Your search keyword '"Katherine M. Kulig"' showing total 20 results

1. In vitroevaluation of decellularized ECM-derived surgical scaffold biomaterials

Author

Katherine M. Kulig, Xiao Luo, Scott M. Goldman, Joseph P. Vacanti, Craig M. Neville, Brian E. Grottkau, Xiang Hong Liu, Cathryn A. Sundback, Eric B. Finkelstein, Irina Pomerantseva, and Margaret F. Nicholson

Subjects

0301 basic medicine, Scaffold, Decellularization, Materials science, Biomedical Engineering, 02 engineering and technology, Matrix (biology), 021001 nanoscience & nanotechnology, Tissue Graft, Regenerative medicine, Biomaterials, Mesothelium, Extracellular matrix, 03 medical and health sciences, 030104 developmental biology, medicine.anatomical_structure, Dermis, medicine, 0210 nano-technology, Biomedical engineering

Abstract

Decellularized extracellular matrix (ECM) biomaterials are increasingly used in regenerative medicine for abdominal tissue repair. Emerging ECM biomaterials with greater compliance target surgical procedures like breast and craniofacial reconstruction to enhance aesthetic outcome. Clinical studies report improved outcomes with newly designed ECM scaffolds, but their comparative biological characteristics have received less attention. In this study, we investigated scaffolds derived from dermis (AlloDerm Regenerative Tissue Matrix), small intestinal submucosa (Surgisis 4-layer Tissue Graft and OASIS Wound Matrix), and mesothelium (Meso BioMatrix Surgical Mesh and Veritas Collagen Matrix) and evaluated biological properties that modulate cellular responses and recruitment. An assay panel was utilized to assess the ECM scaffold effects upon cells. Results of the material-conditioned media study demonstrated Meso BioMatrix and OASIS best supported cell proliferation. Meso BioMatrix promoted the greatest migration and chemotaxis signaling, followed by Veritas and OASIS; OASIS had superior suppression of cell apoptosis. The direct adhesion assay indicated that AlloDerm, Meso BioMatrix, Surgisis, and Veritas had sidedness that affected cell-material interactions. In the chick chorioallantoic membrane assay, Meso BioMatrix and OASIS best supported cell infiltration. Among tested materials, Meso BioMatrix and OASIS demonstrated characteristics that facilitate scaffold incorporation, making them promising choices for many clinical applications. © 2015 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 105B: 585-593, 2017.

Published

2015

2. Liver cell therapy and tissue engineering for transplantation

Author

Joseph P. Vacanti and Katherine M. Kulig

Subjects

Pluripotent Stem Cells, Pathology, medicine.medical_specialty, Xenotransplantation, medicine.medical_treatment, Cell- and Tissue-Based Therapy, Liver transplantation, Mesenchymal Stem Cell Transplantation, Bioinformatics, Regenerative medicine, law.invention, End Stage Liver Disease, law, medicine, Humans, Embryonic Stem Cells, Tissue Engineering, Tissue Scaffolds, Guided Tissue Regeneration, business.industry, Liver cell, Bioartificial liver device, Liver, Artificial, Liver Transplantation, Transplantation, Pediatrics, Perinatology and Child Health, Hepatocytes, Surgery, Liver function, Stem cell, business

Abstract

Liver transplantation remains the only definitive treatment for liver failure and is available to only a tiny fraction of patients with end-stage liver diseases. Major limitations for the procedure include donor organ shortage, high cost, high level of required expertise, and long-term consequences of immune suppression. Alternative cell-based liver therapies could potentially greatly expand the number of patients provided with effective treatment. Investigative research into augmenting or replacing liver function extends into three general strategies. Bioartificial livers (BALs) are extracorporeal devices that utilize cartridges of primary hepatocytes or cell lines to process patient plasma. Injection of liver cell suspensions aims to foster organ regeneration or provide a missing metabolic function arising from a genetic defect. Tissue engineering recreates the organ in vitro for subsequent implantation to augment or replace patient liver function. Translational models and clinical trials have highlighted both the immense challenges involved and some striking examples of success.

