Your search keyword '"Weiss, Anthony S."' showing total 17 results

1. Human‐Recombinant‐Elastin‐Based Bioinks for 3D Bioprinting of Vascularized Soft Tissues

Author

Lee, Sohyung, Sani, Ehsan Shirzaei, Spencer, Andrew R, Guan, Yvonne, Weiss, Anthony S, and Annabi, Nasim

Subjects

Engineering, Biomedical Engineering, Bioengineering, Heart Disease, Cardiovascular, Regenerative Medicine, Biotechnology, Animals, Bioprinting, Elasticity, Elastin, Humans, Myocardium, Printing, Three-Dimensional, Rats, Recombinant Proteins, bioprinting, cardiac tissue, elastic bioinks, elasticity, GelMA, MeTro, vascularized tissue, Physical Sciences, Chemical Sciences, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences

Abstract

Bioprinting has emerged as an advanced method for fabricating complex 3D tissues. Despite the tremendous potential of 3D bioprinting, there are several drawbacks of current bioinks and printing methodologies that limit  the ability to print elastic and highly vascularized tissues. In particular, fabrication of complex biomimetic structure that are entirely based on 3D bioprinting is still challenging primarily due to the lack of suitable bioinks with high printability, biocompatibility, biomimicry, and proper mechanical properties. To address these shortcomings, in this work the use of recombinant human tropoelastin as a highly biocompatible and elastic bioink for 3D printing of complex soft tissues is demonstrated. As proof of the concept, vascularized cardiac constructs are bioprinted and their functions are assessed in vitro and in vivo. The printed constructs demonstrate endothelium barrier function and spontaneous beating of cardiac muscle cells, which are important functions of cardiac tissue in vivo. Furthermore, the printed construct elicits minimal inflammatory responses, and is shown to be efficiently biodegraded in vivo when implanted subcutaneously in rats. Taken together, these results demonstrate the potential of the elastic bioink for printing 3D functional cardiac tissues, which can eventually be used for cardiac tissue replacement.

Published

2020

2. Photocrosslinkable Gelatin/Tropoelastin Hydrogel Adhesives for Peripheral Nerve Repair

Author

Soucy, Jonathan R, Sani, Ehsan Shirzaei, Lara, Roberto Portillo, Diaz, David, Dias, Felipe, Weiss, Anthony S, Koppes, Abigail N, Koppes, Ryan A, and Annabi, Nasim

Subjects

Regenerative Medicine, Bioengineering, Neurosciences, Development of treatments and therapeutic interventions, 5.2 Cellular and gene therapies, Adhesives, Animals, Female, Gelatin, Hydrogels, Male, Nerve Regeneration, Rats, Rats, Sprague-Dawley, Rats, Wistar, Sciatic Nerve, Tropoelastin, nerve anastomosis, nerve repair, Schwann cells, GelMA, MeTro, Biochemistry and Cell Biology, Biomedical Engineering, Materials Engineering

Abstract

Suturing peripheral nerve transections is the predominant therapeutic strategy for nerve repair. However, the use of sutures leads to scar tissue formation, hinders nerve regeneration, and prevents functional recovery. Fibrin-based adhesives have been widely used for nerve reconstruction, but their limited adhesive and mechanical strength and inability to promote nerve regeneration hamper their utility as a stand-alone intervention. To overcome these challenges, we engineered composite hydrogels that are neurosupportive and possess strong tissue adhesion. These composites were synthesized by photocrosslinking two naturally derived polymers, gelatin-methacryloyl (GelMA) and methacryloyl-substituted tropoelastin (MeTro). The engineered materials exhibited tunable mechanical properties by varying the GelMA/MeTro ratio. In addition, GelMA/MeTro hydrogels exhibited 15-fold higher adhesive strength to nerve tissue ex vivo compared to fibrin control. Furthermore, the composites were shown to support Schwann cell (SC) viability and proliferation, as well as neurite extension and glial cell participation in vitro, which are essential cellular components for nerve regeneration. Finally, subcutaneously implanted GelMA/MeTro hydrogels exhibited slower degradation in vivo compared with pure GelMA, indicating its potential to support the growth of slowly regenerating nerves. Thus, GelMA/MeTro composites may be used as clinically relevant biomaterials to regenerate nerves and reduce the need for microsurgical suturing during nerve reconstruction.

