Your search keyword '"N, Hibino"' showing total 42 results

1. Mechanical stimulation enhances development of scaffold-free, 3D-printed, engineered heart tissue grafts.

Author

Lui C, Chin AF, Park S, Yeung E, Kwon C, Tomaselli G, Chen Y, and Hibino N

Subjects

Biomarkers metabolism, Cell Proliferation, Extracellular Matrix metabolism, Female, Fibroblasts metabolism, Gene Expression Regulation, Humans, Induced Pluripotent Stem Cells, Myocardial Contraction physiology, Sarcomeres metabolism, Heart Transplantation, Printing, Three-Dimensional, Stress, Mechanical, Tissue Engineering, Tissue Scaffolds chemistry

Abstract

Current efforts to engineer a clinically relevant tissue graft from human-induced pluripotent stem cells (hiPSCs) have relied on the addition or utilization of external scaffolding material. However, any imbalance in the interactions between embedded cells and their surroundings may hinder the success of the resulting tissue graft. Therefore, the goal of our study was to create scaffold-free, 3D-printed cardiac tissue grafts from hiPSC-derived cardiomyocytes (CMs), and to evaluate whether or not mechanical stimulation would result in improved graft maturation. To explore this, we used a 3D bioprinter to produce scaffold-free cardiac tissue grafts from hiPSC-derived CM cell spheroids. Static mechanical stretching of these grafts significantly increased sarcomere length compared to unstimulated free-floating tissues, as determined by immunofluorescent image analysis. Stretched tissue was found to have decreased elastic modulus, increased maximal contractile force, and increased alignment of formed extracellular matrix, as expected in a functionally maturing tissue graft. Additionally, stretched tissues had upregulated expression of cardiac-specific gene transcripts, consistent with increased cardiac-like cellular identity. Finally, analysis of extracellular matrix organization in stretched grafts suggests improved remodeling by embedded cardiac fibroblasts. Taken together, our results suggest that mechanical stretching stimulates hiPSC-derived CMs in a 3D-printed, scaffold-free tissue graft to develop mature cardiac material structuring and cellular fates. Our work highlights the critical role of mechanical conditioning as an important engineering strategy toward developing clinically applicable, scaffold-free human cardiac tissue grafts., (© 2021 John Wiley & Sons Ltd.)

Published

2021

2. Assessment of decellularized pericardial extracellular matrix and poly(propylene fumarate) biohybrid for small-diameter vascular graft applications.

Author

Kimicata M, Allbritton-King JD, Navarro J, Santoro M, Inoue T, Hibino N, and Fisher JP

Subjects

Animals, Cattle, Fumarates, Humans, Pericardium, Polypropylenes, Tissue Scaffolds, Extracellular Matrix, Tissue Engineering

Abstract

Autologous grafts are the current gold standard of care for coronary artery bypass graft surgeries, but are limited by availability and plagued by high failure rates. Similarly, tissue engineering approaches to small diameter vascular grafts using naturally derived and synthetic materials fall short, largely due to inappropriate mechanical properties. Alternatively, decellularized extracellular matrix from tissue is biocompatible and has comparable strength to vessels, while poly(propylene fumarate) (PPF) has shown promising results for vascular grafts. This study investigates the integration of decellularized pericardial extracellular matrix (dECM) and PPF to create a biohybrid scaffold (dECM+PPF) suitable for use as a small diameter vascular graft. Our method to decellularize the ECM was efficient at removing DNA content and donor variability, while preserving protein composition. PPF was characterized and added to dECM, where it acted to preserve dECM against degradative effects of collagenase without disturbing the material's overall mechanics. A transport study showed that diffusion occurs across dECM+PPF without any effect from collagenase. The modulus of dECM+PPF matched that of human coronary arteries and saphenous veins. dECM+PPF demonstrated ample circumferential stress, burst pressure, and suture retention strength to survive in vivo. An in vivo study showed re-endothelialization and tissue growth. Overall, the dECM+PPF biohybrid presents a robust solution to overcome the limitations of the current methods of treatment for small diameter vascular grafts. STATEMENT OF SIGNIFICANCE: In creating a dECM+PPF biohybrid graft, we have observed phenomena that will have a lasting impact within the scientific community. First, we found that we can reduce donor variability through decellularization, a unique use of the decellularization process. Additionally, we coupled a natural material with a synthetic polymer to capitalize on the benefits of each: the cues provided to cells and the ability to easily tune material properties, respectively. This principle can be applied to other materials in a variety of applications. Finally, we created an off-the-shelf alternative to autologous grafts with a newly developed material that has yet to be utilized in any scaffolds. Furthermore, bovine pericardium has not been investigated as a small diameter vascular graft., Competing Interests: Declaration of Competing Interest JPF holds a patent for the original biohybrid (US 2016/0089476A1). Remaining authors have no conflicts of interest. The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020. Published by Elsevier Ltd.)

Published

2020

3. In vivo implantation of 3-dimensional printed customized branched tissue engineered vascular graft in a porcine model.

Author

Yeung E, Inoue T, Matsushita H, Opfermann J, Mass P, Aslan S, Johnson J, Nelson K, Kim B, Olivieri L, Krieger A, and Hibino N

Subjects

Animals, Computer-Aided Design, Disease Models, Animal, Feasibility Studies, Pulmonary Artery surgery, Swine, Blood Vessel Prosthesis, Blood Vessel Prosthesis Implantation instrumentation, Printing, Three-Dimensional, Tissue Engineering instrumentation

Abstract

Background: The customized vascular graft offers the potential to simplify the surgical procedure, optimize physiological function, and reduce morbidity and mortality. This experiment evaluated the feasibility of a flow dynamic-optimized branched tissue engineered vascular graft (TEVG) customized based on medical imaging and manufactured by 3-dimensional (3D) printing for a porcine model., Methods: We acquired magnetic resonance angiography and 4-dimensional flow data for the native anatomy of the pigs (n = 2) to design a custom-made branched vascular graft of the pulmonary bifurcation. An optimal shape of the branched vascular graft was designed using a computer-aided design system informed by computational flow dynamics analysis. We manufactured and implanted the graft for pulmonary artery (PA) reconstruction in the porcine model. The graft was explanted at 4 weeks after implantation for further evaluation., Results: The custom-made branched PA graft had a wall shear stress and pressure drop (PD) from the main PA to the branch PA comparable to the native vessel. At the end point, magnetic resonance imaging revealed comparable left/right pulmonary blood flow balance. PD from main PA to branch between before and after the graft implantation was unchanged. Immunohistochemistry showed evidence of endothelization and smooth muscle layer formation without calcification of the graft., Conclusions: Our animal model demonstrates the feasibility of designing and implanting image-guided, 3D-printed, customized grafts. These grafts can be designed to optimize both anatomic fit and hemodynamic properties. This study demonstrates the tremendous potential structural and physiological advantages of customized TEVGs in cardiac surgery., (Copyright © 2019 The American Association for Thoracic Surgery. Published by Elsevier Inc. All rights reserved.)