Published

2014

3. Ovine Model for Auricular Reconstruction

Author

Cathryn A. Sundback, Mark A. Randolph, Marc H. Hohman, Robin W. Lindsay, Theresa A. Hadlock, Katherine M. Kulig, Xing Zhao, Irina Pomerantseva, Matthew D. Johnson, Joseph P. Vacanti, Mack L. Cheney, and David A. Bichara

Subjects

Male, medicine.medical_specialty, Cosmetic appearance, Dentistry, Surgical site, Animals, Medicine, Complication rate, Sheep, Tissue Engineering, Tissue Scaffolds, business.industry, Microtia, General Medicine, Perioperative, Plastic Surgery Procedures, medicine.disease, Surgery, Otorhinolaryngology, Polyethylene, Models, Animal, Engineered cartilage, Female, Implant, Ear Cartilage, business, Porosity, Ear Auricle, Large animal

Abstract

Objectives: We developed a large animal model for auricular reconstruction with engineered cartilage frameworks and evaluated the performance of porous polyethylene auricular implants in this model. Methods: Eighteen high-density porous polyethylene auricular frameworks were implanted subcutaneously in the infra-auricular areas of 9 sheep. The implants were harvested 17 weeks later for gross and histologic examination. The perioperative and postoperative courses were carefully documented. Results: Five implants became exposed, and 2 implants needed to be removed at 7 weeks. Additionally, 1 infected implant was removed at 2 weeks. Seromas developed in 2 implants because of drain failures and were drained successfully during the first postoperative week. There were no other surgical site complications. The remaining 10 implants had an acceptable cosmetic appearance at 17 weeks. Conclusions: The perioperative complication rate in the ovine porous polyethylene auricular implant model was higher than that reported for auricular reconstructions in humans. The implant exposures were likely caused by ischemia and excessive stress on the thin overlying skin, because vascularized flap coverage was not used. The histologic findings were comparable to the results reported for other animal models. This large animal model is appropriate for auricular reconstruction experiments, including engineered constructs.

Published

2014

4. A bilayer small diameter

Author

David M, Hoganson, Eric B, Finkelstein, Gwen E, Owens, James C, Hsiao, Kurt Y, Eng, Katherine M, Kulig, Ernest S, Kim, Tatiana, Kniazeva, Irina, Pomerantseva, Craig M, Neville, James R, Turk, Bernard, Fermini, Jeffrey T, Borenstein, and Joseph P, Vacanti

Subjects

Regular Articles

Abstract

In pre-clinical safety studies, drug-induced vascular injury (DIVI) is defined as an adverse response to a drug characterized by degenerative and hyperplastic changes of endothelial cells and vascular smooth muscle cells. Inflammation may also be seen, along with extravasation of red blood cells into the smooth muscle layer (i.e., hemorrhage). Drugs that cause DIVI are often discontinued from development after considerable cost has occurred. An in vitro vascular model has been developed using endothelial and smooth muscle cells in co-culture across a porous membrane mimicking the internal elastic lamina. Arterial flow rates of perfusion media within the endothelial chamber of the model induce physiologic endothelial cell alignment. Pilot testing with a drug known to cause DIVI induced extravasation of red blood cells into the smooth muscle layer in all devices with no extravasation seen in control devices. This engineered vascular model offers the potential to evaluate candidate drugs for DIVI early in the discovery process. The physiologic flow within the co-culture model also makes it candidate for a wide variety of vascular biology investigations.

Published

2016

5. Behavior of poly(glycerol sebacate) plugs in chronic tympanic membrane perforations

Author

Cathryn A. Sundback, Alison Hart, Peter T. Masiakos, Irina Pomerantseva, J. McFadden, Katherine M. Kulig, A. M. Wieland, Maria J. N. Pereira, and Christopher J. Hartnick

Subjects

Glycerol, medicine.medical_specialty, Time Factors, Tympanic Membrane, Materials science, Polymers, Perforation (oil well), Biomedical Engineering, Connective tissue, Biomaterials, Chinchilla, Materials Testing, medicine, Animals, Humans, Process (anatomy), Wound Healing, Decellularization, Tympanic Membrane Perforation, Regeneration (biology), Decanoates, Prostheses and Implants, Surgery, medicine.anatomical_structure, Membrane, Chronic Disease, Middle ear, Wound healing, Biomedical engineering

Abstract

The tympanic membrane (TM), separating the external and middle ear, consists of fibrous connective tissue sandwiched between epithelial layers. To treat chronic ear infections, tympanostomy drainage tubes are placed in surgically created holes in TMs which can become chronic perforations upon extrusion. Perforations are repaired using a variety of techniques, but are limited by morbidity, unsatisfactory closure rates, or minimal regeneration of the connective tissue. A more effective, minimally-invasive therapy is necessary to enhance the perforation closure rate. Current research utilizing decellularized or alignate materials moderately enhance closure but the native TM architecture is not restored. Poly(glycerol sebacate) (PGS) is a biocompatible elastomer which supports cell migration and enzymatically degrades in contact with vascularized tissue. PGS spool-shaped plugs were manufactured using a novel process. Using minimally invasive procedures, these elastomeric plugs were inserted into chronic chinchilla TM perforations. As previously reported, effective perforation closure occurred as both flange surfaces were covered by confluent cell layers; >90% of perforations were closed at 6-week postimplantation. This unique in vivo environment has little vascularized tissue. Consequently, PGS degradation was minimal over 16-week implantation, hindering regeneration of the TM fibrous connective tissue. PGS degradation must be enhanced to promote complete TM regeneration.