Published

2018

3. Photocrosslinkable Gelatin/Tropoelastin Hydrogel Adhesives for Peripheral Nerve Repair.

Author

Soucy, Jonathan R, Shirzaei Sani, Ehsan, Portillo Lara, Roberto, Diaz, David, Dias, Felipe, Weiss, Anthony S, Koppes, Abigail N, Koppes, Ryan A, and Annabi, Nasim

Subjects

Sciatic Nerve, Animals, Rats, Rats, Sprague-Dawley, Rats, Wistar, Tropoelastin, Gelatin, Hydrogels, Adhesives, Nerve Regeneration, Female, Male, GelMA, MeTro, Schwann cells, nerve anastomosis, nerve repair, Biomedical Engineering, Biochemistry and Cell Biology, Materials Engineering

Abstract

Suturing peripheral nerve transections is the predominant therapeutic strategy for nerve repair. However, the use of sutures leads to scar tissue formation, hinders nerve regeneration, and prevents functional recovery. Fibrin-based adhesives have been widely used for nerve reconstruction, but their limited adhesive and mechanical strength and inability to promote nerve regeneration hamper their utility as a stand-alone intervention. To overcome these challenges, we engineered composite hydrogels that are neurosupportive and possess strong tissue adhesion. These composites were synthesized by photocrosslinking two naturally derived polymers, gelatin-methacryloyl (GelMA) and methacryloyl-substituted tropoelastin (MeTro). The engineered materials exhibited tunable mechanical properties by varying the GelMA/MeTro ratio. In addition, GelMA/MeTro hydrogels exhibited 15-fold higher adhesive strength to nerve tissue ex vivo compared to fibrin control. Furthermore, the composites were shown to support Schwann cell (SC) viability and proliferation, as well as neurite extension and glial cell participation in vitro, which are essential cellular components for nerve regeneration. Finally, subcutaneously implanted GelMA/MeTro hydrogels exhibited slower degradation in vivo compared with pure GelMA, indicating its potential to support the growth of slowly regenerating nerves. Thus, GelMA/MeTro composites may be used as clinically relevant biomaterials to regenerate nerves and reduce the need for microsurgical suturing during nerve reconstruction.

Published

2018

4. Engineering a highly elastic human protein–based sealant for surgical applications

Author

Annabi, Nasim, Zhang, Yi-Nan, Assmann, Alexander, Sani, Ehsan Shirzaei, Cheng, George, Lassaletta, Antonio D, Vegh, Andrea, Dehghani, Bijan, Ruiz-Esparza, Guillermo U, Wang, Xichi, Gangadharan, Sidhu, Weiss, Anthony S, and Khademhosseini, Ali

Subjects

Lung, Bioengineering, Adhesives, Animals, Biocompatible Materials, Elasticity, Humans, Male, Models, Animal, Pressure, Protein Engineering, Rats, Wistar, Subcutaneous Tissue, Sus scrofa, Tropoelastin, Wound Healing, Biological Sciences, Medical and Health Sciences

Abstract

Surgical sealants have been used for sealing or reconnecting ruptured tissues but often have low adhesion, inappropriate mechanical strength, cytotoxicity concerns, and poor performance in biological environments. To address these challenges, we engineered a biocompatible and highly elastic hydrogel sealant with tunable adhesion properties by photocrosslinking the recombinant human protein tropoelastin. The subcutaneous implantation of the methacryloyl-substituted tropoelastin (MeTro) sealant in rodents demonstrated low toxicity and controlled degradation. All animals survived surgical procedures with adequate blood circulation by using MeTro in an incisional model of artery sealing in rats, and animals showed normal breathing and lung function in a model of surgically induced rat lung leakage. In vivo experiments in a porcine model demonstrated complete sealing of severely leaking lung tissue in the absence of sutures or staples, with no clinical or sonographic signs of pneumothorax during 14 days of follow-up. The engineered MeTro sealant has high potential for clinical applications because of superior adhesion and mechanical properties compared to commercially available sealants, as well as opportunity for further optimization of the degradation rate to fit desired surgical applications on different tissues.