Published

2020

4. Spontaneous reversal of stenosis in tissue-engineered vascular grafts.

Author

Drews JD, Pepper VK, Best CA, Szafron JM, Cheatham JP, Yates AR, Hor KN, Zbinden JC, Chang YC, Mirhaidari GJM, Ramachandra AB, Miyamoto S, Blum KM, Onwuka EA, Zakko J, Kelly J, Cheatham SL, King N, Reinhardt JW, Sugiura T, Miyachi H, Matsuzaki Y, Breuer J, Heuer ED, West TA, Shoji T, Berman D, Boe BA, Asnes J, Galantowicz M, Matsumura G, Hibino N, Marsden AL, Pober JS, Humphrey JD, Shinoka T, and Breuer CK

Subjects

Animals, Child, Humans, Sheep, United States, Blood Vessel Prosthesis, Constriction, Pathologic therapy, Tissue Engineering

Abstract

We developed a tissue-engineered vascular graft (TEVG) for use in children and present results of a U.S. Food and Drug Administration (FDA)-approved clinical trial evaluating this graft in patients with single-ventricle cardiac anomalies. The TEVG was used as a Fontan conduit to connect the inferior vena cava and pulmonary artery, but a high incidence of graft narrowing manifested within the first 6 months, which was treated successfully with angioplasty. To elucidate mechanisms underlying this early stenosis, we used a data-informed, computational model to perform in silico parametric studies of TEVG development. The simulations predicted early stenosis as observed in our clinical trial but suggested further that such narrowing could reverse spontaneously through an inflammation-driven, mechano-mediated mechanism. We tested this unexpected, model-generated hypothesis by implanting TEVGs in an ovine inferior vena cava interposition graft model, which confirmed the prediction that TEVG stenosis resolved spontaneously and was typically well tolerated. These findings have important implications for our translational research because they suggest that angioplasty may be safely avoided in patients with asymptomatic early stenosis, although there will remain a need for appropriate medical monitoring. The simulations further predicted that the degree of reversible narrowing can be mitigated by altering the scaffold design to attenuate early inflammation and increase mechano-sensing by the synthetic cells, thus suggesting a new paradigm for optimizing next-generation TEVGs. We submit that there is considerable translational advantage to combined computational-experimental studies when designing cutting-edge technologies and their clinical management., (Copyright © 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2020

5. Principles of Spheroid Preparation for Creation of 3D Cardiac Tissue Using Biomaterial-Free Bioprinting.

Author

Ong CS, Pitaktong I, and Hibino N

Subjects

Cells, Cultured, Cytokines pharmacology, Fibroblasts, Human Umbilical Vein Endothelial Cells, Humans, Induced Pluripotent Stem Cells cytology, Induced Pluripotent Stem Cells drug effects, Specimen Handling, Biocompatible Materials, Bioprinting methods, Myocytes, Cardiac transplantation, Printing, Three-Dimensional, Spheroids, Cellular transplantation, Tissue Engineering methods, Tissue Scaffolds

Abstract

Biomaterial-free three-dimensional (3D) bioprinting is a relatively new field within 3D bioprinting, where 3D tissues are created from the fusion of 3D multicellular spheroids, without requiring biomaterial. This is in contrast to traditional 3D bioprinting, which requires biomaterials to carry the cells to be bioprinted, such as a hydrogel or decellularized extracellular matrix. Here, we discuss principles of spheroid preparation for biomaterial-free 3D bioprinting of cardiac tissue. In addition, we discuss principles of using spheroids as building blocks in biomaterial-free 3D bioprinting, including spheroid dislodgement, spheroid transfer, and spheroid fusion. These principles are important considerations, to create the next generation of biomaterial-free spheroid-based 3D bioprinters.

Published

2020

6. Bioprinting of freestanding vascular grafts and the regulatory considerations for additively manufactured vascular prostheses.

Author

Abdollahi S, Boktor J, and Hibino N

Subjects

Humans, Bioprinting, Blood Vessel Prosthesis, Printing, Three-Dimensional, Tissue Engineering legislation & jurisprudence, Tissue Engineering methods

Abstract

Vasculature is the network of blood vessels of an organ or body part that allow for the exchange of nutrients and waste to and from every cell, thus establishing a circulatory equilibrium. Vascular health is at risk from a variety of conditions that includes disease and trauma. In some cases, medical therapy can alleviate the impacts of the condition. Intervention is needed in other instances to restore the health of abnormal vasculature. The main approaches to treat vascular conditions are endovascular procedures and open vascular reconstruction that often requires a graft to accomplish. However, current vascular prostheses have limitations that include size mismatch with the native vessel, risk of immunogenicity from allografts and xenografts, and unavailability of autografts. In this review, we discuss efforts in bioprinting, an emerging method for vascular reconstruction. This includes an overview of 3D printing processes and materials, graft characterization strategies and the regulatory aspects to consider for the commercialization of 3D bioprinted vascular prostheses., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

7. A Net Mold-Based Method of Biomaterial-Free Three-Dimensional Cardiac Tissue Creation.

Author

Yang B, Lui C, Yeung E, Matsushita H, Jeyaram A, Pitaktong I, Inoue T, Mohamed Z, Ong CS, DiSilvestre D, Jay SM, Tung L, Tomaselli G, Ma C, and Hibino N

Subjects

Animals, Arteries surgery, Cell Line, Cell Size, Cell Survival drug effects, Collagen pharmacology, Electrocardiography, Exosomes metabolism, Female, Heart diagnostic imaging, Heart drug effects, Humans, Ligation, Rats, Rats, Inbred Lew, Rats, Nude, Spheroids, Cellular cytology, Biocompatible Materials pharmacology, Heart physiology, Tissue Engineering methods

Abstract

Ischemic cardiomyopathy poses a significant public health burden due to the irreversible loss of functional cardiac tissue. Alternative treatment strategies include creation of three-dimensional (3D) cardiac tissues to both replace and augment injured native tissue. In this study, we utilize a net mold-based method to create a biomaterial-free 3D cardiac tissue and compare it to current methods using biomaterials. Cardiomyocytes, fibroblasts, and endothelial cells were combined using a hanging drop method to create spheroids. For the net mold patch method, spheroids were seeded into a net mold-based system to create biomaterial-free 3D cardiac patches. For the gel patch, spheroids were embedded in a collagen gel. Immunohistochemistry revealed increased alignment, vascularization, collagen I expression, cell viability, and higher density of cells in the net mold patch compared with the gel patch. Furthermore, in vivo testing in a left anterior descending artery ligation rat model found increased ejection fraction and smaller scar area following implantation of the net mold patch. We present a novel and simple reproducible method to create biomaterial-free 3D net mold patches that may potentially improve the treatment of heart failure in the future.