Published

2012

6. A Nanofiber Membrane Maintains the Quiescent Phenotype of Hepatic Stellate Cells

Author

Jeffrey T. Borenstein, Toni A. Steiner, Bradley T. Keller, Craig M. Neville, Eric Park, Ernest S. Kim, Katherine M. Kulig, Hideaki Shimada, Hiroyuki Eda, and Krupali Patel

Subjects

Liver Cirrhosis, Male, Time Factors, Stress fiber, Physiology, medicine.medical_treatment, Primary Cell Culture, Nanofibers, Biological Factors, Transforming Growth Factor beta2, Cell Movement, Stress Fibers, Gene expression, Cell Adhesion, Hepatic Stellate Cells, medicine, Animals, Rats, Wistar, Endothelin-1, Chemistry, Gene Expression Profiling, Growth factor, Gastroenterology, Quiescent state, hemic and immune systems, Anatomy, Phenotype, Rats, Cell biology, Membrane, Nanofiber, Hepatic stellate cell, Plastics

Abstract

Hepatic stellate cells (HSC) play a major role in the progression of liver fibrosis. The aim of our study was to investigate whether rat HSC cultured on a nanofiber membrane (NM) retain their quiescent phenotype during both short- and long-term culture and whether activated HSC revert to a quiescent form when re-cultured on NM. Rat HSC cultured for 1 day on plastic plates (PP) were used as quiescent HSC, while cells cultured for 1 week on PP were considered to be activated HSC. Quiescent or activated HSC were subsequently plated on PP or NM and cultured for an additional 4 days at which time their gene expression, stress fiber development, and growth factor production were determined. For long-term culture, HSC were grown on NM for 20 days and the cells then replated on PP and cultured for another 10 days. Expression of marker genes for HSC activation, stress fiber development, and growth factor production were significantly lower in both quiescent and activated HSC cultured on NM than in those cultured on PP. After long-term culture on NM, activation marker gene expression and stress fiber development were still significantly lower in HSC than in PP, and HSC still retained the ability to activate when replated onto PP. HSC cultured on NM retained quiescent characteristics after both short- and long-term culture while activated HSC reverted toward a quiescent state when cultured on NM. Cultures of HSC grown on NM are a useful in vitro model to investigate the mechanisms of activation and deactivation.

Published

2012

7. Engineering Ear Constructs with a Composite Scaffold to Maintain Dimensions

Author

Mark A. Randolph, Katherine M. Kulig, Erik K. Bassett, Irina Pomerantseva, Xing Zhao, Libin Zhou, Cathryn A. Sundback, Joseph P. Vacanti, David A. Bichara, and Chris M. Bowley

Subjects

Adult, Scaffold, Biomedical Engineering, Mice, Nude, Bioengineering, Biochemistry, Biomaterials, Glycosaminoglycan, Extracellular matrix, Mice, Hydroxyproline, chemistry.chemical_compound, Ear Cartilage, In vivo, Animals, Humans, Composite scaffold, Pliability, Glycosaminoglycans, Sheep, Tissue Engineering, Tissue Scaffolds, Normal wound healing, Ear, DNA, Immunohistochemistry, Extracellular Matrix, Cartilage, chemistry, Collagen, Biomedical engineering

Abstract

Engineered cartilage composed of a patient's own cells can become a feasible option for auricular reconstruction. However, distortion and shrinkage of ear-shaped constructs during scaffold degradation and neocartilage maturation in vivo have hindered the field. Scaffolds made of synthetic polymers often generate degradation products that cause an inflammatory reaction and negatively affect neocartilage formation in vivo. Porous collagen, a natural material, is a promising candidate; however, it cannot withstand the contractile forces exerted by skin and surrounding tissue during normal wound healing. We hypothesised that a permanent support in the form of a coiled wire embedded into a porous collagen scaffold will maintain the construct's size and ear-specific shape. Half-sized human adult ear-shaped fibrous collagen scaffolds with and without embedded coiled titanium wire were seeded with sheep auricular chondrocytes, cultured in vitro for up to 2 weeks, and implanted subcutaneously on the backs of nude mice. After 6 weeks, the dimensional changes in all implants with wire support were minimal (2.0% in length and 4.1% in width), whereas significant reduction in size occurred in the constructs without embedded wire (14.4% in length and 16.5% in width). No gross distortion occurred over the in vivo study period. There were no adverse effects on neocartilage formation from the embedded wire. Histologically, mature neocartilage extracellular matrix was observed throughout all implants. The amount of DNA, glycosaminoglycan, and hydroxyproline in the engineered cartilage were similar to that of native sheep ear cartilage. The embedded wire support was essential for avoiding shrinkage of the ear-shaped porous collagen constructs.