Published

2017

5. Engineering a highly elastic human protein-based sealant for surgical applications.

Author

Annabi, Nasim, Zhang, Yi-Nan, Assmann, Alexander, Sani, Ehsan Shirzaei, Cheng, George, Lassaletta, Antonio D, Vegh, Andrea, Dehghani, Bijan, Ruiz-Esparza, Guillermo U, Wang, Xichi, Gangadharan, Sidhu, Weiss, Anthony S, and Khademhosseini, Ali

Subjects

Lung, Subcutaneous Tissue, Animals, Sus scrofa, Humans, Rats, Wistar, Tropoelastin, Biocompatible Materials, Adhesives, Protein Engineering, Models, Animal, Wound Healing, Elasticity, Pressure, Male, Bioengineering, Biological Sciences, Medical and Health Sciences

Abstract

Surgical sealants have been used for sealing or reconnecting ruptured tissues but often have low adhesion, inappropriate mechanical strength, cytotoxicity concerns, and poor performance in biological environments. To address these challenges, we engineered a biocompatible and highly elastic hydrogel sealant with tunable adhesion properties by photocrosslinking the recombinant human protein tropoelastin. The subcutaneous implantation of the methacryloyl-substituted tropoelastin (MeTro) sealant in rodents demonstrated low toxicity and controlled degradation. All animals survived surgical procedures with adequate blood circulation by using MeTro in an incisional model of artery sealing in rats, and animals showed normal breathing and lung function in a model of surgically induced rat lung leakage. In vivo experiments in a porcine model demonstrated complete sealing of severely leaking lung tissue in the absence of sutures or staples, with no clinical or sonographic signs of pneumothorax during 14 days of follow-up. The engineered MeTro sealant has high potential for clinical applications because of superior adhesion and mechanical properties compared to commercially available sealants, as well as opportunity for further optimization of the degradation rate to fit desired surgical applications on different tissues.

Published

2017

6. Engineering a sprayable and elastic hydrogel adhesive with antimicrobial properties for wound healing

Author

Annabi, Nasim, Rana, Devyesh, Sani, Ehsan Shirzaei, Portillo-Lara, Roberto, Gifford, Jessie L, Fares, Mohammad M, Mithieux, Suzanne M, and Weiss, Anthony S

Subjects

Biotechnology, Bioengineering, 3T3 Cells, Adhesives, Aerosols, Animals, Anti-Infective Agents, Antimicrobial Cationic Peptides, Biocompatible Materials, Cross-Linking Reagents, Elasticity, Gelatin, Hydrogel, Polyethylene Glycol Dimethacrylate, Male, Materials Testing, Methacrylates, Mice, Microbial Viability, Rats, Rats, Wistar, Time Factors, Tissue Engineering, Tropoelastin, Wound Healing, Wound healing, MeTro, GelMA, Antimicrobial hydrogels, Tissue adhesive

Abstract

Hydrogel-based bioadhesives have emerged as alternatives for sutureless wound closure, since they can mimic the composition and physicochemical properties of the extracellular matrix. However, they are often associated with poor mechanical properties, low adhesion to native tissues, and lack of antimicrobial properties. Herein, a new sprayable, elastic, and biocompatible composite hydrogel, with broad-spectrum antimicrobial activity, for the treatment of chronic wounds is reported. The composite hydrogels were engineered using two ECM-derived biopolymers, gelatin methacryloyl (GelMA) and methacryloyl-substituted recombinant human tropoelastin (MeTro). MeTro/GelMA composite hydrogel adhesives were formed via visible light-induced crosslinking. Additionally, the antimicrobial peptide Tet213 was conjugated to the hydrogels, instilling antimicrobial activity against Gram (+) and (-) bacteria. The physical properties (e.g. porosity, degradability, swellability, mechanical, and adhesive properties) of the engineered hydrogel could be fine-tuned by varying the ratio of MeTro/GelMA and the final polymer concentration. The hydrogels supported in vitro mammalian cellular growth in both two-dimensional and three dimensional cultures. The subcutaneous implantation of the hydrogels in rats confirmed their biocompatibility and biodegradation in vivo. The engineered MeTro/GelMA-Tet213 hydrogels can be used for sutureless wound closure strategies to prevent infection and promote healing of chronic wounds.

