further improved. This strategy is a simple and scalable method, which has high potential for expanding the versatility and application of zwitterionic hydrogels for diverse tissue engineering applications., (© 2023 The Authors. Advanced Healthcare Materials published by Wiley‐VCH GmbH.)

Published

2024

39. Dynamic composite hydrogels of gelatin methacryloyl (GelMA) with supramolecular fibers for tissue engineering applications.

Author

Chalard AE, Porritt H, Lam Po Tang EJ, Taberner AJ, Winbo A, Ahmad AM, Fitremann J, and Malmström J

Subjects

Animals, Tissue Scaffolds chemistry, Extracellular Matrix chemistry, Extracellular Matrix metabolism, Rats, Elastic Modulus, Gelatin chemistry, Hydrogels chemistry, Tissue Engineering methods, Methacrylates chemistry, Fibroblasts drug effects, Biocompatible Materials chemistry

Abstract

In the field of tissue engineering, there is a growing need for biomaterials with structural properties that replicate the native characteristics of the extracellular matrix (ECM). It is important to include fibrous structures into ECM mimics, especially when constructing scar models. Additionally, including a dynamic aspect to cell-laden biomaterials is particularly interesting, since native ECM is constantly reshaped by cells. Composite hydrogels are developed to bring different combinations of structures and properties to a scaffold by using different types and sources of materials. In this work, we aimed to combine gelatin methacryloyl (GelMA) with biocompatible supramolecular fibers made of a small self-assembling sugar-derived molecule (N-heptyl-D-galactonamide, GalC7). The GalC7 fibers were directly grown in the GelMA through a thermal process, and it was shown that the presence of the fibrous network increased the Young's modulus of GelMA. Due to the non-covalent interactions that govern the self-assembly, these fibers were observed to dissolve over time, leading to a dynamic softening of the composite gels. Cardiac fibroblast cells were successfully encapsulated into composite gels for 7 days, showing excellent biocompatibility and fibroblasts extending in an elongated morphology, most likely in the channels left by the fibers after their degradation. These novel composite hydrogels present unique properties and could be used as tools to study biological processes such as fibrosis, vascularization and invasion., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: J. Fitremann can receive royalties from the selling of N-heptyl-D-galactonamide by the company Innov'Orga (France). These royalties expected would represent very low amounts and in any case they will not influence her scientific statements related to with this molecule. J. Malmström is an associate editor of Biomaterials Advances. If there are other authors, they declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

40. The Importance of Effective Ligand Concentration to Direct Epithelial Cell Polarity in Dynamic Hydrogels.

Author

Rijns L, Hagelaars MJ, van der Tol JJB, Loerakker S, Bouten CVC, and Dankers PYW

Subjects

Ligands, Humans, Animals, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Madin Darby Canine Kidney Cells, Integrins metabolism, Dogs, Biocompatible Materials chemistry, Hydrogels chemistry, Epithelial Cells cytology, Epithelial Cells metabolism, Cell Polarity

Abstract

Epithelial cysts and organoids are multicellular hollow structures formed by correctly polarized epithelial cells. Important in steering these cysts from single cells is the dynamic regulation of extracellular matrix presented ligands, and matrix dynamics. Here, control over the effective ligand concentration is introduced, decoupled from bulk and local mechanical properties, in synthetic dynamic supramolecular hydrogels formed through noncovalent crosslinking of supramolecular fibers. Control over the effective ligand concentration is realized by 1) keeping the ligand concentration constant, but changing the concentration of nonfunctionalized molecules or by 2) varying the ligand concentration, while keeping the concentration of non-functionalized molecules constant. The results show that in 2D, the effective ligand concentration within the supramolecular fibers rather than gel stiffness (from 0.1 to 8 kPa) regulates epithelial polarity. In 3D, increasing the effective ligand concentration from 0.5 × 10 -3 to 2 × 10 -3 m strengthens the effect of increased gel stiffness from 0.1 to 2 kPa, to synergistically yield more correctly polarized cysts. Through integrin manipulation, it is shown that epithelial polarity is regulated by tension-based homeostasis between cells and matrix. The results reveal the effective ligand concentration as influential factor in regulating epithelial polarity and provide insights on engineering of synthetic biomaterials for cell and organoid culture., (© 2023 The Authors. Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

41. Enhancing organoid culture: harnessing the potential of decellularized extracellular matrix hydrogels for mimicking microenvironments.