Published

2011

8. In vitro analysis of a hepatic device with intrinsic microvascular-based channels

Author

M.R. Kaazempur-Mofrad, Jeffrey T. Borenstein, Wen-Ming Hsu, Katherine M. Kulig, Mark L. Miller, Eric F. Swart, Craig M. Neville, Eli J. Weinberg, A. Carraro, Wing Cheung, and Joseph P. Vacanti

Subjects

Male, Silicon, Materials science, Microfluidics, Cell Culture Techniques, Drug Evaluation, Preclinical, Biomedical Engineering, Serum protein, Soft lithography, Cell Line, In vitro analysis, Tissue engineering, Cell Line, Tumor, Animals, Humans, Hepatocytes, Microfluidic Analytical Techniques, Porosity, Rats, Rats, Inbred Lew, Liver, Artificial, Membranes, Artificial, Molecular Biology, Tumor, Membranes, Inbred Lew, Drug discovery, Bilayer, Preclinical, Liver, Artificial, Drug Evaluation, Biomedical engineering, Microfabrication

Abstract

A novel microfluidics-based bilayer device with a discrete parenchymal chamber modeled upon hepatic organ architecture is described. The microfluidics network was designed using computational models to provide appropriate flow behavior based on physiological data from human microvasculature. Patterned silicon wafer molds were used to generate films with the vascular-based microfluidics network design and parenchymal chamber by soft lithography. The assembled device harbors hepatocytes behind a nanoporous membrane that permits transport of metabolites and small proteins while protecting them from the effects of shear stress. The device can sustain both human hepatoma cells and primary rat hepatocytes by continuous in vitro perfusion of medium, allowing proliferation and maintaining hepatic functions such as serum protein synthesis and metabolism. The design and fabrication processes are scalable, enabling the device concept to serve as both a platform technology for drug discovery and toxicity, and for the continuing development of an improved liver-assist device.

Published

2008

9. In vitro evaluation of decellularized ECM-derived surgical scaffold biomaterials

Author

Xiao, Luo, Katherine M, Kulig, Eric B, Finkelstein, Margaret F, Nicholson, Xiang-Hong, Liu, Scott M, Goldman, Joseph P, Vacanti, Brian E, Grottkau, Irina, Pomerantseva, Cathryn A, Sundback, and Craig M, Neville

Subjects

Tissue Scaffolds, Swine, Chemotaxis, Apoptosis, Dermis, Fibroblasts, Extracellular Matrix, Mice, NIH 3T3 Cells, Animals, Humans, Cattle, Cell Proliferation, Signal Transduction

Abstract

Decellularized extracellular matrix (ECM) biomaterials are increasingly used in regenerative medicine for abdominal tissue repair. Emerging ECM biomaterials with greater compliance target surgical procedures like breast and craniofacial reconstruction to enhance aesthetic outcome. Clinical studies report improved outcomes with newly designed ECM scaffolds, but their comparative biological characteristics have received less attention. In this study, we investigated scaffolds derived from dermis (AlloDerm Regenerative Tissue Matrix), small intestinal submucosa (Surgisis 4-layer Tissue Graft and OASIS Wound Matrix), and mesothelium (Meso BioMatrix Surgical Mesh and Veritas Collagen Matrix) and evaluated biological properties that modulate cellular responses and recruitment. An assay panel was utilized to assess the ECM scaffold effects upon cells. Results of the material-conditioned media study demonstrated Meso BioMatrix and OASIS best supported cell proliferation. Meso BioMatrix promoted the greatest migration and chemotaxis signaling, followed by Veritas and OASIS; OASIS had superior suppression of cell apoptosis. The direct adhesion assay indicated that AlloDerm, Meso BioMatrix, Surgisis, and Veritas had sidedness that affected cell-material interactions. In the chick chorioallantoic membrane assay, Meso BioMatrix and OASIS best supported cell infiltration. Among tested materials, Meso BioMatrix and OASIS demonstrated characteristics that facilitate scaffold incorporation, making them promising choices for many clinical applications. © 2015 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 105B: 585-593, 2017.

