Your search keyword '"Khademhosseini, Ali"' showing total 26 results

1. Interpenetrating network gelatin methacryloyl (GelMA) and pectin-g-PCL hydrogels with tunable properties for tissue engineering.

Author

Fares MM, Shirzaei Sani E, Portillo Lara R, Oliveira RB, Khademhosseini A, and Annabi N

Subjects

Biocompatible Materials chemistry, Cell Line, Cell Proliferation, Cross-Linking Reagents chemistry, Humans, Hydrogels chemical synthesis, Materials Testing, Molecular Weight, Photochemical Processes, Polymerization, Surface Properties, Tissue Scaffolds chemistry, Gelatin chemistry, Hydrogels chemistry, Pectins chemistry, Polyesters chemistry, Polymethacrylic Acids chemistry, Tissue Engineering methods

Abstract

The design of new hydrogel-based biomaterials with tunable physical and biological properties is essential for the advancement of applications related to tissue engineering and regenerative medicine. For instance, interpenetrating polymer network (IPN) and semi-IPN hydrogels have been widely explored to engineer functional tissues due to their characteristic microstructural and mechanical properties. Here, we engineered IPN and semi-IPN hydrogels comprised of a tough pectin grafted polycaprolactone (pectin-g-PCL) component to provide mechanical stability, and a highly cytocompatible gelatin methacryloyl (GelMA) component to support cellular growth and proliferation. IPN hydrogels were formed by calcium ion (Ca2+)-crosslinking of pectin-g-PCL chains, followed by photocrosslinking of the GelMA precursor. Conversely, semi-IPN networks were formed by photocrosslinking of the pectin-g-PCL and GelMA mixture, in the absence of Ca2+ crosslinking. IPN and semi-IPN hydrogels synthesized with varying ratios of pectin-g-PCL to GelMA, with and without Ca2+-crosslinking, exhibited a broad range of mechanical properties. For semi-IPN hydrogels, the aggregation of microcrystalline cores led to formation of hydrogels with compressive moduli ranging from 3.1 to 10.4 kPa. For IPN hydrogels, the mechanistic optimization of pectin-g-PCL, GelMA, and Ca2+ concentrations resulted in hydrogels with comparatively higher compressive modulus, in the range of 39 kPa-5029 kPa. Our results also showed that IPN hydrogels were cytocompatible in vitro and could support the growth of three-dimensionally (3D) encapsulated MC3T3-E1 preosteoblasts in vitro. The simplicity, technical feasibility, low cost, tunable mechanical properties, and cytocompatibility of the engineered semi-IPN and IPN hydrogels highlight their potential for different tissue engineering and biomedical applications.

Published

2018

2. Coaxial extrusion bioprinting of 3D microfibrous constructs with cell-favorable gelatin methacryloyl microenvironments.

Author

Liu W, Zhong Z, Hu N, Zhou Y, Maggio L, Miri AK, Fragasso A, Jin X, Khademhosseini A, and Zhang YS

Subjects

Alginates chemistry, Cells, Cultured, Human Umbilical Vein Endothelial Cells, Humans, Hydrogels chemistry, Methacrylates chemistry, Bioprinting methods, Cellular Microenvironment physiology, Gelatin chemistry, Printing, Three-Dimensional, Tissue Engineering methods, Tissue Scaffolds chemistry

Abstract

Bioinks with shear-thinning/rapid solidification properties and strong mechanics are usually needed for the bioprinting of three-dimensional (3D) cell-laden constructs. As such, it remains challenging to generate soft constructs from bioinks at low concentrations that are favorable for cellular activities. Herein, we report a strategy to fabricate cell-laden constructs with tunable 3D microenvironments achieved by bioprinting of gelatin methacryloyl (GelMA)/alginate core/sheath microfibers, where the alginate sheath serves as a template to support and confine the GelMA pre-hydrogel in the core during the extrusion process, allowing for subsequent UV crosslinking. This novel strategy minimizes the bioprinting requirements for the core bioink, and facilitates the fabrication of cell-laden GelMA constructs at low concentrations. We first showed the capability of generating various alginate hollow microfibrous constructs using a coaxial nozzle setup, and verified the diffusibility and perfusability of the bioprinted hollow structures that are important for the tissue engineering applications. More importantly, the hollow alginate microfibers were then used as templates for generating cell-laden GelMA constructs with soft microenvironments, by using GelMA pre-hydrogel as the bioink for the core phase during bioprinting. As such, GelMA constructs at extremely low concentrations (<2.0%) could be extruded to effectively support cellular activities including proliferation and spreading for various cell types. We believe that our strategy is likely to provide broad opportunities in bioprinting of 3D constructs with cell-favorable microenvironments for applications in tissue engineering and pharmaceutical screening.

Published

2018

3. Photocrosslinkable Gelatin Hydrogel for Epidermal Tissue Engineering.

Author

Zhao X, Lang Q, Yildirimer L, Lin ZY, Cui W, Annabi N, Ng KW, Dokmeci MR, Ghaemmaghami AM, and Khademhosseini A

Subjects

Acrylamides pharmacology, Animals, Cell Adhesion drug effects, Cell Adhesion radiation effects, Cell Proliferation drug effects, Cell Proliferation radiation effects, Cell Survival drug effects, Cell Survival radiation effects, Compressive Strength, Elastic Modulus, Electric Impedance, Humans, Keratinocytes cytology, Keratinocytes drug effects, Keratinocytes radiation effects, Sus scrofa, Tissue Scaffolds chemistry, Cross-Linking Reagents pharmacology, Epidermal Cells, Gelatin pharmacology, Hydrogel, Polyethylene Glycol Dimethacrylate pharmacology, Light, Tissue Engineering methods

Abstract

Natural hydrogels are promising scaffolds to engineer epidermis. Currently, natural hydrogels used to support epidermal regeneration are mainly collagen- or gelatin-based, which mimic the natural dermal extracellular matrix but often suffer from insufficient and uncontrollable mechanical and degradation properties. In this study, a photocrosslinkable gelatin (i.e., gelatin methacrylamide (GelMA)) with tunable mechanical, degradation, and biological properties is used to engineer the epidermis for skin tissue engineering applications. The results reveal that the mechanical and degradation properties of the developed hydrogels can be readily modified by varying the hydrogel concentration, with elastic and compressive moduli tuned from a few kPa to a few hundred kPa, and the degradation times varied from a few days to several months. Additionally, hydrogels of all concentrations displayed excellent cell viability (>90%) with increasing cell adhesion and proliferation corresponding to increases in hydrogel concentrations. Furthermore, the hydrogels are found to support keratinocyte growth, differentiation, and stratification into a reconstructed multilayered epidermis with adequate barrier functions. The robust and tunable properties of GelMA hydrogels suggest that the keratinocyte laden hydrogels can be used as epidermal substitutes, wound dressings, or substrates to construct various in vitro skin models., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2016