Published

2017

7. Engineering a sprayable and elastic hydrogel adhesive with antimicrobial properties for wound healing.

Author

Annabi, Nasim, Rana, Devyesh, Shirzaei Sani, Ehsan, Portillo-Lara, Roberto, Gifford, Jessie L, Fares, Mohammad M, Mithieux, Suzanne M, and Weiss, Anthony S

Subjects

3T3 Cells, Animals, Mice, Rats, Rats, Wistar, Methacrylates, Antimicrobial Cationic Peptides, Tropoelastin, Gelatin, Biocompatible Materials, Aerosols, Anti-Infective Agents, Adhesives, Cross-Linking Reagents, Tissue Engineering, Materials Testing, Wound Healing, Elasticity, Time Factors, Male, Microbial Viability, Hydrogel, Polyethylene Glycol Dimethacrylate, Antimicrobial hydrogels, GelMA, MeTro, Tissue adhesive, Wound healing, Biomedical Engineering

Abstract

Hydrogel-based bioadhesives have emerged as alternatives for sutureless wound closure, since they can mimic the composition and physicochemical properties of the extracellular matrix. However, they are often associated with poor mechanical properties, low adhesion to native tissues, and lack of antimicrobial properties. Herein, a new sprayable, elastic, and biocompatible composite hydrogel, with broad-spectrum antimicrobial activity, for the treatment of chronic wounds is reported. The composite hydrogels were engineered using two ECM-derived biopolymers, gelatin methacryloyl (GelMA) and methacryloyl-substituted recombinant human tropoelastin (MeTro). MeTro/GelMA composite hydrogel adhesives were formed via visible light-induced crosslinking. Additionally, the antimicrobial peptide Tet213 was conjugated to the hydrogels, instilling antimicrobial activity against Gram (+) and (-) bacteria. The physical properties (e.g. porosity, degradability, swellability, mechanical, and adhesive properties) of the engineered hydrogel could be fine-tuned by varying the ratio of MeTro/GelMA and the final polymer concentration. The hydrogels supported in vitro mammalian cellular growth in both two-dimensional and three dimensional cultures. The subcutaneous implantation of the hydrogels in rats confirmed their biocompatibility and biodegradation in vivo. The engineered MeTro/GelMA-Tet213 hydrogels can be used for sutureless wound closure strategies to prevent infection and promote healing of chronic wounds.

Published

2017

8. Highly Elastic and Conductive Human‐Based Protein Hybrid Hydrogels

Author

Annabi, Nasim, Shin, Su Ryon, Tamayol, Ali, Miscuglio, Mario, Bakooshli, Mohsen Afshar, Assmann, Alexander, Mostafalu, Pooria, Sun, Jeong-Yun, Mithieux, Suzanne, Cheung, Louis, Tang, Xiaowu Shirley, Weiss, Anthony S, and Khademhosseini, Ali

Subjects

Engineering, Materials Engineering, Biomedical Engineering, Bioengineering, Biotechnology, Elasticity, Electric Conductivity, Graphite, Humans, Hydrogels, Models, Molecular, Molecular Conformation, Oxides, Tensile Strength, Tropoelastin, cardiac tissue engineering, elasticity, graphene oxides, hydrogels, tropoelastins, Physical Sciences, Chemical Sciences, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences

Abstract

A highly elastic hybrid hydrogel of methacryloyl-substituted recombinant human tropoelastin (MeTro) and graphene oxide (GO) nanoparticles are developed. The synergistic effect of these two materials significantly enhances both ultimate strain (250%), reversible rotation (9700°), and the fracture energy (38.8 ± 0.8 J m(-2) ) in the hybrid network. Furthermore, improved electrical signal propagation and subsequent contraction of the muscles connected by hybrid hydrogels are observed in ex vivo tests.