Published

2015

10. Conditions for seeding and promoting neo-auricular cartilage formation in a fibrous collagen scaffold

Author

Irina Pomerantseva, Christopher M. Bowley, David A. Bichara, Alan Tseng, Joseph P. Vacanti, Mark A. Randolph, Katherine M. Kulig, Cathryn A. Sundback, Xing Zhao, and Libin Zhou

Subjects

Scaffold, Pathology, medicine.medical_specialty, Time Factors, Surface Properties, Cell Culture Techniques, Mice, Nude, Cell Separation, Collagen Type I, Mice, Chondrocytes, Subcutaneous Tissue, Tissue engineering, Ear Cartilage, medicine, Animals, Cells, Cultured, Glycosaminoglycans, Auricle, Sheep, Tissue Engineering, Tissue Scaffolds, business.industry, Cartilage, food and beverages, Anatomy, DNA, Chondrogenesis, Costal cartilage, Elastin, Hydroxyproline, medicine.anatomical_structure, Otorhinolaryngology, Surgery, Oral Surgery, business, Type I collagen

Abstract

Background Carved autologous costal cartilage and porous polyethylene implants (Medpor) are the most common approaches for total ear reconstruction, but these approaches may have inconsistent cosmetic outcomes, a high risk of extrusion, or other surgical complications. Engineering ear cartilage to emulate native auricular tissue is an appealing approach, but often the cell-seeded scaffolds are susceptible to shrinkage and architectural changes when placed in vivo . The aim of this study was to assess the most favorable conditions for in vitro pre-culture of cell-seeded type I collagen scaffolds prior to in vivo implantation. Methods Sheep auricular chondrocytes were seeded into this type I collagen scaffold. The cell-seeded constructs were cultured in either static or dynamic conditions for two days or two weeks and then implanted into nude mice for another six weeks. The harvested constructs were evaluated histologically, immunohistochemically, and biochemically. Results Robust neo-cartilage formation was found in these collagen scaffolds seeded with auricular chondrocytes, which was comparable to native cartilage morphologically, histologically, and biochemically. Culture under dynamic conditions prior to implantation improved the neo-cartilage formation histologically and biochemically. Conclusion Dynamic culture of this cell-seeded fibrous collagen material could permit predictable engineered auricular cartilage and a promising approach for external ear reconstruction.

Published

2014

11. A bilayer small diameter in vitro vascular model for evaluation of drug induced vascular injury

Author

David M. Hoganson, James C. Hsiao, James R. Turk, Kurt Y. Eng, Eric B. Finkelstein, Craig M. Neville, Joseph P. Vacanti, Ernest S. Kim, Tatiana Kniazeva, Jeffrey T. Borenstein, Irina Pomerantseva, Gwen E. Owens, Bernard Fermini, and Katherine M. Kulig

Subjects

0301 basic medicine, Fluid Flow and Transfer Processes, Pathology, medicine.medical_specialty, Vascular smooth muscle, business.industry, 0206 medical engineering, Smooth muscle layer, Biomedical Engineering, Inflammation, 02 engineering and technology, Condensed Matter Physics, Internal elastic lamina, 020601 biomedical engineering, In vitro, Extravasation, Endothelial stem cell, 03 medical and health sciences, 030104 developmental biology, Colloid and Surface Chemistry, Medicine, General Materials Science, medicine.symptom, business, Perfusion

Abstract

In pre-clinical safety studies, drug-induced vascular injury (DIVI) is defined as an adverse response to a drug characterized by degenerative and hyperplastic changes of endothelial cells and vascular smooth muscle cells. Inflammation may also be seen, along with extravasation of red blood cells into the smooth muscle layer (i.e., hemorrhage). Drugs that cause DIVI are often discontinued from development after considerable cost has occurred. An in vitro vascular model has been developed using endothelial and smooth muscle cells in co-culture across a porous membrane mimicking the internal elastic lamina. Arterial flow rates of perfusion media within the endothelial chamber of the model induce physiologic endothelial cell alignment. Pilot testing with a drug known to cause DIVI induced extravasation of red blood cells into the smooth muscle layer in all devices with no extravasation seen in control devices. This engineered vascular model offers the potential to evaluate candidate drugs for DIVI early in the discovery process. The physiologic flow within the co-culture model also makes it candidate for a wide variety of vascular biology investigations.