4. Tough and flexible CNT-polymeric hybrid scaffolds for engineering cardiac constructs.

Author

Kharaziha M, Shin SR, Nikkhah M, Topkaya SN, Masoumi N, Annabi N, Dokmeci MR, and Khademhosseini A

Subjects

Animals, Biocompatible Materials chemistry, Cells, Cultured, Electric Conductivity, Glycerol chemistry, Myocardium cytology, Nanofibers chemistry, Nanofibers ultrastructure, Rats, Sprague-Dawley, Decanoates chemistry, Gelatin chemistry, Glycerol analogs & derivatives, Myocytes, Cardiac cytology, Nanotubes, Carbon chemistry, Polymers chemistry, Tissue Engineering methods, Tissue Scaffolds chemistry

Abstract

In the past few years, a considerable amount of effort has been devoted toward the development of biomimetic scaffolds for cardiac tissue engineering. However, most of the previous scaffolds have been electrically insulating or lacked the structural and mechanical robustness to engineer cardiac tissue constructs with suitable electrophysiological functions. Here, we developed tough and flexible hybrid scaffolds with enhanced electrical properties composed of carbon nanotubes (CNTs) embedded aligned poly(glycerol sebacate):gelatin (PG) electrospun nanofibers. Incorporation of varying concentrations of CNTs from 0 to 1.5% within the PG nanofibrous scaffolds (CNT-PG scaffolds) notably enhanced fiber alignment and improved the electrical conductivity and toughness of the scaffolds while maintaining the viability, retention, alignment, and contractile activities of cardiomyocytes (CMs) seeded on the scaffolds. The resulting CNT-PG scaffolds resulted in stronger spontaneous and synchronous beating behavior (3.5-fold lower excitation threshold and 2.8-fold higher maximum capture rate) compared to those cultured on PG scaffold. Overall, our findings demonstrated that aligned CNT-PG scaffold exhibited superior mechanical properties with enhanced CM beating properties. It is envisioned that the proposed hybrid scaffolds can be useful for generating cardiac tissue constructs with improved organization and maturation., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

5. Direct-write bioprinting of cell-laden methacrylated gelatin hydrogels.

Author

Bertassoni LE, Cardoso JC, Manoharan V, Cristino AL, Bhise NS, Araujo WA, Zorlutuna P, Vrana NE, Ghaemmaghami AM, Dokmeci MR, and Khademhosseini A

Subjects

Animals, Biocompatible Materials toxicity, Cell Survival drug effects, Elastic Modulus, Hep G2 Cells, Humans, Hydrogels toxicity, Mice, NIH 3T3 Cells, Tissue Scaffolds, Biocompatible Materials chemistry, Bioprinting methods, Gelatin chemistry, Hydrogels chemistry, Methacrylates chemistry, Tissue Engineering methods

Abstract

Fabrication of three dimensional (3D) organoids with controlled microarchitectures has been shown to enhance tissue functionality. Bioprinting can be used to precisely position cells and cell-laden materials to generate controlled tissue architecture. Therefore, it represents an exciting alternative for organ fabrication. Despite the rapid progress in the field, the development of printing processes that can be used to fabricate macroscale tissue constructs from ECM-derived hydrogels has remained a challenge. Here we report a strategy for bioprinting of photolabile cell-laden methacrylated gelatin (GelMA) hydrogels. We bioprinted cell-laden GelMA at concentrations ranging from 7 to 15% with varying cell densities and found a direct correlation between printability and the hydrogel mechanical properties. Furthermore, encapsulated HepG2 cells preserved cell viability for at least eight days following the bioprinting process. In summary, this work presents a strategy for direct-write bioprinting of a cell-laden photolabile ECM-derived hydrogel, which may find widespread application for tissue engineering, organ printing and the development of 3D drug discovery platforms.

Published

2014

6. Microfluidics-assisted fabrication of gelatin-silica core-shell microgels for injectable tissue constructs.

Author

Cha C, Oh J, Kim K, Qiu Y, Joh M, Shin SR, Wang X, Camci-Unal G, Wan KT, Liao R, and Khademhosseini A

Subjects

Animals, Gelatin administration & dosage, Gels, Injections, Mice, Mice, Inbred C57BL, Silicon Dioxide administration & dosage, Gelatin chemistry, Microfluidic Analytical Techniques methods, Silicon Dioxide chemistry, Tissue Engineering methods

Abstract

Microfabrication technology provides a highly versatile platform for engineering hydrogels used in biomedical applications with high-resolution control and injectability. Herein, we present a strategy of microfluidics-assisted fabrication photo-cross-linkable gelatin microgels, coupled with providing protective silica hydrogel layer on the microgel surface to ultimately generate gelatin-silica core-shell microgels for applications as in vitro cell culture platform and injectable tissue constructs. A microfluidic device having flow-focusing channel geometry was utilized to generate droplets containing methacrylated gelatin (GelMA), followed by a photo-cross-linking step to synthesize GelMA microgels. The size of the microgels could easily be controlled by varying the ratio of flow rates of aqueous and oil phases. Then, the GelMA microgels were used as in vitro cell culture platform to grow cardiac side population cells on the microgel surface. The cells readily adhered on the microgel surface and proliferated over time while maintaining high viability (∼90%). The cells on the microgels were also able to migrate to their surrounding area. In addition, the microgels eventually degraded over time. These results demonstrate that cell-seeded GelMA microgels have a great potential as injectable tissue constructs. Furthermore, we demonstrated that coating the cells on GelMA microgels with biocompatible and biodegradable silica hydrogels via sol-gel method provided significant protection against oxidative stress which is often encountered during and after injection into host tissues, and detrimental to the cells. Overall, the microfluidic approach to generate cell-adhesive microgel core, coupled with silica hydrogels as a protective shell, will be highly useful as a cell culture platform to generate a wide range of injectable tissue constructs.

Published

2014

7. Transdermal regulation of vascular network bioengineering using a photopolymerizable methacrylated gelatin hydrogel.

Author

Lin RZ, Chen YC, Moreno-Luna R, Khademhosseini A, and Melero-Martin JM

Subjects

Animals, Cell Proliferation, Cell Survival physiology, Cells, Cultured, Humans, Mice, Mice, Nude, Bioengineering, Gelatin chemistry, Hydrogel, Polyethylene Glycol Dimethacrylate chemistry, Methacrylates chemistry, Tissue Engineering methods