Author

Li C, An N, Song Q, Hu Y, Yin W, Wang Q, Le Y, Pan W, Yan X, Wang Y, and Liu J

Subjects

Humans, Animals, Tissue Scaffolds chemistry, Extracellular Matrix chemistry, Organoids, Hydrogels chemistry, Decellularized Extracellular Matrix chemistry, Tissue Engineering methods

Abstract

Over the past decade, organoids have emerged as a prevalent and promising research tool, mirroring the physiological architecture of the human body. However, as the field advances, the traditional use of animal or tumor-derived extracellular matrix (ECM) as scaffolds has become increasingly inadequate. This shift has led to a focus on developing synthetic scaffolds, particularly hydrogels, that more accurately mimic three-dimensional (3D) tissue structures and dynamics in vitro. The ECM-cell interaction is crucial for organoid growth, necessitating hydrogels that meet organoid-specific requirements through modifiable physical and compositional properties. Advanced composite hydrogels have been engineered to more effectively replicate in vivo conditions, offering a more accurate representation of human organs compared to traditional matrices. This review explores the evolution and current uses of decellularized ECM scaffolds, emphasizing the application of decellularized ECM hydrogels in organoid culture. It also explores the fabrication of composite hydrogels and the prospects for their future use in organoid systems., (© 2024. The Author(s).)

Published

2024

42. Bioactivity and in vitro immunological studies of xenogeneic decellularized extracellular matrix scaffolds for implantable applications.

Author

Yu Q, Gao Y, Guo J, Wang X, Gao X, Zhao Y, Liu Y, Wen M, Zhang X, and An M

Subjects

Animals, Mice, Swine, RAW 264.7 Cells, Extracellular Matrix chemistry, Biocompatible Materials chemistry, Humans, Cell Proliferation, Tissue Engineering, Tissue Scaffolds chemistry, Decellularized Extracellular Matrix chemistry

Abstract

Decellularized scaffolds retain the main bioactive substances of the extracellular matrix, which can better promote cell proliferation and matrix reconstruction at the defect site, and have great potential for morphological and functional restoration in patients with tissue defects. Due to the safety of the material source of allogeneic decellularized scaffolds, there is a great limitation in their clinical application, so the preparation and evaluation of xenodermal acellular scaffolds have attracted much attention. In terms of skin tissue structure and function, porcine skin has a high degree of similarity to human skin and has the advantages of sufficient quantity and no ethical issues. However, there is a risk of immune rejection after xenodermal acellular scaffold transplantation. To address the above problems, this paper focuses on porcine dermal decellularized scaffolds prepared using two common decellularization preparation methods and compares the decellularization efficiency, retention of active components of the extracellular matrix, structural characterization of the decellularized scaffolds, and the effect of porcine dermal decellularized scaffolds on mouse Raw264.7 macrophages, so as to make a functional evaluation of the active components and immune effects of porcine dermal decellularized scaffolds, and to provide a reference for filling trauma-induced defects in humans.

Published

2024

43. A capsule-based scaffold incorporating decellularized extracellular matrix and curcumin for islet beta cell therapy in type 1 diabetes mellitus.