Published

2019

8. Formation of Neoarteries with Optimal Remodeling Using Rapidly Degrading Textile Vascular Grafts.

Author

Fukunishi T, Ong CS, Lui C, Pitaktong I, Smoot C, Harris J, Gabriele P, Vricella L, Santhanam L, Lu S, and Hibino N

Subjects

Animals, Blood Vessel Prosthesis Implantation methods, Constriction, Pathologic surgery, Polymers chemistry, Tissue Engineering methods

Abstract

Impact Statement: We utilized innovative textile technology to create tissue-engineered vascular grafts (TEVGs) comprised exclusively of rapidly degrading material poly(glycolic acid). Our new technology led to robust neotissue formation in the TEVGs, especially extracellular matrix formation, such as elastin. In addition, the rapid degradation of the polymer significantly reduced complications, such as stenosis or calcification, as seen with the use of slow degrading polymers in the majority of previous studies for aortic small diameter TEVGs.

Published

2019

9. A Net Mold-based Method of Scaffold-free Three-Dimensional Cardiac Tissue Creation.

Author

Bai Y, Yeung E, Lui C, Ong CS, Pitaktong I, Huang C, Inoue T, Matsushita H, Ma C, and Hibino N

Subjects

Cells, Cultured, Humans, Myocytes, Cardiac cytology, Myocytes, Cardiac metabolism, Tissue Engineering methods

Abstract

This protocol describes a novel and easy net mold-based method to create three-dimensional (3-D) cardiac tissues without additional scaffold material. Human-induced pluripotent stem-cell-derived cardiomyocytes (iPSC-CMs), human cardiac fibroblasts (HCFs), and human umbilical vein endothelial cells (HUVECs) are isolated and used to generate a cell suspension with 70% iPSC-CMs, 15% HCFs, and 15% HUVECs. They are co-cultured in an ultra-low attachment "hanging drop" system, which contains micropores for condensing hundreds of spheroids at one time. The cells aggregate and spontaneously form beating spheroids after 3 days of co-culture. The spheroids are harvested, seeded into a novel mold cavity, and cultured on a shaker in the incubator. The spheroids become a mature functional tissue approximately 7 days after seeding. The resultant multilayered tissues consist of fused spheroids with satisfactory structural integrity and synchronous beating behavior. This new method has promising potential as a reproducible and cost-effective method to create engineered tissues for the treatment of heart failure in the future.

Published

2018

10. In vivo therapeutic applications of cell spheroids.

Author

Ong CS, Zhou X, Han J, Huang CY, Nashed A, Khatri S, Mattson G, Fukunishi T, Zhang H, and Hibino N

Subjects

Animals, Humans, Cell- and Tissue-Based Therapy, Regenerative Medicine, Spheroids, Cellular, Tissue Engineering

Abstract

Spheroids are increasingly being employed to answer a wide range of clinical and biomedical inquiries ranging from pharmacology to disease pathophysiology, with the ultimate goal of using spheroids for tissue engineering and regeneration. When compared to traditional two-dimensional cell culture, spheroids have the advantage of better replicating the 3D extracellular microenvironment and its associated growth factors and signaling cascades. As knowledge about the preparation and maintenance of spheroids has improved, there has been a plethora of translational experiments investigating in vivo implantation of spheroids into various animal models studying tissue regeneration. We review methods for spheroid delivery and how they have been utilized in tissue engineering experiments. We break down efforts in this field by organ systems, discussing applications of spheroids to various animal models of disease processes and their potential clinical implications. These breakthroughs have been made possible by advancements in spheroid formation, in vivo delivery and assessment. There is unexplored potential and room for further research and development in spheroid-based tissue engineering approaches. Regenerative medicine and other clinical applications ensure this exciting area of research remains relevant for patient care., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2018

11. Role of Bone Marrow Mononuclear Cell Seeding for Nanofiber Vascular Grafts.

Author

Fukunishi T, Best CA, Ong CS, Groehl T, Reinhardt J, Yi T, Miyachi H, Zhang H, Shinoka T, Breuer CK, Johnson J, and Hibino N

Subjects

Animals, Blood Vessel Prosthesis, Cells, Cultured, Female, Immunohistochemistry, Mice, Mice, Inbred C57BL, Bone Marrow Cells cytology, Tissue Engineering methods, Tissue Scaffolds chemistry

Abstract

Objective: Electrospinning is a promising technology that provides biodegradable nanofiber scaffolds for cardiovascular tissue engineering. However, success with these materials has been limited, and the optimal combination of scaffold parameters for a tissue-engineered vascular graft (TEVG) remains elusive. The purpose of the present study is to evaluate the effect of bone marrow mononuclear cell (BM-MNC) seeding in electrospun scaffolds to support the rational design of optimized TEVGs., Methods: Nanofiber scaffolds were fabricated from co-electrospinning a solution of polyglycolic acid and a solution of poly(ι-lactide-co-ɛ-caprolactone) and characterized with scanning electron microscopy. Platelet activation and cell seeding efficiency were assessed by ATP secretion and DNA assays, respectively. Cell-free and BM-MNC seeded scaffolds were implanted in C57BL/6 mice (n = 15/group) as infrarenal inferior vena cava (IVC) interposition conduits. Animals were followed with serial ultrasonography for 6 months, after which grafts were harvested for evaluation of patency and neotissue formation by histology and immunohistochemistry (n = 10/group) and PCR (n = 5/group) analyses., Results: BM-MNC seeding of electrospun scaffolds prevented stenosis compared with unseeded scaffolds (seeded: 9/10 patent vs. unseeded: 1/10 patent, p = 0.0003). Seeded vascular grafts demonstrated concentric laminated smooth muscle cells, a confluent endothelial monolayer, and a collagen-rich extracellular matrix. Platelet-derived ATP, a marker of platelet activation, was significantly reduced after incubating thrombin-activated platelets in the presence of seeded scaffolds compared with unseeded scaffolds (p < 0.0001). In addition, reduced macrophage infiltration and a higher M2 macrophage percentage were observed in seeded grafts., Conclusions: The beneficial effects of BM-MNC seeding apply to electrospun TEVG scaffolds by attenuating stenosis through the regulation of platelet activation and inflammatory macrophage function, leading to well-organized neotissue formation. BM-MNC seeding is a valuable technique that can be used in the rational design of optimal TEVG scaffolds.

Published

2018

12. Biomaterial-Free Three-Dimensional Bioprinting of Cardiac Tissue using Human Induced Pluripotent Stem Cell Derived Cardiomyocytes.