Abstract

The search for hydrogel materials compatible with vascular morphogenesis is an active area of investigation in tissue engineering. One candidate material is methacrylated gelatin (GelMA), a UV-photocrosslinkable hydrogel that is synthesized by adding methacrylate groups to the amine-containing side-groups of gelatin. GelMA hydrogels containing human endothelial colony-forming cells (ECFCs) and mesenchymal stem cells (MSCs) can be photopolymerized ex vivo and then surgically transplanted in vivo as a means to generate vascular networks. However, the full clinical potential of GelMA will be best captured by enabling minimally invasive implantation and in situ polymerization. In this study, we demonstrated the feasibility of bioengineering human vascular networks inside GelMA constructs that were first subcutaneously injected into immunodeficient mice while in liquid form, and then rapidly crosslinked via transdermal exposure to UV light. These bioengineered vascular networks developed within 7 days, formed functional anastomoses with the host vasculature, and were uniformly distributed throughout the constructs. Most notably, we demonstrated that the vascularization process can be directly modulated by adjusting the initial exposure time to UV light (15-45 s range), with constructs displaying progressively less vascular density and smaller average lumen size as the degree of GelMA crosslinking was increased. Our studies support the use of GelMA in its injectable form, followed by in situ transdermal photopolymerization, as a preferable means to deliver cells in applications that require the formation of vascular networks in vivo., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2013

8. Template‐Enabled Biofabrication of Thick 3D Tissues with Patterned Perfusable Macrochannels

Author

Davoodi, Elham, Montazerian, Hossein, Zhianmanesh, Masoud, Abbasgholizadeh, Reza, Haghniaz, Reihaneh, Baidya, Avijit, Pourmohammadali, Homeyra, Annabi, Nasim, Weiss, Paul S, Toyserkani, Ehsan, and Khademhosseini, Ali

Subjects

Engineering, Biomedical Engineering, Bioengineering, Regenerative Medicine, Bioprinting, Gelatin, Hydrogels, Methacrylates, Plastics, Printing, Three-Dimensional, Tissue Engineering, Tissue Scaffolds, 3D bioprinting, additive manufacturing, biofabrication, cell-laden hydrogels, gelatin methacryloyl, Medicinal and Biomolecular Chemistry, Medical Biotechnology, Medical biotechnology, Biomedical engineering

Abstract

Interconnected pathways in 3D bioartificial organs are essential to retaining cell activity in thick functional 3D tissues. 3D bioprinting methods have been widely explored in biofabrication of functionally patterned tissues; however, these methods are costly and confined to thin tissue layers due to poor control of low-viscosity bioinks. Here, cell-laden hydrogels that could be precisely patterned via water-soluble gelatin templates are constructed by economical extrusion 3D printed plastic templates. Tortuous co-continuous plastic networks, designed based on triply periodic minimal surfaces (TPMS), serve as a sacrificial pattern to shape the secondary sacrificial gelatin templates. These templates are eventually used to form cell-encapsulated gelatin methacryloyl (GelMA) hydrogel scaffolds patterned with the complex interconnected pathways. The proposed fabrication process is compatible with photo-crosslinkable hydrogels wherein prepolymer casting enables incorporation of high cell populations with high viability. The cell-laden hydrogel constructs are characterized by robust mechanical behavior. In vivo studies demonstrate a superior cell ingrowth into the highly permeable constructs compared to the bulk hydrogels. Perfusable complex interconnected networks within cell-encapsulated hydrogels may assist in engineering thick and functional tissue constructs through the permeable internal channels for efficient cellular activities in vivo.

Published

2022

9. Synthesis, properties, and biomedical applications of gelatin methacryloyl (GelMA) hydrogels

Author

Yue, Kan, Santiago, Grissel Trujillo-de, Alvarez, Mario Moisés, Tamayol, Ali, Annabi, Nasim, and Khademhosseini, Ali

Subjects

Biotechnology, Bioengineering, Regenerative Medicine, Generic health relevance, Amino Acid Motifs, Animals, Biocompatible Materials, Cell Proliferation, Extracellular Matrix, Gelatin, Graphite, Humans, Hydrogels, Methacrylates, Mice, Microfluidics, Nanotubes, Carbon, Oxides, Polymers, Tissue Engineering, Tissue Scaffolds, GelMA, Hydrogel, Tissue engineering, Biomedical, Methacryloyl

Abstract

Gelatin methacryloyl (GelMA) hydrogels have been widely used for various biomedical applications due to their suitable biological properties and tunable physical characteristics. GelMA hydrogels closely resemble some essential properties of native extracellular matrix (ECM) due to the presence of cell-attaching and matrix metalloproteinase responsive peptide motifs, which allow cells to proliferate and spread in GelMA-based scaffolds. GelMA is also versatile from a processing perspective. It crosslinks when exposed to light irradiation to form hydrogels with tunable mechanical properties. It can also be microfabricated using different methodologies including micromolding, photomasking, bioprinting, self-assembly, and microfluidic techniques to generate constructs with controlled architectures. Hybrid hydrogel systems can also be formed by mixing GelMA with nanoparticles such as carbon nanotubes and graphene oxide, and other polymers to form networks with desired combined properties and characteristics for specific biological applications. Recent research has demonstrated the proficiency of GelMA-based hydrogels in a wide range of tissue engineering applications including engineering of bone, cartilage, cardiac, and vascular tissues, among others. Other applications of GelMA hydrogels, besides tissue engineering, include fundamental cell research, cell signaling, drug and gene delivery, and bio-sensing.

Published

2015

10. Hybrid hydrogels containing vertically aligned carbon nanotubes with anisotropic electrical conductivity for muscle myofiber fabrication.

Author

Ahadian, Samad, Ramón-Azcón, Javier, Estili, Mehdi, Liang, Xiaobin, Ostrovidov, Serge, Shiku, Hitoshi, Ramalingam, Murugan, Nakajima, Ken, Sakka, Yoshio, Bae, Hojae, Matsue, Tomokazu, and Khademhosseini, Ali

Subjects

Myoblasts, Animals, Mice, Nanotubes, Carbon, Muscle Proteins, Gelatin, Hydrogels, Electrophoresis, Cell Culture Techniques, Tissue Engineering, Electric Stimulation, Cell Differentiation, Cell Survival, Gene Expression, Electric Conductivity, Anisotropy, Tissue Scaffolds, Muscle Fibers, Skeletal, Nanotubes, Carbon, Muscle Fibers, Skeletal

Abstract

Biological scaffolds with tunable electrical and mechanical properties are of great interest in many different fields, such as regenerative medicine, biorobotics, and biosensing. In this study, dielectrophoresis (DEP) was used to vertically align carbon nanotubes (CNTs) within methacrylated gelatin (GelMA) hydrogels in a robust, simple, and rapid manner. GelMA-aligned CNT hydrogels showed anisotropic electrical conductivity and superior mechanical properties compared with pristine GelMA hydrogels and GelMA hydrogels containing randomly distributed CNTs. Skeletal muscle cells grown on vertically aligned CNTs in GelMA hydrogels yielded a higher number of functional myofibers than cells that were cultured on hydrogels with randomly distributed CNTs and horizontally aligned CNTs, as confirmed by the expression of myogenic genes and proteins. In addition, the myogenic gene and protein expression increased more profoundly after applying electrical stimulation along the direction of the aligned CNTs due to the anisotropic conductivity of the hybrid GelMA-vertically aligned CNT hydrogels. We believe that platform could attract great attention in other biomedical applications, such as biosensing, bioelectronics, and creating functional biomedical devices.