Author

Ma H, Xu J, Fang H, Su Y, Lu Y, Shu Y, Liu W, Li B, Cheng YY, Nie Y, Zhong Y, and Song K

Subjects

Animals, Mice, Swine, Islets of Langerhans Transplantation, Capsules chemistry, Insulin metabolism, Diabetes Mellitus, Experimental therapy, Cell Line, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Diabetes Mellitus, Type 1 therapy, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells metabolism, Insulin-Secreting Cells cytology, Tissue Scaffolds chemistry, Curcumin pharmacology, Curcumin chemistry, Decellularized Extracellular Matrix chemistry, Decellularized Extracellular Matrix pharmacology

Abstract

The transplantation of islet beta cells offers an alternative to heterotopic islet transplantation for treating type 1 diabetes mellitus (T1DM). However, the use of systemic immunosuppressive drugs in islet transplantation poses significant risks to the body. To address this issue, we constructed an encapsulated hybrid scaffold loaded with islet beta cells. This article focuses on the preparation of the encapsulated structure using 3D printing, which incorporates porcine pancreas decellularized extracellular matrix (dECM) to the core scaffold. The improved decellularization method successfully preserved a substantial proportion of protein (such as Collagen I and Laminins) architecture and glycosaminoglycans in the dECM hydrogel, while effectively removing most of the DNA. The inclusion of dECM enhanced the physical and chemical properties of the scaffold, resulting in a porosity of 83.62% ± 1.09% and a tensile stress of 1.85 ± 0.16 MPa. In teams of biological activity, dECM demonstrated enhanced proliferation, differentiation, and expression of transcription factors such as Ki67, PDX1, and NKX6.1, leading to improved insulin secretion function in MIN-6 pancreatic beta cells. In the glucose-stimulated insulin secretion experiment on day 21, the maximum insulin secretion from the encapsulated structure reached 1.96 ± 0.08 mIU ml -1 , representing a 44% increase compared to the control group. Furthermore, conventional capsule scaffolds leaverage the compatibility of natural biomaterials with macrophages to mitigate immune rejection. Here, incorporating curcumin into the capsule scaffold significantly reduced the secretion of pro-inflammatory cytokine (IL-1 β , IL-6, TNF- α , IFN- γ ) secretion by RAW264.7 macrophages and T cells in T1DM mice. This approach protected pancreatic islet cells against immune cell infiltration mediated by inflammatory factors and prevented insulitis. Overall, the encapsulated scaffold developed in this study shows promise as a natural platform for clinical treatment of T1DM., (© 2024 IOP Publishing Ltd. All rights, including for text and data mining, AI training, and similar technologies, are reserved.)

Published

2024

44. A viscoelastic-stochastic model of cell adhesion considering matrix morphology and medium viscoelasticity.

Author

Li S, Huang C, Liu H, Han X, Wang Z, Chen Z, Huang J, and Wang Z

Subjects

Viscosity, Monte Carlo Method, Cell Adhesion, Elasticity, Extracellular Matrix chemistry, Models, Biological

Abstract

Quantitative investigation of the adhesive behavior between cells and the extracellular matrix (ECM) through molecular bonds is essential for cell culture and bio-medical engineering in vitro . Cell adhesion is a complex multi-scale behavior that includes temporal and spatial scales. However, the influence of the cell and matrix creep effect and the complex spatial morphology characteristics of the matrix on the cell adhesion mechanism is unclear. In the present study, an idealized theoretical model has been considered, where the adhesion of cells and the matrix is simplified into a planar strain problem of homogeneous viscoelastic half-spaces. Furthermore, a new viscoelastic-stochastic model that considers the morphological characteristics of the matrix, the viscoelasticity of the cell and the viscoelasticity of the substrate was developed under the action of a constant external force. The model characterizes the matrix topographical features by fractal dimension (FD), interprets the effects of FD and medium viscoelasticity on the molecular bond force and the receptor-ligand bond re-association rate and reveals a new mechanism for the stable adhesion of molecular bond clusters by Monte Carlo simulation. Based on this model, it was identified that the temporal and spatial distribution of molecular bond force was affected by the matrix FD and the lifetime and stability of the molecular bond cluster could be significantly improved by tuning the FD. At the same time, the viscoelastic creep effect of the cell and matrix increased the re-association rate of open bonds and could expand the window of stable adhesion more flexibly.

Published

2024

45. Decellularized extracellular matrix-based bioengineered 3D breast cancer scaffolds for personalized therapy and drug screening.