Author

Ong CS, Fukunishi T, Zhang H, Huang CY, Nashed A, Blazeski A, DiSilvestre D, Vricella L, Conte J, Tung L, Tomaselli GF, and Hibino N

Subjects

Animals, Cell Differentiation, Cells, Cultured, Electrophysiological Phenomena, Endothelial Cells, Fibroblasts cytology, Fibroblasts metabolism, Myocardium cytology, Myocardium metabolism, Rats, Spheroids, Cellular, Tissue Transplantation, Biocompatible Materials chemistry, Bioprinting, Induced Pluripotent Stem Cells cytology, Myocytes, Cardiac cytology, Myocytes, Cardiac physiology, Printing, Three-Dimensional, Tissue Engineering, Tissue Scaffolds

Abstract

We have developed a novel method to deliver stem cells using 3D bioprinted cardiac patches, free of biomaterials. Human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs), fibroblasts (FB) and endothelial cells (EC) were aggregated to create mixed cell spheroids. Cardiac patches were created from spheroids (CM:FB:EC = 70:15:15, 70:0:30, 45:40:15) using a 3D bioprinter. Cardiac patches were analyzed with light and video microscopy, immunohistochemistry, immunofluorescence, cell viability assays and optical electrical mapping. Cardiac tissue patches of all cell ratios beat spontaneously after 3D bioprinting. Patches exhibited ventricular-like action potential waveforms and uniform electrical conduction throughout the patch. Conduction velocities were higher and action potential durations were significantly longer in patches containing a lower percentage of FBs. Immunohistochemistry revealed staining for CM, FB and EC markers, with rudimentary CD31+ blood vessel formation. Immunofluorescence revealed the presence of Cx43, the main cardiac gap junction protein, localized to cell-cell borders. In vivo implantation suggests vascularization of 3D bioprinted cardiac patches with engraftment into native rat myocardium. This constitutes a significant step towards a new generation of stem cell-based treatment for heart failure.

Published

2017

13. Creation of Cardiac Tissue Exhibiting Mechanical Integration of Spheroids Using 3D Bioprinting.

Author

Ong CS, Fukunishi T, Nashed A, Blazeski A, Zhang H, Hardy S, DiSilvestre D, Vricella L, Conte J, Tung L, Tomaselli G, and Hibino N

Subjects

Humans, Myocytes, Cardiac metabolism, Spheroids, Cellular metabolism, Bioprinting methods, Myocytes, Cardiac cytology, Spheroids, Cellular cytology, Tissue Engineering methods

Abstract

This protocol describes 3D bioprinting of cardiac tissue without the use of biomaterials, using only cells. Cardiomyocytes, endothelial cells and fibroblasts are first isolated, counted and mixed at desired cell ratios. They are co-cultured in individual wells in ultra-low attachment 96-well plates. Within 3 days, beating spheroids form. These spheroids are then picked up by a nozzle using vacuum suction and assembled on a needle array using a 3D bioprinter. The spheroids are then allowed to fuse on the needle array. Three days after 3D bioprinting, the spheroids are removed as an intact patch, which is already spontaneously beating. 3D bioprinted cardiac patches exhibit mechanical integration of component spheroids and are highly promising in cardiac tissue regeneration and as 3D models of heart disease.

Published

2017

14. Tissue engineered vascular grafts: current state of the field.

Author

Ong CS, Zhou X, Huang CY, Fukunishi T, Zhang H, and Hibino N

Subjects

Biomimetic Materials, Humans, Absorbable Implants, Blood Vessel Prosthesis, Tissue Engineering methods, Tissue Scaffolds

Abstract

Introduction: Conventional synthetic vascular grafts are limited by the inability to remodel, as well as issues of patency at smaller diameters. Tissue-engineered vascular grafts (TEVGs), constructed from biologically active cells and biodegradable scaffolds have the potential to overcome these limitations, and provide growth capacity and self-repair. Areas covered: This article outlines the TEVG design, biodegradable scaffolds, TEVG fabrication methods, cell seeding, drug delivery, strategies to reduce wait times, clinical trials, as well as a 5-year view with expert commentary. Expert commentary: TEVG technology has progressed significantly with advances in scaffold material and design, graft design, cell seeding and drug delivery. Strategies have been put in place to reduce wait times and improve 'off-the-shelf' capability of TEVGs. More recently, clinical trials have been conducted to investigate the clinical applications of TEVGs.

Published

2017

15. Preclinical study of patient-specific cell-free nanofiber tissue-engineered vascular grafts using 3-dimensional printing in a sheep model.

Author

Fukunishi T, Best CA, Sugiura T, Opfermann J, Ong CS, Shinoka T, Breuer CK, Krieger A, Johnson J, and Hibino N

Subjects

Animals, Computed Tomography Angiography, Endothelial Cells metabolism, Endothelial Cells pathology, Extracellular Matrix metabolism, Extracellular Matrix pathology, Macrophages metabolism, Macrophages pathology, Models, Animal, Myocytes, Smooth Muscle metabolism, Myocytes, Smooth Muscle pathology, Neointima, Phlebography methods, Sheep, Domestic, Time Factors, Vascular Patency, Vascular Remodeling, Vena Cava, Inferior metabolism, Vena Cava, Inferior pathology, Vena Cava, Inferior physiopathology, Venous Pressure, Blood Vessel Prosthesis, Blood Vessel Prosthesis Implantation instrumentation, Computer-Aided Design, Nanostructures, Nanotechnology methods, Printing, Three-Dimensional, Prosthesis Design, Tissue Engineering methods, Vena Cava, Inferior surgery

Abstract

Background: Tissue-engineered vascular grafts (TEVGs) offer potential to overcome limitations of current approaches for reconstruction in congenital heart disease by providing biodegradable scaffolds on which autologous cells proliferate and provide physiologic functionality. However, current TEVGs do not address the diverse anatomic requirements of individual patients. This study explores the feasibility of creating patient-specific TEVGs by combining 3-dimensional (3D) printing and electrospinning technology., Methods: An electrospinning mandrel was 3D-printed after computer-aided design based on preoperative imaging of the ovine thoracic inferior vena cava (IVC). TEVG scaffolds were then electrospun around the 3D-printed mandrel. Six patient-specific TEVGs were implanted as cell-free IVC interposition conduits in a sheep model and explanted after 6 months for histologic, biochemical, and biomechanical evaluation., Results: All sheep survived without complications, and all grafts were patent without aneurysm formation or ectopic calcification. Serial angiography revealed significant decreases in TEVG pressure gradients between 3 and 6 months as the grafts remodeled. At explant, the nanofiber scaffold was nearly completely resorbed and the TEVG showed similar mechanical properties to that of native IVC. Histological analysis demonstrated an organized smooth muscle cell layer, extracellular matrix deposition, and endothelialization. No significant difference in elastin and collagen content between the TEVG and native IVC was identified. There was a significant positive correlation between wall thickness and CD68 + macrophage infiltration into the TEVG., Conclusions: Creation of patient-specific nanofiber TEVGs by combining electrospinning and 3D printing is a feasible technology as future clinical option. Further preclinical studies involving more complex anatomical shapes are warranted., (Copyright © 2016. Published by Elsevier Inc.)