Published

2014

11. PGS:Gelatin nanofibrous scaffolds with tunable mechanical and structural properties for engineering cardiac tissues.

Author

Kharaziha, Mahshid, Nikkhah, Mehdi, Shin, Su-Ryon, Annabi, Nasim, Masoumi, Nafiseh, Gaharwar, Akhilesh K, Camci-Unal, Gulden, and Khademhosseini, Ali

Subjects

Myocardium, Cells, Cultured, Fibroblasts, Myocytes, Cardiac, Animals, Rats, Rats, Sprague-Dawley, Glycerol, Polymers, Decanoates, Gelatin, Tissue Engineering, Cell Adhesion, Cell Proliferation, Tissue Scaffolds, Nanofibers, Scaffold, Nanofibrous, poly(glycerol sebacate):gelatin, Cardiac cells, Tissue engineering, Cells, Cultured, Myocytes, Cardiac, Sprague-Dawley, Biomedical Engineering

Abstract

A significant challenge in cardiac tissue engineering is the development of biomimetic grafts that can potentially promote myocardial repair and regeneration. A number of approaches have used engineered scaffolds to mimic the architecture of the native myocardium tissue and precisely regulate cardiac cell functions. However, previous attempts have not been able to simultaneously recapitulate chemical, mechanical, and structural properties of the myocardial extracellular matrix (ECM). In this study, we utilized an electrospinning approach to fabricate elastomeric biodegradable poly(glycerol sebacate) (PGS):gelatin nanofibrous scaffolds with a wide range of chemical composition, stiffness and anisotropy. Our findings demonstrated that through incorporation of PGS, it is possible to create nanofibrous scaffolds with well-defined anisotropy that mimic the left ventricular myocardium architecture. Furthermore, we studied attachment, proliferation, differentiation and alignment of neonatal rat cardiac fibroblast cells (CFs) as well as protein expression, alignment, and contractile function of cardiomyocyte (CMs) on PGS:gelatin scaffolds with variable amount of PGS. Notably, aligned nanofibrous scaffold, consisting of 33 wt. % PGS, induced optimal synchronous contractions of CMs while significantly enhanced cellular alignment. Overall, our study suggests that the aligned nanofibrous PGS:gelatin scaffold support cardiac cell organization, phenotype and contraction and could potentially be used to develop clinically relevant constructs for cardiac tissue engineering.

Published

2013

12. Interpenetrating network gelatin methacryloyl (GelMA) and pectin-g-PCL hydrogels with tunable properties for tissue engineering

Author

Fares, Mohammad M, Shirzaei Sani, Ehsan, Portillo Lara, Roberto, Oliveira, Rhayza B, Khademhosseini, Ali, and Annabi, Nasim

Subjects

Tissue Engineering, Tissue Scaffolds, Surface Properties, Polyesters, Medical Biotechnology, Biocompatible Materials, Hydrogels, Bioengineering, Photochemical Processes, Regenerative Medicine, Cell Line, Polymerization, Molecular Weight, Medicinal and Biomolecular Chemistry, Cross-Linking Reagents, Polymethacrylic Acids, Materials Testing, Humans, Pectins, Gelatin, Biochemistry and Cell Biology, Cell Proliferation

Abstract

The design of new hydrogel-based biomaterials with tunable physical and biological properties is essential for the advancement of applications related to tissue engineering and regenerative medicine. For instance, interpenetrating polymer network (IPN) and semi-IPN hydrogels have been widely explored to engineer functional tissues due to their characteristic microstructural and mechanical properties. Here, we engineered IPN and semi-IPN hydrogels comprised of a tough pectin grafted polycaprolactone (pectin-g-PCL) component to provide mechanical stability, and a highly cytocompatible gelatin methacryloyl (GelMA) component to support cellular growth and proliferation. IPN hydrogels were formed by calcium ion (Ca2+)-crosslinking of pectin-g-PCL chains, followed by photocrosslinking of the GelMA precursor. Conversely, semi-IPN networks were formed by photocrosslinking of the pectin-g-PCL and GelMA mixture, in the absence of Ca2+ crosslinking. IPN and semi-IPN hydrogels synthesized with varying ratios of pectin-g-PCL to GelMA, with and without Ca2+-crosslinking, exhibited a broad range of mechanical properties. For semi-IPN hydrogels, the aggregation of microcrystalline cores led to formation of hydrogels with compressive moduli ranging from 3.1 to 10.4 kPa. For IPN hydrogels, the mechanistic optimization of pectin-g-PCL, GelMA, and Ca2+ concentrations resulted in hydrogels with comparatively higher compressive modulus, in the range of 39 kPa-5029 kPa. Our results also showed that IPN hydrogels were cytocompatible in vitro and could support the growth of three-dimensionally (3D) encapsulated MC3T3-E1 preosteoblasts in vitro. The simplicity, technical feasibility, low cost, tunable mechanical properties, and cytocompatibility of the engineered semi-IPN and IPN hydrogels highlight their potential for different tissue engineering and biomedical applications.

Published

2018

13. In situ forming microporous gelatin methacryloyl hydrogel scaffolds from thermostable microgels for tissue engineering.

Author

Zoratto, Nicole, Di Lisa, Donatella, Rutte, Joseph, Sakib, Md Nurus, Alves e Silva, Angelo Roncalli, Tamayol, Ali, Di Carlo, Dino, Khademhosseini, Ali, and Sheikhi, Amir

Subjects

HYDROGELS, MICROGELS, TISSUE engineering, MELTING points, GELATIN, THERMAL instability

Abstract

Converting biopolymers to extracellular matrix (ECM)‐mimetic hydrogel‐based scaffolds has provided invaluable opportunities to design in vitro models of tissues/diseases and develop regenerative therapies for damaged tissues. Among biopolymers, gelatin and its crosslinkable derivatives, such as gelatin methacryloyl (GelMA), have gained significant importance for biomedical applications due to their ECM‐mimetic properties. Recently, we have developed the first class of in situ forming GelMA microporous hydrogels based on the chemical annealing of physically crosslinked GelMA microscale beads (microgels), which addressed several key shortcomings of bulk (nanoporous) GelMA scaffolds, including lack of interconnected micron‐sized pores to support on‐demand three‐dimensional‐cell seeding and cell–cell interactions. Here, we address one of the limitations of in situ forming microporous GelMA hydrogels, that is, the thermal instability (melting) of their physically crosslinked building blocks at physiological temperature, resulting in compromised microporosity. To overcome this challenge, we developed a two‐step fabrication strategy in which thermostable GelMA microbeads were produced via semi‐photocrosslinking, followed by photo‐annealing to form stable microporous scaffolds. We show that the semi‐photocrosslinking step (exposure time up to 90 s at an intensity of ~100 mW/cm2 and a wavelength of ~365 nm) increases the thermostability of GelMA microgels while decreasing their scaffold forming (annealing) capability. Hinging on the tradeoff between microgel and scaffold stabilities, we identify the optimal crosslinking condition (exposure time ~60 s) that enables the formation of stable annealed microgel scaffolds. This work is a step forward in engineering in situ forming microporous hydrogels made up from thermostable GelMA microgels for in vitro and in vivo applications at physiological temperature well above the gelatin melting point. [ABSTRACT FROM AUTHOR]