Author

Bhattacharya T, Kumari M, Kaur K, Kaity S, Arumugam S, Ravichandiran V, and Roy S

Subjects

Humans, Female, Precision Medicine, Antineoplastic Agents chemistry, Antineoplastic Agents pharmacology, Extracellular Matrix chemistry, Extracellular Matrix metabolism, Drug Screening Assays, Antitumor, Animals, Tissue Engineering, Drug Evaluation, Preclinical, Tumor Microenvironment, Breast Neoplasms pathology, Tissue Scaffolds chemistry, Decellularized Extracellular Matrix chemistry

Abstract

Breast cancer (BC) is the second deadliest cancer after lung cancer. Similar to all cancers, it is also driven by a 3D microenvironment. The extracellular matrix (ECM) is an essential component of the 3D tumor micro-environment, wherein it functions as a scaffold for cells and provides metabolic support. BC is characterized by alterations in the ECM. Various studies have attempted to mimic BC-specific ECMs using artificial materials, such as Matrigel. Nevertheless, research has proven that naturally derived decellularized extracellular matrices (dECMs) are superior in providing the essential in vivo -like cues needed to mimic a cancer-like environment. Developing in vitro 3-D BC models is not straightforward and requires extensive analysis of the data established by researchers. For the benefit of researchers, in this review, we have tried to highlight all developmental studies that have been conducted by various scientists so far. The analysis of the conclusions drawn from these studies is also discussed. The advantages and drawbacks of the decellularization methods employed for generating BC scaffolds will be covered, and the review will shed light on how dECM scaffolds help develop a BC environment. The later stages of the article will also focus on immunogenicity issues arising from decellularization and the origin of the tissue. Finally, this review will also discuss the biofabrication of matrices, which is the core part of the bioengineering process.

Published

2024

46. Engineering an Extracellular Matrix Mimic Using Hemoglobin Protein Nanofibrils.

Author

Chen Q, Steinmetz K, Oh JK, Travaš-Sejdić J, and Domigan LJ

Subjects

Animals, Cattle, Cell Proliferation drug effects, Cell Adhesion drug effects, Tissue Scaffolds chemistry, Particle Size, Mice, Fibroblasts, Hemoglobins chemistry, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Nanofibers chemistry, Tissue Engineering, Materials Testing, Biocompatible Materials chemistry, Biocompatible Materials pharmacology, Polyesters chemistry

Abstract

Extracellular matrix (ECM) is essential for tissue development, providing structural support and a microenvironment that is necessary for cells. As tissue engineering advances, there is a growing demand for ECM mimics. Polycaprolactone (PCL) is a commonly used synthetic polymer for ECM mimic materials. However, its biologically inactive surface limits its direct application in tissue engineering. Our study aimed to improve the biocompatibility of PCL by incorporating hemoglobin nanofibrils (HbFs) into PCL using an electrospinning technique. HbFs were formed from bovine hemoglobin (Hb) extracted from industrial byproducts and designed to offer PCL an improved cell adhesion property. The fabricated HbFs@PCL electrospun scaffold exhibits improved fibroblast adherence, proliferation, and deeper fibroblast infiltration into the scaffold compared with the pure PCL scaffold, indicating its potential to be an ECM mimic. This study represents the pioneering utilization of Hb-sourced nanofibrils in the electrospun PCL scaffolds for tissue engineering applications.

Published

2024

47. Bone-derived extracellular matrix hydrogel from thrombospondin-2 knock-out mice for bone repair.

Author

Chen Z, Zhang J, Lee FY, and Kyriakides TR

Subjects

Animals, Humans, Mice, Bone and Bones drug effects, Bone Regeneration drug effects, Decellularized Extracellular Matrix chemistry, Decellularized Extracellular Matrix pharmacology, Mesenchymal Stem Cells metabolism, Mesenchymal Stem Cells cytology, Mice, Knockout, Neovascularization, Physiologic drug effects, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Human Umbilical Vein Endothelial Cells metabolism, Hydrogels chemistry, Thrombospondins metabolism, Thrombospondins genetics