Published

2016

9. Highly Elastic and Conductive Human-Based Protein Hybrid Hydrogels.

Author

Annabi, Nasim, Shin, Su Ryon, Tamayol, Ali, Miscuglio, Mario, Bakooshli, Mohsen Afshar, Assmann, Alexander, Mostafalu, Pooria, Sun, Jeong-Yun, Mithieux, Suzanne, Cheung, Louis, Tang, Xiaowu Shirley, Weiss, Anthony S, and Khademhosseini, Ali

Subjects

Humans, Oxides, Graphite, Tropoelastin, Hydrogels, Molecular Conformation, Electric Conductivity, Elasticity, Tensile Strength, Models, Molecular, Engineering, cardiac tissue engineering, elasticity, graphene oxides, hydrogels, tropoelastins, Models, Molecular, Bioengineering, Biotechnology, Nanoscience & Nanotechnology, Physical Sciences, Chemical Sciences

Abstract

A highly elastic hybrid hydrogel of methacryloyl-substituted recombinant human tropoelastin (MeTro) and graphene oxide (GO) nanoparticles are developed. The synergistic effect of these two materials significantly enhances both ultimate strain (250%), reversible rotation (9700°), and the fracture energy (38.8 ± 0.8 J m(-2) ) in the hybrid network. Furthermore, improved electrical signal propagation and subsequent contraction of the muscles connected by hybrid hydrogels are observed in ex vivo tests.

Published

2016

10. Highly Elastic Micropatterned Hydrogel for Engineering Functional Cardiac Tissue

Author

Annabi, Nasim, Tsang, Kelly, Mithieux, Suzanne M, Nikkhah, Mehdi, Ameri, Afshin, Khademhosseini, Ali, and Weiss, Anthony S

Subjects

Biotechnology, Regenerative Medicine, Bioengineering, Cardiovascular, Heart Disease, tropoelastin, microfabrication, cardiomyocyte, cell alignment, elasticity, Physical Sciences, Chemical Sciences, Engineering, Materials

Abstract

Heart failure is a major international health issue. Myocardial mass loss and lack of contractility are precursors to heart failure. Surgical demand for effective myocardial repair is tempered by a paucity of appropriate biological materials. These materials should conveniently replicate natural human tissue components, convey persistent elasticity, promote cell attachment, growth and conformability to direct cell orientation and functional performance. Here, microfabrication techniques are applied to recombinant human tropoelastin, the resilience-imparting protein found in all elastic human tissues, to generate photocrosslinked biological materials containing well-defined micropatterns. These highly elastic substrates are then used to engineer biomimetic cardiac tissue constructs. The micropatterned hydrogels, produced through photocrosslinking of methacrylated tropoelastin (MeTro), promote the attachment, spreading, alignment, function, and intercellular communication of cardiomyocytes by providing an elastic mechanical support that mimics their dynamic mechanical properties in vivo. The fabricated MeTro hydrogels also support the synchronous beating of cardiomyocytes in response to electrical field stimulation. These novel engineered micropatterned elastic gels are designed to be amenable to 3D modular assembly and establish a versatile, adaptable foundation for the modeling and regeneration of functional cardiac tissue with potential for application to other elastic tissues.

Published

2013

11. Highly Elastic Micropatterned Hydrogel for Engineering Functional Cardiac Tissue.

Author

Annabi, Nasim, Tsang, Kelly, Mithieux, Suzanne M, Nikkhah, Mehdi, Ameri, Afshin, Khademhosseini, Ali, and Weiss, Anthony S

Subjects

tropoelastin, microfabrication, cardiomyocyte, cell alignment, elasticity, Biotechnology, Heart Disease, Bioengineering, Regenerative Medicine, Cardiovascular, Chemical Sciences, Engineering, Physical Sciences, Materials