Published

2020

14. Photocrosslinkable Gelatin Hydrogel for Epidermal Tissue Engineering

Author

Zhao, Xin, Lang, Qi, Yildirimer, Lara, Lin, Zhi Yuan, Cui, Wenguo, Annabi, Nasim, Ng, Kee Woei, Dokmeci, Mehmet R, Ghaemmaghami, Amir M, and Khademhosseini, Ali

Subjects

keratinocytes, Compressive Strength, Light, Cell Survival, Sus scrofa, Medical Biotechnology, Biomedical Engineering, photocrosslinkable gelatin, Bioengineering, macromolecular substances, mechanical properties, Regenerative Medicine, complex mixtures, Medicinal and Biomolecular Chemistry, Elastic Modulus, epidermis, Cell Adhesion, Electric Impedance, Animals, Humans, Cell Proliferation, degradation, Skin, Acrylamides, integumentary system, Tissue Engineering, Tissue Scaffolds, technology, industry, and agriculture, Hydrogel, Cross-Linking Reagents, Polyethylene Glycol Dimethacrylate, Epidermal Cells, Gelatin, Biotechnology

Abstract

Natural hydrogels are promising scaffolds to engineer epidermis. Currently, natural hydrogels used to support epidermal regeneration are mainly collagen- or gelatin-based, which mimic the natural dermal extracellular matrix but often suffer from insufficient and uncontrollable mechanical and degradation properties. In this study, a photocrosslinkable gelatin (i.e., gelatin methacrylamide (GelMA)) with tunable mechanical, degradation, and biological properties is used to engineer the epidermis for skin tissue engineering applications. The results reveal that the mechanical and degradation properties of the developed hydrogels can be readily modified by varying the hydrogel concentration, with elastic and compressive moduli tuned from a few kPa to a few hundred kPa, and the degradation times varied from a few days to several months. Additionally, hydrogels of all concentrations displayed excellent cell viability (>90%) with increasing cell adhesion and proliferation corresponding to increases in hydrogel concentrations. Furthermore, the hydrogels are found to support keratinocyte growth, differentiation, and stratification into a reconstructed multilayered epidermis with adequate barrier functions. The robust and tunable properties of GelMA hydrogels suggest that the keratinocyte laden hydrogels can be used as epidermal substitutes, wound dressings, or substrates to construct various in vitro skin models.

Published

2016

15. Gelatin‐polysaccharide composite scaffolds for 3D cell culture and tissue engineering: Towards natural therapeutics.

Author

Afewerki, Samson, Sheikhi, Amir, Kannan, Soundarapandian, Ahadian, Samad, and Khademhosseini, Ali

Subjects

GELATIN, POLYSACCHARIDES, CELL culture, TISSUE engineering, EXTRACELLULAR matrix

Abstract

Gelatin is a promising material as scaffold with therapeutic and regenerative characteristics due to its chemical similarities to the extracellular matrix (ECM) in the native tissues, biocompatibility, biodegradability, low antigenicity, cost‐effectiveness, abundance, and accessible functional groups that allow facile chemical modifications with other biomaterials or biomolecules. Despite the advantages of gelatin, poor mechanical properties, sensitivity to enzymatic degradation, high viscosity, and reduced solubility in concentrated aqueous media have limited its applications and encouraged the development of gelatin‐based composite hydrogels. The drawbacks of gelatin may be surmounted by synergistically combining it with a wide range of polysaccharides. The addition of polysaccharides to gelatin is advantageous in mimicking the ECM, which largely contains proteoglycans or glycoproteins. Moreover, gelatin–polysaccharide biomaterials benefit from mechanical resilience, high stability, low thermal expansion, improved hydrophilicity, biocompatibility, antimicrobial and anti‐inflammatory properties, and wound healing potential. Here, we discuss how combining gelatin and polysaccharides provides a promising approach for developing superior therapeutic biomaterials. We review gelatin–polysaccharides scaffolds and their applications in cell culture and tissue engineering, providing an outlook for the future of this family of biomaterials as advanced natural therapeutics. [ABSTRACT FROM AUTHOR]

Published

2019

16. Synthesis and characterization of photocrosslinkable gelatin and silk fibroin interpenetrating polymer network hydrogels.

Author

Xiao, Wenqian, He, Jiankang, Nichol, Jason W., Wang, Lianyong, Hutson, Ché B., Wang, Ben, Du, Yanan, Fan, Hongsong, and Khademhosseini, Ali

Subjects

COLLOIDS in medicine, POLYMER networks, GELATIN, SILK, METHYL methacrylate, CROSSLINKING (Polymerization), TISSUE engineering, REGENERATIVE medicine

Abstract

Abstract: To effectively repair or replace damaged tissues, it is necessary to design scaffolds with tunable structural and biomechanical properties that closely mimic the host tissue. In this paper, we describe a newly synthesized photocrosslinkable interpenetrating polymer network (IPN) hydrogel based on gelatin methacrylate (GelMA) and silk fibroin (SF) formed by sequential polymerization, which possesses tunable structural and biological properties. Experimental results revealed that IPNs, where both the GelMA and SF were independently crosslinked in interpenetrating networks, demonstrated a lower swelling ratio, higher compressive modulus and lower degradation rate as compared to the GelMA and semi-IPN hydrogels, where only GelMA was crosslinked. These differences were likely caused by a higher degree of overall crosslinking due to the presence of crystallized SF in the IPN hydrogels. NIH-3T3 fibroblasts readily attached to, spread and proliferated on the surface of IPN hydrogels, as demonstrated by F-actin staining and analysis of mitochondrial activity (MTT). In addition, photolithography combined with lyophilization techniques was used to fabricate three-dimensional micropatterned and porous microscaffolds from GelMA–SF IPN hydrogels, furthering their versatility for use in various microscale tissue engineering applications. Overall, this study introduces a class of photocrosslinkable, mechanically robust and tunable IPN hydrogels that could be useful for various tissue engineering and regenerative medicine applications. [Copyright &y& Elsevier]

Published

2011

17. Tissue Engineering: Gold Nanocomposite Bioink for Printing 3D Cardiac Constructs (Adv. Funct. Mater. 12/2017).

Author

Zhu, Kai, Shin, Su Ryon, van Kempen, Tim, Li, Yi‐Chen, Ponraj, Vidhya, Nasajpour, Amir, Mandla, Serena, Hu, Ning, Liu, Xiao, Leijten, Jeroen, Lin, Yi‐Dong, Hussain, Mohammad Asif, Zhang, Yu Shrike, Tamayol, Ali, and Khademhosseini, Ali