Published

2016

12. Biologic properties of surgical scaffold materials derived from dermal ECM

Author

Xiang-Hong Liu, Cathryn A. Sundback, Eric B. Finkelstein, Craig M. Neville, Katherine M. Kulig, Scott M. Goldman, Xiao Luo, and Joseph P. Vacanti

Subjects

Scaffold, Cell signaling, Materials science, Cell, Sus scrofa, Biophysics, Bioengineering, Apoptosis, Biocompatible Materials, Chorioallantoic Membrane, Cell Line, Surgical Equipment, Biomaterials, Extracellular matrix, Materials Testing, medicine, Cell Adhesion, Animals, Humans, Cell Proliferation, Decellularization, Tissue Scaffolds, Cell growth, Chemotaxis, Dermis, Extracellular Matrix, Chorioallantoic membrane, medicine.anatomical_structure, Mechanics of Materials, Cell culture, Culture Media, Conditioned, Ceramics and Composites, Chickens, Biomedical engineering

Abstract

Surgical scaffold materials manufactured from donor human or animal tissue are increasingly being used to promote soft tissue repair and regeneration. The clinical product consists of the residual extracellular matrix remaining after a rigorous decellularization process. Optimally, the material provides both structural support during the repair period and cell guidance cues for effective incorporation into the regenerating tissue. Surgical scaffold materials are available from several companies and are unique products manufactured by proprietary methodology. A significant need exists for a more thorough understanding of scaffold properties that impact the early steps of host cell recruitment and infiltration. In this study, a panel of in vitro assays was used to make direct comparisons of several similar, commercially-available materials: Alloderm, Medeor Matrix, Permacol, and Strattice. Differences in the materials were detected for both cell signaling and scaffold architecture-dependent cell invasion. Material-conditioned media studies found Medeor Matrix to have the greatest positive effect upon cell proliferation and induction of migration. Strattice provided the greatest chemotaxis signaling and best suppressed apoptotic induction. Among assays measuring structure-dependent properties, Medeor Matrix was superior for cell attachment, followed by Permacol. Only Alloderm and Medeor Matrix supported chemotaxis-driven cell invasion beyond the most superficial zone. Medeor Matrix was the only material in the chorioallantoic membrane assay to support substantial cell invasion. These results indicate that both biologic and structural properties need to be carefully assessed in the considerable ongoing efforts to develop new uses and products in this important class of biomaterials.

Published

2012

13. Liver-assist device with a microfluidics-based vascular bed in an animal model

Author

Joseph P. Vacanti, Eli J. Weinberg, Jeffrey T. Borenstein, A. Carraro, Katherine M. Kulig, Fateh Entabi, Michael T. Watkins, Wen-Ming Hsu, Hassan Albadawi, Craig M. Neville, M.R. Kaazempur-Mofrad, and Mark L. Miller

Subjects

Male, Pathology, medicine.medical_specialty, Cell Survival, Animals, Arteriovenous Shunt, Surgical, Bioreactors, Cell Culture Techniques, Cells, Cultured, Disease Models, Animal, Femur, Hepatocytes, Laser-Doppler Flowmetry, Microcirculation, Microfluidics, Proteins, Rats, Rats, Inbred Lew, Liver, Artificial, Cells, Surgical, Medicine, Viability assay, Cultured, Inbred Lew, Animal, business.industry, Arteriovenous Shunt, Blood flow, Laser Doppler velocimetry, medicine.anatomical_structure, Liver, Disease Models, Artificial, Circulatory system, Surgery, Liver function, business, Perfusion, Blood vessel

Abstract

Objective This study evaluates a novel liver-assist device platform with a microfluidics-modeled vascular network in a femoral arteriovenous shunt in rats. Summary of background data Liver-assist devices in clinical trials that use pumps to force separated plasma through packed beds of parenchymal cells exhibited significant necrosis with a negative impact on function. Methods Microelectromechanical systems technology was used to design and fabricate a liver-assist device with a vascular network that supports a hepatic parenchymal compartment through a nanoporous membrane. Sixteen devices with rat primary hepatocytes and 12 with human HepG2/C3A cells were tested in athymic rats in a femoral arteriovenous shunt model. Several parenchymal tube configurations were evaluated for pressure profile and cell survival. The blood flow pattern and perfusion status of the devices was examined by laser Doppler scanning. Cell viability and serum protein secretion functions were assessed. Results Femoral arteriovenous shunt was successfully established in all animals. Blood flow was homogeneous through the vascular bed and replicated native flow patterns. Survival of seeded liver cells was highly dependent on parenchymal chamber pressures. The tube configuration that generated the lowest pressure supported excellent cell survival and function. Conclusions This device is the first to incorporate a microfluidics network in the systemic circulatory system. The microvascular network supported viability and function of liver cells in a short-term ex vivo model. Parenchymal chamber pressure generated in an arteriovenous shunt model is a critical parameter that affects viability and must be considered in future designs. The microfluidics-based vascular network is a promising platform for generating a large-scale medical device capable of augmenting liver function in a clinical setting.