Abstract

Bone extracellular matrix (ECM) has been shown to mimic aspects of the tissue's complex microenvironment, suggesting its potential role in promoting bone repair. However, current ECM-based therapies suffer from limitations such as inefficient scale-up, lack of mechanical integrity, and sub-optimal efficacy. Here, we fabricated hydrogels from decellularized ECM (dECM) from wild type (WT) and thrombospondin-2 knock-out (TSP2KO) mouse bones. TSP2KO bone ECM hydrogel was found to have distinct mechanical properties and collagen fibril assembly from WT. Furthermore, TSP2KO hydrogel promoted mesenchymal stem cell (MSC) attachment, spreading, and invasion in vitro. Similarly, it promoted formation of tube-like structures by human umbilical vein endothelial cells (HUVECs). When applied to a murine calvarial defect model, TSP2KO hydrogel enhanced repair, in part, due to increased angiogenesis. Our study suggests the pro-angiogenic therapeutic potential of TSP2KO bone ECM hydrogel in bone repair. STATEMENT OF SIGNIFICANCE: The study describes the first successful preparation of a novel hydrogel made from decellularized bones from wild-type mice and mice lacking thrombospondin-2 (TSP2). Hydrogels from TSP2 knock-out (TSP2KO) bones have unique characteristics in structure and biomechanics. These gels interacted well with cells in vitro and helped repair damaged bone in a mouse model. Therefore, TSP2KO bone-derived hydrogel has translational potential for accelerating repair of bone defects that are otherwise difficult to heal. This study not only creates a new material with promise for accelerated healing, but also validates tunability of native biomaterials by genetic engineering., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published

2024

48. Mimicking the extracellular world: from natural to fully synthetic matrices utilizing supramolecular biomaterials.

Author

Rijns L, Rutten MGTA, Vrehen AF, Aldana AA, Baker MB, and Dankers PYW

Subjects

Humans, Tissue Engineering, Animals, Extracellular Matrix chemistry, Extracellular Matrix metabolism, Hydrogels chemistry, Biomimetic Materials chemistry, Biocompatible Materials chemistry

Abstract

The extracellular matrix (ECM) has evolved around complex covalent and non-covalent interactions to create impressive function-from cellular signaling to constant remodeling. A major challenge in the biomedical field is the de novo design and control of synthetic ECMs for applications ranging from tissue engineering to neuromodulation to bioelectronics. As we move towards recreating the ECM's complexity in hydrogels, the field has taken several approaches to recapitulate the main important features of the native ECM ( i.e. mechanical, bioactive and dynamic properties). In this review, we first describe the wide variety of hydrogel systems that are currently used, ranging from fully natural to completely synthetic to hybrid versions, highlighting the advantages and limitations of each class. Then, we shift towards supramolecular hydrogels that show great potential for their use as ECM mimics due to their biomimetic hierarchical structure, inherent (controllable) dynamic properties and their modular design, allowing for precise control over their mechanical and biochemical properties. In order to make the next step in the complexity of synthetic ECM-mimetic hydrogels, we must leverage the supramolecular self-assembly seen in the native ECM; we therefore propose to use supramolecular monomers to create larger, hierarchical, co-assembled hydrogels with complex and synergistic mechanical, bioactive and dynamic features.

Published

2024

49. Maneuvering the mineralization of self-assembled peptide nanofibers for designing mechanically-stiffened self-healable composites toward bone-mimetic ECM.