Subjects

TISSUE engineering

Abstract

A novel conductive bioink containing dispersed gold nanoparticles in a photocrosslinkable hydrogel matrix is developed for microfluidic bioprinting of cardiomyocyteladen microfibrous scaffolds. As described by Su Ryon Shin, Ali Khademhosseini, and co‐workers in article number 1605352, increased conductivity of the bioink leads to improved functionality of cardiomyocytes in the bioprinted patches, enabling potential applications in cardiac tissue engineering. [ABSTRACT FROM AUTHOR]

Published

2017

18. The mechanical properties and cytotoxicity of cell-laden double-network hydrogels based on photocrosslinkable gelatin and gellan gum biomacromolecules

Author

Shin, Hyeongho, Olsen, Bradley D., and Khademhosseini, Ali

Subjects

*HYDROGELS, *CELL-mediated cytotoxicity, *GELATIN, *GELLAN gum, *TISSUE engineering, *CARTILAGE, *MECHANICAL behavior of materials

Abstract

Abstract: A major goal in the application of hydrogels for tissue engineering scaffolds, especially for load-bearing tissues such as cartilage, is to develop hydrogels with high mechanical strength. In this study, a double-network (DN) strategy was used to engineer strong hydrogels that can encapsulate cells. We improved upon previously studied double-network (DN) hydrogels by using a processing condition compatible with cell survival. The DN hydrogels were created by a two-step photocrosslinking using gellan gum methacrylate (GGMA) for the rigid and brittle first network, and gelatin methacrylamide (GelMA) for the soft and ductile second network. We controlled the degree of methacrylation of each polymer so that they obtain relevant mechanical properties as each network. The DN was formed by photocrosslinking the GGMA, diffusing GelMA into the first network, and photocrosslinking the GelMA to form the second network. The formation of the DN was examined by diffusion tests of the large GelMA molecules into the GGMA network, the resulting enhancement in the mechanical properties, and the difference in mechanical properties between GGMA/GelMA single networks (SN) and DNs. The resulting DN hydrogels exhibited the compressive failure stress of up to 6.9 MPa, which approaches the strength of cartilage. It was found that there is an optimal range of the crosslink density of the second network for high strength of DN hydrogels. DN hydrogels with a higher mass ratio of GelMA to GGMA exhibited higher strength, which shows promise in developing even stronger DN hydrogels in the future. Three dimensional (3D) encapsulation of NIH-3T3 fibroblasts and the following viability test showed the cell-compatibility of the DN formation process. Given the high strength and the ability to encapsulate cells, the DN hydrogels made from photocrosslinkable macromolecules could be useful for the regeneration of load-bearing tissues. [Copyright &y& Elsevier]

Published

2012

19. Structural analysis of photocrosslinkable methacryloyl-modified protein derivatives.

Author

Yue, Kan, Li, Xiuyu, Schrobback, Karsten, Sheikhi, Amir, Annabi, Nasim, Leijten, Jeroen, Zhang, Weijia, Zhang, Yu Shrike, Hutmacher, Dietmar W., Klein, Travis J., and Khademhosseini, Ali

Subjects

*PHOTOCROSSLINKING, *BIOMATERIALS, *GELATIN, *REGENERATIVE medicine, *HYDROGELS in medicine, *TISSUE engineering

Abstract

Biochemically modified proteins have attracted significant attention due to their widespread applications as biomaterials. For instance, chemically modified gelatin derivatives have been widely explored to develop hydrogels for tissue engineering and regenerative medicine applications. Among the reported methods, modification of gelatin with methacrylic anhydride (MA) stands out as a convenient and efficient strategy to introduce functional groups and form hydrogels via photopolymerization. Combining light-activation of modified gelatin with soft lithography has enabled the materialization of microfabricated hydrogels. So far, this gelatin derivative has been referred to in the literature as gelatin methacrylate, gelatin methacrylamide, or gelatin methacryloyl, with the same abbreviation of GelMA. Considering the complex composition of gelatin and the presence of different functional groups on the amino acid residues, both hydroxyl groups and amine groups can possibly react with methacrylic anhydride during functionalization of the protein. This can also apply to the modification of other proteins, such as recombinant human tropoelastin to form MA-modified tropoelastin (MeTro). Here, we employed analytical methods to quantitatively determine the amounts of methacrylate and methacrylamide groups in MA-modified gelatin and tropoelastin to better understand the reaction mechanism. By combining two chemical assays with instrumental techniques, such as proton nuclear magnetic resonance ( 1 H NMR) and liquid chromatography tandem-mass spectrometry (LC-MS/MS), our results indicated that while amine groups had higher reactivity than hydroxyl groups and resulted in a majority of methacrylamide groups, modification of proteins by MA could lead to the formation of both methacrylamide and methacrylate groups. It is therefore suggested that the standard terms for GelMA and MeTro should be defined as gelatin methacryloyl and methacryloyl-substituted tropoelastin, respectively, to remain consistent with the widespread abbreviations used in literature. [ABSTRACT FROM AUTHOR]

Published

2017

20. Myotube formation on gelatin nanofibers – Multi-walled carbon nanotubes hybrid scaffolds.

Author

Ostrovidov, Serge, Shi, Xuetao, Zhang, Ling, Liang, Xiaobin, Kim, Sang Bok, Fujie, Toshinori, Ramalingam, Murugan, Chen, Mingwei, Nakajima, Ken, Al-Hazmi, Faten, Bae, Hojae, Memic, Adnan, and Khademhosseini, Ali

Subjects

*GELATIN, *NANOFIBERS, *MULTIWALLED carbon nanotubes, *TISSUE scaffolds, *TISSUE engineering, *MYOBLASTS

Abstract

Abstract: Engineering functional muscle tissue requires the formation of densely packed, aligned, and mature myotubes. To enhance the formation of aligned myotubes with improved contractibility, we fabricated aligned electrospun gelatin multi-walled carbon nanotubes (MWNTs) hybrid fibers that were used as scaffolds for the growth of myoblasts (C2C12). The MWNTs significantly enhanced myotube formation by improving the mechanical properties of the resulting fibers and upregulated the activation of mechanotransduction related genes. In addition, the fibers enhanced the maturation of the myotubes and the amplitude of the myotube contractions under electrical stimulation (ES). Such hybrid material scaffolds may be useful to direct skeletal muscle cellular organization, improve cellular functionality and tissue formation. [Copyright &y& Elsevier]

Published

2014

21. Synthesis and Characterization of Hybrid HyaluronicAcid-Gelatin Hydrogels.

Author

Camci-Unal, Gulden, Cuttica, Davide, Annabi, Nasim, Demarchi, Danilo, and Khademhosseini, Ali

Subjects

*HYALURONIC acid, *GELATIN, *COLLOID synthesis, *BIOMIMETIC materials, *TISSUE engineering, *REGENERATIVE medicine, *BIODEGRADATION, *POLYMERS