Abstract

Heart failure is a major international health issue. Myocardial mass loss and lack of contractility are precursors to heart failure. Surgical demand for effective myocardial repair is tempered by a paucity of appropriate biological materials. These materials should conveniently replicate natural human tissue components, convey persistent elasticity, promote cell attachment, growth and conformability to direct cell orientation and functional performance. Here, microfabrication techniques are applied to recombinant human tropoelastin, the resilience-imparting protein found in all elastic human tissues, to generate photocrosslinked biological materials containing well-defined micropatterns. These highly elastic substrates are then used to engineer biomimetic cardiac tissue constructs. The micropatterned hydrogels, produced through photocrosslinking of methacrylated tropoelastin (MeTro), promote the attachment, spreading, alignment, function, and intercellular communication of cardiomyocytes by providing an elastic mechanical support that mimics their dynamic mechanical properties in vivo. The fabricated MeTro hydrogels also support the synchronous beating of cardiomyocytes in response to electrical field stimulation. These novel engineered micropatterned elastic gels are designed to be amenable to 3D modular assembly and establish a versatile, adaptable foundation for the modeling and regeneration of functional cardiac tissue with potential for application to other elastic tissues.

Published

2013

12. Hydrogel-coated microfluidic channels for cardiomyocyte culture.

Author

Annabi, Nasim, Selimović, Šeila, Acevedo Cox, Juan Pablo, Ribas, João, Afshar Bakooshli, Mohsen, Heintze, Déborah, Weiss, Anthony S, Cropek, Donald, and Khademhosseini, Ali

Subjects

Cells, Cultured, Myocytes, Cardiac, Animals, Rats, Rats, Sprague-Dawley, Hydrogel, Dimethylpolysiloxanes, Troponin I, Tropoelastin, Gelatin, Microscopy, Confocal, Microfluidic Analytical Techniques, Cell Adhesion, Elasticity, Hydrogel, Polyethylene Glycol Dimethacrylate, Cells, Cultured, Myocytes, Cardiac, Sprague-Dawley, Microscopy, Confocal, Polyethylene Glycol Dimethacrylate, Bioengineering, Regenerative Medicine, Biotechnology, Analytical Chemistry, Chemical Sciences, Engineering

Abstract

The research areas of tissue engineering and drug development have displayed increased interest in organ-on-a-chip studies, in which physiologically or pathologically relevant tissues can be engineered to test pharmaceutical candidates. Microfluidic technologies enable the control of the cellular microenvironment for these applications through the topography, size, and elastic properties of the microscale cell culture environment, while delivering nutrients and chemical cues to the cells through continuous media perfusion. Traditional materials used in the fabrication of microfluidic devices, such as poly(dimethylsiloxane) (PDMS), offer high fidelity and high feature resolution, but do not facilitate cell attachment. To overcome this challenge, we have developed a method for coating microfluidic channels inside a closed PDMS device with a cell-compatible hydrogel layer. We have synthesized photocrosslinkable gelatin and tropoelastin-based hydrogel solutions that were used to coat the surfaces under continuous flow inside 50 μm wide, straight microfluidic channels to generate a hydrogel layer on the channel walls. Our observation of primary cardiomyocytes seeded on these hydrogel layers showed preferred attachment as well as higher spontaneous beating rates on tropoelastin coatings compared to gelatin. In addition, cellular attachment, alignment and beating were stronger on 5% (w/v) than on 10% (w/v) hydrogel-coated channels. Our results demonstrate that cardiomyocytes respond favorably to the elastic, soft tropoelastin culture substrates, indicating that tropoelastin-based hydrogels may be a suitable coating choice for some organ-on-a-chip applications. We anticipate that the proposed hydrogel coating method and tropoelastin as a cell culture substrate may be useful for the generation of elastic tissues, e.g. blood vessels, using microfluidic approaches.

Published

2013

13. Elastomeric recombinant protein-based biomaterials

Author

Annabi, Nasim, Mithieux, Suzanne M, Camci-Unal, Gulden, Dokmeci, Mehmet R, Weiss, Anthony S, and Khademhosseini, Ali

Subjects

Engineering, Biomedical Engineering, Regenerative Medicine, Biotechnology, Bioengineering, Elastomer, Tropoelastin, Elastin-like polypeptides, Biomaterials, Elasticity, Biochemistry and Cell Biology, Chemical Engineering, Industrial Biotechnology, Industrial biotechnology, Chemical engineering