Author

Mavlankar NA, Nath D, Chandran Y, Gupta N, Singh A, Balakrishnan V, and Pal A

Subjects

Humans, Biomimetic Materials chemistry, Hydrogels chemistry, Bone and Bones, Biocompatible Materials chemistry, Biocompatible Materials pharmacology, Nanofibers chemistry, Peptides chemistry, Peptides pharmacology, Extracellular Matrix metabolism, Extracellular Matrix chemistry

Abstract

Extracellular matrix (ECM) elasticity remains a crucial parameter to determine cell-material interactions ( viz. adhesion, growth, and differentiation), cellular communication, and migration that are essential to tissue repair and regeneration. Supramolecular peptide hydrogels with their 3-dimensional porous network and tuneable mechanical properties have emerged as an excellent class of ECM-mimetic biomaterials with relevant dynamic attributes and bioactivity. Here, we demonstrate the design of minimalist amyloid-inspired peptide amphiphiles, CnPA ( n = 6, 8, 10, 12) with tuneable peptide nanostructures that are efficiently biomineralized and cross-linked using bioactive silicates. Such hydrogel composites, CnBG exhibit excellent mechanical attributes and possess excellent self-healing abilities and collagen-like strain-stiffening ability as desired for bone ECM mimetic scaffold. The composites exhibited the formation of a hydroxyapatite mineral phase upon incubation in a simulated body fluid that rendered mechanical stiffness akin to the hydroxyapatite-bridged collagen fibers to match the bone tissue elasticity eventually. In a nutshell, peptide nanostructure-guided temporal effects and mechanical attributes demonstrate C8BG to be an optimal composite. Finally, such constructs feature the potential for adhesion, proliferation of U2OS cells, high alkaline phosphatase activity, and osteoconductivity.

Published

2024

50. Cell-Material Interactions in Covalent Adaptable Thioester Hydrogels.

Author

Desai S, Carberry B, Anseth KS, and Schultz KM

Subjects

Humans, Polyethylene Glycols chemistry, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Esters chemistry, Tissue Scaffolds chemistry, Hydrogels chemistry, Mesenchymal Stem Cells metabolism, Mesenchymal Stem Cells cytology, Rheology, Sulfhydryl Compounds chemistry

Abstract

Covalent adaptable networks (CANs) are polymeric networks with cross-links that can break and reform in response to external stimuli, including pH, shear, and temperature, making them potential materials for use as injectable cell delivery vehicles. In the native niche, cells rearrange the extracellular matrix (ECM) to undergo basic functions including migration, spreading, and proliferation. Bond rearrangement enables these hydrogels to mimic viscoelastic properties of the native ECM which promote migration and delivery from the material to the native tissue. In this work, we characterize thioester CANs to inform their design as effective cell delivery vehicles. Using bulk rheology, we characterize the rearrangement of these networks when they are subjected to strain, which mimics the strain applied by a syringe, and using multiple particle tracking microrheology (MPT) we measure cell-mediated remodeling of the pericellular region. Thioester networks are formed by photopolymerizing 8-arm poly(ethylene glycol) (PEG)-thiol and PEG-thioester norbornene. Bulk rheology measures scaffold properties during low and high strain and demonstrates that thioester scaffolds can recover rheological properties after high strain is applied. We then 3D encapsulated human mesenchymal stem cells (hMSCs) in thioester scaffolds. Using MPT, we characterize degradation in the pericellular region. Encapsulated hMSCs degrade these scaffolds within ≈4 days post-encapsulation. We hypothesize that this degradation is mainly due to cytoskeletal tension that cells apply to the matrix, causing adaptable thioester bonds to rearrange, leading to degradation. To verify this, we inhibited cytoskeletal tension using blebbistatin, a myosin-II inhibitor. Blebbistatin-treated cells can degrade these networks only by secreting enzymes including esterases. Esterases hydrolyze thioester bonds, which generate free thiols, leading to bond exchange. Around treated cells, we measure a decrease in the extent of pericellular degradation. We also compare cell area, eccentricity, and speed of untreated and treated cells. Inhibiting cytoskeletal tension results in significantly smaller cell area, more rounded cells, and lower cell speeds when compared to untreated cells. Overall, this work shows that cytoskeletal tension plays a major role in hMSC-mediated degradation of thioester networks. Cytoskeletal tension is also important for the spreading and motility of hMSCs in these networks. This work informs the design of thioester scaffolds for tissue regeneration and cell delivery.

Published

2024