Abstract

Biomimetic hybrid hydrogels havegenerated broad interest in tissueengineering and regenerative medicine. Hyaluronic acid (HA) and gelatin(hydrolyzed collagen) are naturally derived polymers and biodegradableunder physiological conditions. Moreover, collagen and HA are majorcomponents of the extracellular matrix (ECM) in most of the tissues(e.g., cardiovascular, cartilage, neural). When used as a hybrid material,HA-gelatin hydrogels may enable mimicking the ECM of native tissues.Although HA-gelatin hybrid hydrogels are promising biomimetic substrates,their material properties have not been thoroughly characterized inthe literature. Herein, we generated hybrid hydrogels with tunablephysical and biological properties by using different concentrationsof HA and gelatin. The physical properties of the fabricated hydrogelsincluding swelling ratio, degradation, and mechanical properties wereinvestigated. In addition, in vitro cellular responses in both twoand three-dimensional culture conditions were assessed. It was foundthat the addition of gelatin methacrylate (GelMA) into HA methacrylate(HAMA) promoted cell spreading in the hybrid hydogels. Moreover, thehybrid hydrogels showed significantly improved mechanical propertiescompared to their single component analogs. The HAMA-GelMA hydrogelsexhibited remarkable tunability behavior and may be useful for cardiovasculartissue engineering applications. [ABSTRACT FROM AUTHOR]

Published

2013

22. SAM-based cell transfer to photopatterned hydrogels for microengineering vascular-like structures

Author

Sadr, Nasser, Zhu, Mojun, Osaki, Tatsuya, Kakegawa, Takahiro, Yang, Yunzhi, Moretti, Matteo, Fukuda, Junji, and Khademhosseini, Ali

Subjects

*TISSUE engineering, *HYDROGELS, *MOLECULAR self-assembly, *MONOMOLECULAR films, *GELATIN, *METHYL methacrylate, *OLIGOPEPTIDES, *ELECTRIC batteries

Abstract

Abstract: A major challenge in tissue engineering is to reproduce the native 3D microvascular architecture fundamental for in vivo functions. Current approaches still lack a network of perfusable vessels with native 3D structural organization. Here we present a new method combining self-assembled monolayer (SAM)-based cell transfer and gelatin methacrylate hydrogel photopatterning techniques for microengineering vascular structures. Human umbilical vein cell (HUVEC) transfer from oligopeptide SAM-coated surfaces to the hydrogel revealed two SAM desorption mechanisms: photoinduced and electrochemically triggered. The former, occurs concomitantly to hydrogel photocrosslinking, and resulted in efficient (>97%) monolayer transfer. The latter, prompted by additional potential application, preserved cell morphology and maintained high transfer efficiency of VE-cadherin positive monolayers over longer culture periods. This approach was also applied to transfer HUVECs to 3D geometrically defined vascular-like structures in hydrogels, which were then maintained in perfusion culture for 15 days. As a step toward more complex constructs, a cell-laden hydrogel layer was photopatterned around the endothelialized channel to mimic the vascular smooth muscle structure of distal arterioles. This study shows that the coupling of the SAM-based cell transfer and hydrogel photocrosslinking could potentially open up new avenues in engineering more complex, vascularized tissue constructs for regenerative medicine and tissue engineering applications. [Copyright &y& Elsevier]

Published

2011

23. Cell-laden microengineered gelatin methacrylate hydrogels

Author

Nichol, Jason W., Koshy, Sandeep T., Bae, Hojae, Hwang, Chang M., Yamanlar, Seda, and Khademhosseini, Ali

Subjects

*TISSUE engineering, *GELATIN, *METHYL methacrylate, *MICROFLUIDIC devices, *HYDRATION, *PHOTOPOLYMERIZATION, *COLLOIDS in medicine

Abstract

Abstract: The cellular microenvironment plays an integral role in improving the function of microengineered tissues. Control of the microarchitecture in engineered tissues can be achieved through photopatterning of cell-laden hydrogels. However, despite high pattern fidelity of photopolymerizable hydrogels, many such materials are not cell-responsive and have limited biodegradability. Here, we demonstrate gelatin methacrylate (GelMA) as an inexpensive, cell-responsive hydrogel platform for creating cell-laden microtissues and microfluidic devices. Cells readily bound to, proliferated, elongated, and migrated both when seeded on micropatterned GelMA substrates as well as when encapsulated in microfabricated GelMA hydrogels. The hydration and mechanical properties of GelMA were demonstrated to be tunable for various applications through modification of the methacrylation degree and gel concentration. The pattern fidelity and resolution of GelMA were high and it could be patterned to create perfusable microfluidic channels. Furthermore, GelMA micropatterns could be used to create cellular micropatterns for in vitro cell studies or 3D microtissue fabrication. These data suggest that GelMA hydrogels could be useful for creating complex, cell-responsive microtissues, such as endothelialized microvasculature, or for other applications that require cell-responsive microengineered hydrogels. [Copyright &y& Elsevier]

Published

2010

24. Hybrid hydrogels containing vertically aligned carbon nanotubes with anisotropic electrical conductivity for muscle myofiber fabrication

Author

Javier Ramón-Azcón, Ken Nakajima, Hojae Bae, Yoshio Sakka, Mehdi Estili, Murugan Ramalingam, Hitoshi Shiku, Tomokazu Matsue, Samad Ahadian, Ali Khademhosseini, Serge Ostrovidov, Xiaobin Liang, Harvard University--MIT Division of Health Sciences and Technology, and Khademhosseini, Ali

Subjects

Electrophoresis, Materials science, Fabrication, food.ingredient, Cell Survival, Muscle Fibers, Skeletal, Cell Culture Techniques, Muscle Proteins, Gene Expression, Bioengineering, Nanotechnology, Carbon nanotube, Regenerative Medicine, Muscle Fibers, Gelatin, Article, law.invention, Myoblasts, Mice, food, Tissue engineering, law, Animals, Bioelectronics, Nanotubes, Multidisciplinary, Tissue Engineering, Tissue Scaffolds, Nanotubes, Carbon, Electric Conductivity, Hydrogels, Cell Differentiation, Skeletal, Dielectrophoresis, Carbon, Electric Stimulation, Self-healing hydrogels, Anisotropy, Biosensor

Abstract

Biological scaffolds with tunable electrical and mechanical properties are of great interest in many different fields, such as regenerative medicine, biorobotics, and biosensing. In this study, dielectrophoresis (DEP) was used to vertically align carbon nanotubes (CNTs) within methacrylated gelatin (GelMA) hydrogels in a robust, simple, and rapid manner. GelMA-aligned CNT hydrogels showed anisotropic electrical conductivity and superior mechanical properties compared with pristine GelMA hydrogels and GelMA hydrogels containing randomly distributed CNTs. Skeletal muscle cells grown on vertically aligned CNTs in GelMA hydrogels yielded a higher number of functional myofibers than cells that were cultured on hydrogels with randomly distributed CNTs and horizontally aligned CNTs, as confirmed by the expression of myogenic genes and proteins. In addition, the myogenic gene and protein expression increased more profoundly after applying electrical stimulation along the direction of the aligned CNTs due to the anisotropic conductivity of the hybrid GelMA-vertically aligned CNT hydrogels. We believe that platform could attract great attention in other biomedical applications, such as biosensing, bioelectronics, and creating functional biomedical devices.