Abstract

Elastomeric protein-based biomaterials, produced from elastin derivatives, are widely investigated as promising tissue engineering scaffolds due to their remarkable properties including substantial extensibility, long-term stability, self-assembly, high resilience upon stretching, low energy loss, and excellent biological activity. These elastomers are processed from different sources of soluble elastin such as animal-derived soluble elastin, recombinant human tropoelastin, and elastin-like polypeptides into various forms including three dimensional (3D) porous hydrogels, elastomeric films, and fibrous electrospun scaffolds. Elastin-based biomaterials have shown great potential for the engineering of elastic tissues such as skin, lung and vasculature. In this review, the synthesis and properties of various elastin-based elastomers with their applications in tissue engineering are described.

Published

2013

14. Elastomeric Recombinant Protein-based Biomaterials.

Author

Annabi, Nasim, Mithieux, Suzanne M, Camci-Unal, Gulden, Dokmeci, Mehmet R, Weiss, Anthony S, and Khademhosseini, Ali

Subjects

Elastomer, Tropoelastin, Elastin-like polypeptides, Biomaterials, Elasticity, Regenerative Medicine, Bioengineering, Biotechnology, Biochemistry and Cell Biology, Chemical Engineering, Industrial Biotechnology

Abstract

Elastomeric protein-based biomaterials, produced from elastin derivatives, are widely investigated as promising tissue engineering scaffolds due to their remarkable properties including substantial extensibility, long-term stability, self-assembly, high resilience upon stretching, low energy loss, and excellent biological activity. These elastomers are processed from different sources of soluble elastin such as animal-derived soluble elastin, recombinant human tropoelastin, and elastin-like polypeptides into various forms including three dimensional (3D) porous hydrogels, elastomeric films, and fibrous electrospun scaffolds. Elastin-based biomaterials have shown great potential for the engineering of elastic tissues such as skin, lung and vasculature. In this review, the synthesis and properties of various elastin-based elastomers with their applications in tissue engineering are described.

Published

2013

15. Hydrogel-coated microfluidic channels for cardiomyocyte culture

Author

Annabi, Nasim, Selimović, Šeila, Cox, Juan Pablo Acevedo, Ribas, João, Bakooshli, Mohsen Afshar, Heintze, Déborah, Weiss, Anthony S, Cropek, Donald, and Khademhosseini, Ali

Subjects

Bioengineering, Regenerative Medicine, Biotechnology, Animals, Cell Adhesion, Cells, Cultured, Dimethylpolysiloxanes, Elasticity, Gelatin, Hydrogel, Polyethylene Glycol Dimethacrylate, Microfluidic Analytical Techniques, Microscopy, Confocal, Myocytes, Cardiac, Rats, Rats, Sprague-Dawley, Tropoelastin, Troponin I, Chemical Sciences, Engineering, Analytical Chemistry

Abstract

The research areas of tissue engineering and drug development have displayed increased interest in organ-on-a-chip studies, in which physiologically or pathologically relevant tissues can be engineered to test pharmaceutical candidates. Microfluidic technologies enable the control of the cellular microenvironment for these applications through the topography, size, and elastic properties of the microscale cell culture environment, while delivering nutrients and chemical cues to the cells through continuous media perfusion. Traditional materials used in the fabrication of microfluidic devices, such as poly(dimethylsiloxane) (PDMS), offer high fidelity and high feature resolution, but do not facilitate cell attachment. To overcome this challenge, we have developed a method for coating microfluidic channels inside a closed PDMS device with a cell-compatible hydrogel layer. We have synthesized photocrosslinkable gelatin and tropoelastin-based hydrogel solutions that were used to coat the surfaces under continuous flow inside 50 μm wide, straight microfluidic channels to generate a hydrogel layer on the channel walls. Our observation of primary cardiomyocytes seeded on these hydrogel layers showed preferred attachment as well as higher spontaneous beating rates on tropoelastin coatings compared to gelatin. In addition, cellular attachment, alignment and beating were stronger on 5% (w/v) than on 10% (w/v) hydrogel-coated channels. Our results demonstrate that cardiomyocytes respond favorably to the elastic, soft tropoelastin culture substrates, indicating that tropoelastin-based hydrogels may be a suitable coating choice for some organ-on-a-chip applications. We anticipate that the proposed hydrogel coating method and tropoelastin as a cell culture substrate may be useful for the generation of elastic tissues, e.g. blood vessels, using microfluidic approaches.