Published

2017

16. Tissue-Engineered Small Diameter Arterial Vascular Grafts from Cell-Free Nanofiber PCL/Chitosan Scaffolds in a Sheep Model.

Author

Fukunishi T, Best CA, Sugiura T, Shoji T, Yi T, Udelsman B, Ohst D, Ong CS, Zhang H, Shinoka T, Breuer CK, Johnson J, and Hibino N

Subjects

Animals, Cell-Free System, Extracellular Matrix, Mice, Microscopy, Electron, Scanning, Models, Animal, Muscle, Smooth, Vascular cytology, Sheep, Blood Vessel Prosthesis, Chitosan chemistry, Nanofibers chemistry, Polyesters chemistry, Tissue Engineering

Abstract

Tissue engineered vascular grafts (TEVGs) have the potential to overcome the issues faced by existing small diameter prosthetic grafts by providing a biodegradable scaffold where the patient's own cells can engraft and form functional neotissue. However, applying classical approaches to create arterial TEVGs using slow degrading materials with supraphysiological mechanical properties, typically results in limited host cell infiltration, poor remodeling, stenosis, and calcification. The purpose of this study is to evaluate the feasibility of novel small diameter arterial TEVGs created using fast degrading material. A 1.0mm and 5.0mm diameter TEVGs were fabricated with electrospun polycaprolactone (PCL) and chitosan (CS) blend nanofibers. The 1.0mm TEVGs were implanted in mice (n = 3) as an unseeded infrarenal abdominal aorta interposition conduit., The 5.0mm TEVGs were implanted in sheep (n = 6) as an unseeded carotid artery (CA) interposition conduit. Mice were followed with ultrasound and sacrificed at 6 months. All 1.0mm TEVGs remained patent without evidence of thrombosis or aneurysm formation. Based on small animal outcomes, sheep were followed with ultrasound and sacrificed at 6 months for histological and mechanical analysis. There was no aneurysm formation or calcification in the TEVGs. 4 out of 6 grafts (67%) were patent. After 6 months in vivo, 9.1 ± 5.4% remained of the original scaffold. Histological analysis of patent grafts demonstrated deposition of extracellular matrix constituents including elastin and collagen production, as well as endothelialization and organized contractile smooth muscle cells, similar to that of native CA. The mechanical properties of TEVGs were comparable to native CA. There was a significant positive correlation between TEVG wall thickness and CD68+ macrophage infiltration into the scaffold (R2 = 0.95, p = 0.001). The fast degradation of CS in our novel TEVG promoted excellent cellular infiltration and neotissue formation without calcification or aneurysm. Modulating host macrophage infiltration into the scaffold is a key to reducing excessive neotissue formation and stenosis.

Published

2016

17. In Vitro Endothelialization of Biodegradable Vascular Grafts Via Endothelial Progenitor Cell Seeding and Maturation in a Tubular Perfusion System Bioreactor.

Author

Melchiorri AJ, Bracaglia LG, Kimerer LK, Hibino N, and Fisher JP

Subjects

Cell Proliferation, Cells, Cultured, Humans, Stress, Mechanical, Bioreactors, Blood Vessel Prosthesis, Cell Differentiation, Endothelial Progenitor Cells cytology, Endothelium, Vascular cytology, Tissue Engineering methods

Abstract

A critical challenge to the success of biodegradable vascular grafts is the establishment of a healthy endothelium. To establish this monolayer of endothelial cells (ECs), a variety of techniques have been developed, including cell seeding. Vascular grafts may be seeded with relevant cell types and allowed to mature before implantation. Due to the low proliferative ability of adult ECs and issues with donor site morbidity, there has been increasing interest in using endothelial progenitor cells (EPCs) for vascular healing procedures. In this work, we combined the proliferative and differentiation capabilities of a commercial cell line of early EPCs with an established bioreactor system to support the maturation of cell-seeded vascular grafts. All components of the vascular graft and bioreactor setup are commercially available and allow for complete customization of the scaffold and culturing system. This bioreactor setup enables the control of flow through the graft, imparting fluid shear stress on EPCs and affecting cellular proliferation and differentiation. Grafts cultured with EPCs in the bioreactor system demonstrated greatly increased cell populations and neotissue formation compared with grafts seeded and cultured in a static system. Increased expression of markers for mature endothelial tissues were also observed in bioreactor-cultured EPC-seeded grafts. These findings suggest the distinct advantages of a customizable bioreactor setup for the proliferation and maturation of EPCs. Such a strategy may be beneficial for utilizing EPCs in vascular tissue engineering applications.

Published

2016

18. Rational design of an improved tissue-engineered vascular graft: determining the optimal cell dose and incubation time.

Author

Lee YU, Mahler N, Best CA, Tara S, Sugiura T, Lee AY, Yi T, Hibino N, Shinoka T, and Breuer C

Subjects

Animals, Cell Culture Techniques, Cells, Cultured, Female, Humans, Mice, Blood Vessel Prosthesis, Bone Marrow Cells cytology, Bone Marrow Cells metabolism, Tissue Engineering methods

Abstract

Aim: We investigated the effect of cell seeding dose and incubation time on tissue-engineered vascular graft (TEVG) patency., Materials & Methods: Various doses of bone marrow-derived mononuclear cells (BM-MNCs) were seeded onto TEVGs, incubated for 0 or 12 h, and implanted in C57BL/6 mice. Different doses of human BM-MNCs were seeded onto TEVGs and measured for cell attachment., Results: The incubation time showed no significant effect on TEVG patency. However, TEVG patency was significantly increased in a dose-dependent manner. In the human graft, more bone marrow used for seeding resulted in increased cell attachment in a dose-dependent manner., Conclusion: Increasing the BM-MNC dose and reducing incubation time is a viable strategy for improving the performance and utility of the graft., Competing Interests: Financial & competing interests disclosure This research was supported by R01-HL098228 (C Breuer). C Breuer and T Shinoka have received grant support from the Pall Corporation and Gunze Limited. All authors have read the journals policy on conflict of interest. C Breuer and T Shinoka have patents related to the TEVG. The authors have no other relevant affiliations or financial involvement with any organization or entity with a financial interest in or financial conflict with the subject matter or materials discussed in the manuscript apart from those disclosed. No writing assistance was utilized in the production of this manuscript.