Published

2014

25. Carbon-nanotube-embedded hydrogel sheets for engineering cardiac constructs and bioactuators

Author

Su Ryon Shin, Mehdi Nikkhah, Masoud Khabiry, Jing Kong, Kai-Tak Wan, Ali Khademhosseini, Keekyoung Kim, Hojae Bae, Momen Zalabany, Xiaowu Tang, Tomas Palacios, Mohamed Azize, Sang Bok Kim, Sung Mi Jung, Pinar Zorlutuna, Mehmet R. Dokmeci, Harvard University--MIT Division of Health Sciences and Technology, Massachusetts Institute of Technology. Research Laboratory of Electronics, Shin, Su Ryon, Jung, Sung Mi, Zalabany, Momen, Kim, Keekyoung, Zorlutuna, Pinar, Kim, Sang bok, Nikkhah, Mehdi, Azize, Mohamed, Kong, Jing, Palacios, Tomas, Dokmeci, Mehmet, and Khademhosseini, Ali

Subjects

food.ingredient, Materials science, General Physics and Astronomy, Nanotechnology, Carbon nanotube, Gelatin, Article, law.invention, food, Tissue engineering, law, Biomimetic Materials, Myocyte, Animals, General Materials Science, Myocytes, Cardiac, Neonatal rat, Tissue Engineering, Tissue Scaffolds, Nanotubes, Carbon, Myocardium, General Engineering, Hydrogels, Adhesion, Extracellular Matrix, Rats, Coupling (electronics), Self-healing hydrogels, Biomedical engineering

Abstract

We engineered functional cardiac patches by seeding neonatal rat cardiomyocytes onto carbon nanotube (CNT)-incorporated photo-cross-linkable gelatin methacrylate (GelMA) hydrogels. The resulting cardiac constructs showed excellent mechanical integrity and advanced electrophysiological functions. Specifically, myocardial tissues cultured on 50 μm thick CNT-GelMA showed 3 times higher spontaneous synchronous beating rates and 85% lower excitation threshold, compared to those cultured on pristine GelMA hydrogels. Our results indicate that the electrically conductive and nanofibrous networks formed by CNTs within a porous gelatin framework are the key characteristics of CNT-GelMA leading to improved cardiac cell adhesion, organization, and cell–cell coupling. Centimeter-scale patches were released from glass substrates to form 3D biohybrid actuators, which showed controllable linear cyclic contraction/extension, pumping, and swimming actuations. In addition, we demonstrate for the first time that cardiac tissues cultured on CNT-GelMA resist damage by a model cardiac inhibitor as well as a cytotoxic compound. Therefore, incorporation of CNTs into gelatin, and potentially other biomaterials, could be useful in creating multifunctional cardiac scaffolds for both therapeutic purposes and in vitro studies. These hybrid materials could also be used for neuron and other muscle cells to create tissue constructs with improved organization, electroactivity, and mechanical integrity., United States. Army Research Office. Institute for Soldier Nanotechnologies, National Institutes of Health (U.S.) (HL092836), National Institutes of Health (U.S.) (EB02597), National Institutes of Health (U.S.) (AR057837), National Institutes of Health (U.S.) (HL099073), National Science Foundation (U.S.) (DMR0847287), United States. Office of Naval Research (ONR PECASE Award), United States. Office of Naval Research (Young Investigator award), National Research Foundation of Korea (grant (NRF-2010-220-D00014))

Published

2013

26. The mechanical properties and cytotoxicity of cell-laden double-network hydrogels based on photocrosslinkable gelatin and gellan gum biomacromolecules

Author

Hyeongho Shin, Bradley D. Olsen, Ali Khademhosseini, Harvard University--MIT Division of Health Sciences and Technology, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Shin, Hyeongho, Olsen, Bradley D., and Khademhosseini, Ali

Subjects

Materials science, food.ingredient, Compressive Strength, Light, Cell Survival, Macromolecular Substances, Biophysics, Bioengineering, Biocompatible Materials, Methacrylate, Gelatin, Article, Biomaterials, chemistry.chemical_compound, Mice, food, Tissue engineering, Hardness, Elastic Modulus, Materials Testing, Methacrylamide, Animals, Composite material, Cell encapsulation, Tissue Scaffolds, Polysaccharides, Bacterial, Hydrogels, Gellan gum, Compressive strength, Cross-Linking Reagents, chemistry, Chemical engineering, Mechanics of Materials, Self-healing hydrogels, Ceramics and Composites, NIH 3T3 Cells

Abstract

A major goal in the application of hydrogels for tissue engineering scaffolds, especially for load-bearing tissues such as cartilage, is to develop hydrogels with high mechanical strength. In this study, a double-network (DN) strategy was used to engineer strong hydrogels that can encapsulate cells. We improved upon previously studied double-network (DN) hydrogels by using a processing condition compatible with cell survival. The DN hydrogels were created by a two-step photocrosslinking using gellan gum methacrylate (GGMA) for the rigid and brittle first network, and gelatin methacrylamide (GelMA) for the soft and ductile second network. We controlled the degree of methacrylation of each polymer so that they obtain relevant mechanical properties as each network. The DN was formed by photocrosslinking the GGMA, diffusing GelMA into the first network, and photocrosslinking the GelMA to form the second network. The formation of the DN was examined by diffusion tests of the large GelMA molecules into the GGMA network, the resulting enhancement in the mechanical properties, and the difference in mechanical properties between GGMA/GelMA single networks (SN) and DNs. The resulting DN hydrogels exhibited the compressive failure stress of up to 6.9 MPa, which approaches the strength of cartilage. It was found that there is an optimal range of the crosslink density of the second network for high strength of DN hydrogels. DN hydrogels with a higher mass ratio of GelMA to GGMA exhibited higher strength, which shows promise in developing even stronger DN hydrogels in the future. Three dimensional (3D) encapsulation of NIH-3T3 fibroblasts and the following viability test showed the cell-compatibility of the DN formation process. Given the high strength and the ability to encapsulate cells, the DN hydrogels made from photocrosslinkable macromolecules could be useful for the regeneration of load-bearing tissues., Samsung Scholarship Foundation, National Institutes of Health (U.S.) (HL092836), National Institutes of Health (U.S.) (EB02597), National Institutes of Health (U.S.) (AR057837), National Science Foundation (U.S.) (CAREER Award DMR0847287), United States. Office of Naval Research (Young Investigator Award)

Published

2012