Published

2013

16. Effect of Dense Gas CO2 on the Coacervation of Elastin

Author

Dehghani, Fariba, Annabi, Nasim, Valtchev, Peter, Mithieux, Suzanne M, Weiss, Anthony S, Kazarian, Sergei G, and Tay, Feng H

Subjects

Chemical Engineering, Engineering, Amides, Animals, Carbon Dioxide, Cattle, Circular Dichroism, Elastin, Pressure, Sodium Chloride, Spectrophotometry, Infrared, Spectroscopy, Fourier Transform Infrared, Temperature, Chemical Sciences, Biological Sciences, Polymers, Biological sciences, Chemical sciences

Abstract

In this study for the first time the effect of high-pressure CO2 on the coacervation of alpha-elastin was investigated using analytical techniques including light spectroscopy and attenuated total reflection Fourier transform infrared (ATR-FTIR) spectroscopic imaging and circular dichroism (CD) spectroscopy. The coacervation behavior of alpha-elastin, a protein biopolymer, was determined at temperatures below 40 degrees C and pressures lower than 180 bar. At these conditions elevated pressures did not disrupt the ability of alpha-elastin to coacervate. It was feasible to monitor the presence of amide I, II, and III bands for alpha-elastin at high-pressure CO2 using ATR-FTIR imaging. At a constant temperature the peak absorption was substantially enhanced by increasing the pressure of the system. CD analysis demonstrated the preservation of secondary structure attributes of alpha-elastin exposed to dense gas CO2 at the pressure range investigated in this study. The lower critical solution temperature of alpha-elastin was dramatically decreased from 37 to 16 degrees C when the CO2 pressure increased from 1 to 50 bar, without a significant change after that. Carbon dioxide at high pressures also impeded the reversible coacervation of alpha-elastin solution. These effects were predominantly associated with the lowered pH of the aqueous solution and maybe the interaction between CO2 and hydrophobic domains of alpha-elastin.

Published

2008

17. Effect of dense gas CO2 on the coacervation of elastin.

Author

Dehghani, Fariba, Annabi, Nasim, Valtchev, Peter, Mithieux, Suzanne M, Weiss, Anthony S, Kazarian, Sergei G, and Tay, Feng H

Subjects

Animals, Cattle, Carbon Dioxide, Sodium Chloride, Amides, Elastin, Spectrophotometry, Infrared, Spectroscopy, Fourier Transform Infrared, Circular Dichroism, Temperature, Pressure, Spectrophotometry, Infrared, Spectroscopy, Fourier Transform Infrared, Chemical Sciences, Biological Sciences, Engineering, Polymers

Abstract

In this study for the first time the effect of high-pressure CO2 on the coacervation of alpha-elastin was investigated using analytical techniques including light spectroscopy and attenuated total reflection Fourier transform infrared (ATR-FTIR) spectroscopic imaging and circular dichroism (CD) spectroscopy. The coacervation behavior of alpha-elastin, a protein biopolymer, was determined at temperatures below 40 degrees C and pressures lower than 180 bar. At these conditions elevated pressures did not disrupt the ability of alpha-elastin to coacervate. It was feasible to monitor the presence of amide I, II, and III bands for alpha-elastin at high-pressure CO2 using ATR-FTIR imaging. At a constant temperature the peak absorption was substantially enhanced by increasing the pressure of the system. CD analysis demonstrated the preservation of secondary structure attributes of alpha-elastin exposed to dense gas CO2 at the pressure range investigated in this study. The lower critical solution temperature of alpha-elastin was dramatically decreased from 37 to 16 degrees C when the CO2 pressure increased from 1 to 50 bar, without a significant change after that. Carbon dioxide at high pressures also impeded the reversible coacervation of alpha-elastin solution. These effects were predominantly associated with the lowered pH of the aqueous solution and maybe the interaction between CO2 and hydrophobic domains of alpha-elastin.

Published

2008