Published

2016

19. Effect of cell seeding on neotissue formation in a tissue engineered trachea.

Author

Clark ES, Best C, Onwuka E, Sugiura T, Mahler N, Bolon B, Niehaus A, James I, Hibino N, Shinoka T, Johnson J, and Breuer CK

Subjects

Animals, Cells, Cultured, Nanofibers, Polymers, Sheep, Tissue Engineering instrumentation, Vacuum, Monocytes transplantation, Tissue Engineering methods, Tissue Scaffolds, Trachea growth & development

Abstract

Background: Surgical management of long segment tracheal disease is limited by a paucity of donor tissue and poor performance of synthetic materials. A potential solution is the development of a tissue-engineered tracheal graft (TETG) which promises an autologous airway conduit with growth capacity., Methods: We created a TETG by vacuum seeding bone marrow-derived mononuclear cells (BM-MNCs) on a polymeric nanofiber scaffold. First, we evaluated the role of scaffold porosity on cell seeding efficiency in vitro. We then determined the effect of cell seeding on graft performance in vivo using an ovine model., Results: Seeding efficiency of normal porosity (NP) grafts was significantly increased when compared to high porosity (HP) grafts (NP: 360.3 ± 69.19 × 10(3) cells/mm(2); HP: 133.7 ± 22.73 × 10(3) cells/mm(2); p<0.004). Lambs received unseeded (n=2) or seeded (n=3) NP scaffolds as tracheal interposition grafts for 6 weeks. Three animals were terminated early owing to respiratory complications (n=2 unseeded, n=1 seeded). Seeded TETG explants demonstrated wound healing, epithelial migration, and delayed stenosis when compared to their unseeded counterparts., Conclusion: Vacuum seeding BM-MNCs on nanofiber scaffolds for immediate implantation as tracheal interposition grafts is a viable approach to generate TETGs, but further preclinical research is warranted before advocating this technology for clinical application., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

20. TGFβR1 inhibition blocks the formation of stenosis in tissue-engineered vascular grafts.

Author

Duncan DR, Chen PY, Patterson JT, Lee YU, Hibino N, Cleary M, Naito Y, Yi T, Gilliland T, Kurobe H, Church SN, Shinoka T, Fahmy TM, Simons M, and Breuer CK

Subjects

Animals, Benzamides pharmacology, Constriction, Pathologic pathology, Dioxoles pharmacology, Humans, Mice, Mice, Inbred C57BL, Polyglycolic Acid administration & dosage, Receptor, Transforming Growth Factor-beta Type I, Benzamides therapeutic use, Blood Vessel Prosthesis trends, Constriction, Pathologic prevention & control, Dioxoles therapeutic use, Protein Serine-Threonine Kinases antagonists & inhibitors, Receptors, Transforming Growth Factor beta antagonists & inhibitors, Tissue Engineering methods

Published

2015

21. Vessel bioengineering.

Author

Tara S, Rocco KA, Hibino N, Sugiura T, Kurobe H, Breuer CK, and Shinoka T

Subjects

Animals, Heart Defects, Congenital physiopathology, Humans, Tissue Engineering trends, Absorbable Implants, Blood Vessel Prosthesis, Heart Defects, Congenital therapy, Tissue Engineering methods, Tissue Scaffolds

Abstract

The development of vascular bioengineering has led to a variety of novel treatment strategies for patients with cardiovascular disease. Notably, combining biodegradable scaffolds with autologous cell seeding to create tissue-engineered vascular grafts (TEVG) allows for in situ formation of organized neovascular tissue and we have demonstrated the clinical viability of this technique in patients with congenital heart defects. The role of the scaffold is to provide a temporary 3-dimensional structure for cells, but applying TEVG strategy to the arterial system requires scaffolds that can also endure arterial pressure. Both biodegradable synthetic polymers and extracellular matrix-based natural materials can be used to generate arterial scaffolds that satisfy these requirements. Furthermore, the role of specific cell types in tissue remodeling is crucial and as a result many different cell sources, from matured somatic cells to stem cells, are now used in a variety of arterial TEVG techniques. However, despite great progress in the field over the past decade, clinical effectiveness of small-diameter arterial TEVG (<6mm) has remained elusive. To achieve successful translation of this complex multidisciplinary technology to the clinic, active participation of biologists, engineers, and clinicians is required.

Published

2014

22. Strategies and techniques to enhance the in situ endothelialization of small-diameter biodegradable polymeric vascular grafts.

Author

Melchiorri AJ, Hibino N, and Fisher JP

Subjects

Animals, Endothelium, Vascular metabolism, Humans, Absorbable Implants, Blood Vessel Prosthesis, Endothelium, Vascular cytology, Tissue Engineering methods

Abstract

Due to the lack of success in small-diameter (<6 mm) prosthetic vascular grafts, a variety of strategies have evolved utilizing a tissue-engineering approach. Much of this work has focused on enhancing the endothelialization of these grafts. A healthy, confluent endothelial layer provides dynamic control over homeo-stasis, influencing and preventing thrombosis and smooth muscle cell proliferation that can lead to intimal hyperplasia. Strategies to improve endothelialization of biodegradable polymeric grafts have encompassed both chemical and physical modifications to graft surfaces, many focusing on the recruitment of endothelial and endothelial progenitor cells. This review aims to provide a compilation of current and developing strategies that utilize in situ endothelialization to improve vascular graft outcomes, providing a context for the future directions of vascular tissue-engineering strategies that do not require preprocedural cell seeding.

Published

2013

23. Evaluation of the use of an induced puripotent stem cell sheet for the construction of tissue-engineered vascular grafts.

Author

Hibino N, Duncan DR, Nalbandian A, Yi T, Qyang Y, Shinoka T, and Breuer CK

Subjects

Animals, Apoptosis, Biomarkers metabolism, Cell Differentiation, Cell Line, Female, Immunohistochemistry, In Situ Hybridization, Fluorescence, Induced Pluripotent Stem Cells metabolism, Lactic Acid chemistry, Male, Mice, Mice, SCID, Paracrine Communication, Polyesters chemistry, Polyglycolic Acid chemistry, Polymers chemistry, Prosthesis Design, Real-Time Polymerase Chain Reaction, Time Factors, Tissue Scaffolds, Ultrasonography, Vena Cava, Inferior diagnostic imaging, Vena Cava, Inferior metabolism, Vena Cava, Inferior pathology, Y Chromosome metabolism, Blood Vessel Prosthesis, Blood Vessel Prosthesis Implantation instrumentation, Induced Pluripotent Stem Cells transplantation, Tissue Engineering methods, Vena Cava, Inferior surgery