Published

2010

14. Three-Dimensional Microfluidic Tissue-Engineering Scaffolds Using a Flexible Biodegradable Polymer

Author

Yadong Wang, Katherine M. Kulig, Robert Langer, Christopher J. Bettinger, Jeffrey T. Borenstein, Joseph P. Vacanti, and Eli J. Weinberg

Subjects

Scaffold, Materials science, Biocompatibility, Mechanical Engineering, Microfluidics, technology, industry, and agriculture, Nanotechnology, Biodegradable polymer, Article, PLGA, chemistry.chemical_compound, Tissue engineering, chemistry, Mechanics of Materials, General Materials Science, Polymer scaffold, Microfabrication

Abstract

Organ loss and failure is one of the most critical issues facing the healthcare industry in developed nations. The shortage of available organ donors has driven the growth and expansion of the field of tissue engineering as a means of developing replacement tissues and organs[1,2] including the liver.[3] Microfabrication and bio-microelectromechanical system (bio-MEMS) technology is an attractive tool for developing tissue-engineering systems because of the improved spatial resolutions over traditional scaffold fabrication techniques such as casting and porogen leaching,[4] gas foaming,[5] and three-dimensional printing.[6] Polymer scaffolds replica-molded on micromachined silicon substrates can achieve feature resolutions of less than 10 µm,[7] the same lengthscale of mammalian cells. Microfluidic bioreactors have been both fabricated and seeded with a variety of cell types, including endothelial cells[7–10] and hepatocytes.[10–12] However, one limiting factor in previous studies of microfluidic scaffolds has been the choice of material. Microfabricated silicon and replica-molded poly(dimethylsiloxane) (PDMS), although ubiquitous and inexpensive, are not biodegradable and have limited biocompatibility, and therefore are not suitable biomaterials for a tissue-engineering scaffold. Microfluidic scaffolds fabricated from poly(L-lactic-co-glycolic acid) (PLGA),[13] while biodegradable, exhibit suboptimal properties for an implant material, such as rigid mechanical properties,[14] undesirable bulk degradation kinetics,[15] and limited biocompatibility in some cases.[16] High concentrations of PLGA byproducts has also been shown to be cytotoxic,[17] which is a major limitation in the prospect of fabricating large, organ-size scaffolds.

Published

2009

15. Poly(glycerol sebacate)-engineered plugs to repair chronic tympanic membrane perforations in a chinchilla model

Author

Peter T. Masiakos, Christopher J. Hartnick, Aaron M. Wieland, Cathryn A. Sundback, Katherine M. Kulig, and Allison Hart

Subjects

Chinchilla, Glycerol, medicine.medical_specialty, Polymers, Perforation (oil well), Neovascularization, Physiologic, Neovascularization, Myringoplasty, biology.animal, otorhinolaryngologic diseases, Medicine, Animals, Tympanic Membrane Perforation, Wound Healing, biology, Tissue Scaffolds, business.industry, Guided Tissue Regeneration, Decanoates, Histology, Surgery, Disease Models, Animal, Membrane, Otorhinolaryngology, Female, medicine.symptom, business, Wound healing

Abstract

Objective To evaluate the degree of neovascularization and efficacy of repair of chronic tympanic membrane perforations in a chinchilla model using poly(glycerol sebacate) (PGS), a novel bioengineered scaffold material. Study Design A feasibility study in which chinchilla ears with chronic perforations were randomly assigned to repair with PGS plugs or Gelfilm overlay myringoplasty. Setting Interventions were performed in the animal care facility of a tertiary care academic institution. Subjects and Methods Sixteen adult female chinchillas. Perforations were established under microscopic visualization with thermal cautery. The animals were examined six weeks later, and those ears with stable perforations were randomly assigned to repair with PGS or Gelfilm. All ears were evaluated six weeks after repair, and resected membranes underwent histological evaluation. Results Chronic perforations were established in 22 of 32 (69%) chinchilla tympanic membranes. Nineteen tympanic membranes were included in the study group (3 ears were excluded secondary to death from anesthesia during the repair); 11 were implanted with PGS, and eight underwent Gelfilm myringoplasty. Of the 11 tympanic membranes implanted with PGS, 10 were healed at six weeks, while six of the eight tympanic membranes repaired with Gelfilm had healed at six weeks. Imaging of the medial mucosal and lateral epithelial surfaces of the tympanic membranes revealed PGS plug incorporation with neovascularization. Histology demonstrated a confluent cell layer on both sides of the graft. Conclusions PGS plugs are easily placed and allow for perforation closure and graft neovascularization in a chinchilla model.