Abstract

Objective: The development of a living, tissue-engineered vascular graft (TEVG) holds great promise for advancing the field of cardiovascular surgery. However, the ultimate source and time needed to procure these cells remain problematic. Induced puripotent stem (iPS) cells have recently been developed and have the potential for creating a pluripotent cell line from a patient's own somatic cells. In the present study, we evaluated the use of a sheet created from iPS cell-derived vascular cells as a potential source for the construction of TEVG., Methods: Male mouse iPS cells were differentiated into embryoid bodies using the hanging-drop method. Cell differentiation was confirmed by a decrease in the proportion of SSEA-1-positive cells over time using fluorescence-activated cell sorting. The expression of endothelial cell and smooth muscle cell markers was detected using real-time polymerase chain reaction (PCR). The differentiated iPS cell sheet was made using temperature-responsive dishes and then seeded onto a biodegradable scaffold composed of polyglycolic acid-poly-l-lactide and poly(l-lactide-co-ε-caprolactone) with a diameter of 0.8 mm. These scaffolds were implanted as interposition grafts in the inferior vena cava of female severe combined immunodeficiency/beige mice (n = 15). Graft function was serially monitored using ultrasonography. The grafts were analyzed at 1, 4, and 10 weeks with histologic examination and immunohistochemistry. The behavior of seeded differentiated iPS cells was tracked using Y-chromosome fluorescent in situ hybridization and SRY real-time PCR., Results: All mice survived without thrombosis, aneurysm formation, graft rupture, or calcification. PCR evaluation of iPS cell sheets in vitro demonstrated increased expression of endothelial cell markers. Histologic evaluation of the grafts demonstrated endothelialization with von Willebrand factor and an inner layer with smooth muscle actin- and calponin-positive cells at 10 weeks. The number of seeded differentiated iPS cells was found to decrease over time using real-time PCR (42.2% at 1 week, 10.4% at 4 weeks, 9.8% at 10 weeks). A fraction of the iPS cells were found to be Y-chromosome fluorescent positive at 1 week. No iPS cells were found to co-localize with von Willebrand factor or smooth muscle actin-positive cells at 10 weeks., Conclusions: Differentiated iPS cells offer an alternative cell source for constructing TEVG. Seeded iPS cells exerted a paracrine effect to induce neotissue formation in the acute phase and were reduced in number by apoptosis at later time points. Sheet seeding of our TEVG represents a viable mode of iPS cell delivery over time., (Copyright © 2012. Published by Mosby, Inc.)

Published

2012

24. Characterization of the natural history of extracellular matrix production in tissue-engineered vascular grafts during neovessel formation.

Author

Naito Y, Williams-Fritze M, Duncan DR, Church SN, Hibino N, Madri JA, Humphrey JD, Shinoka T, and Breuer CK

Subjects

Animals, Bone Marrow Cells cytology, Collagen metabolism, Elastin metabolism, Female, Lactic Acid chemistry, Male, Matrix Metalloproteinases metabolism, Mice, Mice, Inbred C57BL, Polyesters chemistry, Polyglycolic Acid chemistry, Polymers chemistry, Tissue Scaffolds chemistry, Blood Vessel Prosthesis, Extracellular Matrix metabolism, Tissue Engineering methods, Vascular Grafting, Vena Cava, Inferior surgery

Abstract

Background: The extracellular matrix (ECM) is a critical determinant of neovessel integrity., Materials and Methods: Thirty-six (polyglycolic acid + polycaprolactone and poly lactic acid) tissue-engineered vascular grafts seeded with syngeneic bone marrow mononuclear cells were implanted as inferior vena cava interposition grafts in C57BL/6 mice. Specimens were characterized using immunohistochemical staining and qPCR for representative ECM components in addition to matrix metalloproteinases (MMPs). Total collagen, elastin, and glycosaminoglycan (GAG) contents were determined. MMP activity was measured using zymography., Results: Collagen production on histology demonstrated an initial increase in type III at 1 week followed by type I production at 2 weeks and type IV at 4 weeks. Gene expression of both type I and type III peaked at 2 weeks, whereas type IV continued to increase over the 4-week period. Histology demonstrated fibrillin-1 deposition at 1 week followed by elastin production at 4 weeks. Elastin gene expression significantly increased at 4 weeks, whereas fibrillin-1 decreased at 4 weeks. GAG demonstrated abundant production at each time point on histology. Gene expression of decorin significantly increased at 4 weeks, whereas versican decreased over time. Biochemical analysis showed that total collagen production was greatest at 2 weeks, and there was a significant increase in elastin and GAG production at 4 weeks. Histological characterization of MMPs showed abundant production of MMP-2 at each time point, while MMP-9 decreased over the 4-week period. Gene expression of MMP-2 significantly increased at 4 weeks, whereas MMP-9 significantly decreased at 4 weeks., Conclusions: ECM production during neovessel formation is characterized by early ECM deposition followed by extensive remodeling., (Copyright © 2011 S. Karger AG, Basel.)

Published

2012

25. Determining the fate of seeded cells in venous tissue-engineered vascular grafts using serial MRI.

Author

Harrington JK, Chahboune H, Criscione JM, Li AY, Hibino N, Yi T, Villalona GA, Kobsa S, Meijas D, Duncan DR, Devine L, Papademetri X, Shin'oka T, Fahmy TM, and Breuer CK

Subjects

Animals, Cell Line, Cell Survival, Macrophages metabolism, Magnetic Resonance Imaging, Magnetite Nanoparticles, Mice, Mice, SCID, Tissue Scaffolds, Vena Cava, Inferior cytology, Vena Cava, Inferior surgery, Blood Vessel Prosthesis, Macrophages cytology, Tissue Engineering

Abstract

A major limitation of tissue engineering research is the lack of noninvasive monitoring techniques for observations of dynamic changes in single tissue-engineered constructs. We use cellular magnetic resonance imaging (MRI) to track the fate of cells seeded onto functional tissue-engineered vascular grafts (TEVGs) through serial imaging. After in vitro optimization, murine macrophages were labeled with ultrasmall superparamagnetic iron oxide (USPIO) nanoparticles and seeded onto scaffolds that were surgically implanted as inferior vena cava interposition grafts in SCID/bg mice. Serial MRI showed the transverse relaxation times (T(2)) were significantly lower immediately following implantation of USPIO-labeled scaffolds (T(2) = 44 ± 6.8 vs. 71 ± 10.2 ms) but increased rapidly at 2 h to values identical to control implants seeded with unlabeled macrophages (T(2) = 63 ± 12 vs. 63 ± 14 ms). This strongly indicates the rapid loss of seeded cells from the scaffolds, a finding verified using Prussian blue staining for iron containing macrophages on explanted TEVGs. Our results support a novel paradigm where seeded cells are rapidly lost from implanted scaffolds instead of developing into cells of the neovessel, as traditionally thought. Our findings confirm and validate this paradigm shift while demonstrating the first successful application of noninvasive MRI for serial study of cellular-level processes in tissue engineering.

Published

2011

26. Comparison of human bone marrow mononuclear cell isolation methods for creating tissue-engineered vascular grafts: novel filter system versus traditional density centrifugation method.