Published

2009

16. Nanofabricated collagen-inspired synthetic elastomers for primary rat hepatocyte culture

Author

Christopher J. Bettinger, Katherine M. Kulig, Robert Langer, Joseph P. Vacanti, and Jeffrey T. Borenstein

Subjects

Biomedical Engineering, Cell Culture Techniques, Bioengineering, Biochemistry, Article, Biomaterials, Extracellular matrix, Tissue engineering, Cell Movement, medicine, Cell Adhesion, Animals, Nanotechnology, Secretion, Cell adhesion, Cell Shape, Cells, Cultured, Chemistry, Substrate (chemistry), Adhesion, Rats, medicine.anatomical_structure, Elastomers, Liver, Cell culture, Hepatocyte, Biophysics, Hepatocytes, Collagen

Abstract

Synthetic substrates that mimic the properties of extracellular matrix proteins hold significant promise for use in systems designed for tissue engineering applications. In this report, we designed a synthetic polymeric substrate that is intended to mimic chemical, mechanical, and topological characteristics of collagen. We found that elastomeric poly(ester amide) substrates modified with replica-molded nanotopographic features enhanced initial attachment, spreading, and adhesion of primary rat hepatocytes. Further, hepatocytes cultured on nanotopographic substrates also demonstrated reduced albumin secretion and urea synthesis, which is indicative of strongly adherent hepatocytes. These results suggest that these engineered substrates can function as synthetic collagen analogs for in vitro cell culture.

Published

2008

17. Tissue Engineering of Liver

Author

Alexander B. G. Katherine M. Kulig, Alexander B. G. Sevy, and Alexander B. G. Katherine M. Joseph P. Vacanti

Subjects

Pathology, medicine.medical_specialty, Tissue engineering, business.industry, medicine, business

Published

2008

18. Hepatic tissue engineering

Author

Joseph P. Vacanti and Katherine M. Kulig

Subjects

medicine.medical_specialty, Cell Survival, Immunology, Cell Culture Techniques, Economic shortage, Organ transplantation, Fulminant hepatic failure, Bioreactors, Tissue engineering, Immunology and Allergy, Medicine, Animals, Humans, Intensive care medicine, Transplantation, Tissue Engineering, business.industry, Hepatic tissue, Liver Failure, Acute, Liver, Artificial, Tissue Donors, Surgery, Waiting list, Hepatocytes, Liver function, business

Abstract

Fulminant hepatic failure (FHF) attributes to rising medical cost and accounts for many deaths each year in the United States. Currently, the only solution is organ transplantation. Due to increasing donor organ shortage, many in need of transplantation continue to remain on the waiting list. Liver Assist Devices (LADs) are being used to temporarily sustain liver function and bridge the period between FHF and transplantation. Hepatic Tissue Engineering is a step toward alleviating the need for donor organs; yet many challenges must be overcome including scaffold choice, cell source and immunological barriers. Bioreactors have aided in hepatocyte survival and have proven to sustain viable cells for several weeks. Achieving the necessary functions required for hepatic replacement is aided by the incorporation of growth factors and mitogens many that now can be bound to the polymer scaffold and released in a timely manner. Utilizing concepts such as MicroElectroMechanical systems (MEMs) technology, our laboratory is able to mimic the natural vasculature of the liver and sustain functional and viable hepatocytes. Expanding and improving upon this platform technology, advancements made will continue toward the development of a fully functioning and implantable liver.

Published

2004

19. 120: DEVELOPMENT OF AN ENGINEERED EAR USING A FIBROUS COLLAGEN SCAFFOLD WITH EMBEDDED WIRE

Author

David A. Bichara, Joseph P. Vacanti, Erik K. Bassett, Mark A. Randolph, L Zhou, X Zhao, Irina Pomerantseva, Cathryn A. Sundback, and Katherine M. Kulig

Subjects

business.industry, Medicine, Surgery, business, Collagen scaffold, Biomedical engineering

Published

2011

20. Liver assist device as bridge for liver transplant in hepatic failure: A first in vivo step of tissue engineering development

Author

Mark L. Miller, Wen-Ming Hsu, A. Carraro, Eli J. Weinberg, Joseph P. Vacanti, B. Orrick, K. Morgan, Umberto Cillo, Craig M. Neville, E. Swart, J.T. Borenstein, Katherine M. Kulig, K. Bonner, and M.R. Kaazempur-Mofrad

Subjects

medicine.medical_specialty, Hepatology, Tissue engineering, business.industry, In vivo, law, Gastroenterology, medicine, Bioartificial liver device, business, Bridge (interpersonal), Surgery, law.invention

Published

2007