Author

Hibino N, Nalbandian A, Devine L, Martinez RS, McGillicuddy E, Yi T, Karandish S, Ortolano GA, Shin'oka T, Snyder E, and Breuer CK

Subjects

Animals, Blood Vessels diagnostic imaging, Blood Vessels pathology, Flow Cytometry, Humans, Mice, Mice, SCID, Time Factors, Tomography, X-Ray Computed, Ultrasonography, Blood Vessel Prosthesis, Bone Marrow Cells cytology, Cell Separation methods, Centrifugation, Density Gradient methods, Filtration instrumentation, Leukocytes, Mononuclear cytology, Tissue Engineering methods

Abstract

Introduction: We created the first tissue-engineered vascular graft (TEVG) to be successfully used in humans. The TEVG is made by seeding autologous bone marrow-derived mononuclear cells (BM-MNCs) onto a biodegradable tubular scaffold fabricated from polyglycolic-acid mesh coated with a 50:50 copolymer of poly-L-lactide and-ɛ-caprolactone. In the initial clinical study, the BM-MNCs were isolated using a Ficoll density centrifugation method. Use of this cell isolation technique is problematic in that it is performed using an open system and therefore is susceptible to contamination. As a first step toward creating a closed system for assembling a TEVG, we evaluated the use of a filter-based method for isolating BM-MNCs and compared it to density centrifugation in Ficoll., Methods: BM-MNCs were isolated from human BM using density centrifugation in Ficoll or a filter-based method. BM-MNCs were seeded onto biodegradable tubular scaffold and incubated for 24 h before implantation. The TEVG were implanted as inferior vena cava interposition grafts in SCID/bg mice (n=24) using microsurgical technique. Grafts were followed with ultrasonography and computed tomography-angiography. Ten weeks after implantation the TEVG were explanted and examined using histology and immunohistochemistry., Results: Both methods isolated similar number of cells (Ficoll: 8.5±6.6×10(6)/mL, Filter: 6.6±3.5×10(6)/mL; p=0.686) with similar viability as assayed using fluorescence-activated cell sorting (FACS) (Ficoll: 97.0%±1.5%, Filter: 95.9%±3.0%; p=0.339). FACS analysis demonstrated that the fraction of lymphocytes and monocytes to total cells was lower in the filter group (CD4 in Ficoll: 8.9%±1.1%, CD4 in Filter: 3.5%±0.8%; p=0.002, CD8 in Ficoll: 9.4%±2.1%, CD8 in Filter: 3.9%±1.4%; p=0.021, Monocyte in Ficoll: 6.9%±1.0%, Monocyte in Filter: 2.7%±1.0%; p=0.008), consistent with granulocyte contamination (Ficoll: 46.6±2.7×10(6)/mL, Filter: 58.1±5.2×10(6)/mL; p<0.001). The ratio of stem cells to BM-MNCs was comparable between groups. There were no statistically significant differences with regard to TEVG patency and morphology between groups. Both methods of cell isolation produced neovessels with similar histology., Conclusion: Filter-based BM-MNC isolation is comparable to BM-MNC isolation using density centrifugation in Ficoll for TEVG assembly. The filter-based cell isolation technique has the added advantage of the potential to create a closed disposable system., (© Mary Ann Liebert, Inc.)

Published

2011

27. Development of an operator-independent method for seeding tissue-engineered vascular grafts.

Author

Udelsman B, Hibino N, Villalona GA, McGillicuddy E, Nieponice A, Sakamoto Y, Matsuda S, Vorp DA, Shinoka T, and Breuer CK

Subjects

Cell Adhesion, Cell Count, Cell Culture Techniques, Cell Survival, Humans, Perfusion, Tissue Scaffolds, Vacuum, Leukocytes, Mononuclear cytology, Tissue Engineering methods, Vascular Grafting methods

Abstract

The manual seeding of cells onto a biodegradable scaffold by pipetting is an effective method of cell seeding. However, the widespread use and ultimate clinical utility of this technique is limited by operator variability. This study was conducted to evaluate an operator-independent vacuum-seeding method for use in an upcoming clinical trial. Using bone marrow-derived mononuclear cells, we achieved seeding comparable to manually seeded scaffolds in terms of cellular attachment, distribution, and viability in vacuum-seeded grafts at vacuum pressures of -25 to -50 mmHg. In conclusion, we describe an operator-independent seeding method for use in the clinical setting.

Published

2011

28. Vascular tissue engineering: towards the next generation vascular grafts.

Author

Naito Y, Shinoka T, Duncan D, Hibino N, Solomon D, Cleary M, Rathore A, Fein C, Church S, and Breuer C

Subjects

Animals, Blood Vessel Prosthesis Implantation trends, Graft Occlusion, Vascular epidemiology, Humans, Tissue Engineering trends, Tissue Scaffolds trends, Blood Vessel Prosthesis trends, Cardiovascular Diseases surgery, Tissue Engineering methods

Abstract

The application of tissue engineering technology to cardiovascular surgery holds great promise for improving outcomes in patients with cardiovascular diseases. Currently used synthetic vascular grafts have several limitations including thrombogenicity, increased risk of infection, and lack of growth potential. We have completed the first clinical trial evaluating the feasibility of using tissue engineered vascular grafts (TEVG) created by seeding autologous bone marrow-derived mononuclear cells (BM-MNC) onto biodegradable tubular scaffolds. Despite an excellent safety profile, data from the clinical trial suggest that the primary graft related complication of the TEVG is stenosis, affecting approximately 16% of grafts within the first seven years after implantation. Continued investigation into the cellular and molecular mechanisms underlying vascular neotissue formation will improve our basic understanding and provide insights that will enable the rationale design of second generation TEVG., (Published by Elsevier B.V.)

Published

2011

29. Tissue-engineered vascular grafts: does cell seeding matter?

Author

Mirensky TL, Hibino N, Sawh-Martinez RF, Yi T, Villalona G, Shinoka T, and Breuer CK

Subjects

Animals, Cell Proliferation, Disease Models, Animal, Female, Graft Survival, Humans, Immunohistochemistry, Mice, Mice, SCID, Prosthesis Design, Vascular Patency physiology, Vena Cava, Inferior cytology, Blood Vessel Prosthesis, Monocytes cytology, Tissue Engineering, Tissue Scaffolds, Vena Cava, Inferior transplantation

Abstract

Purpose: Use of tissue-engineered vascular grafts (TEVGs) in the repair of congenital heart defects provides growth and remodeling potential. Little is known about the mechanisms involved in neovessel formation. We sought to define the role of seeded monocytes derived from bone marrow mononuclear cells (BM-MNCs) on neovessel formation., Methods: Small diameter biodegradable tubular scaffolds were constructed. Scaffolds were seeded with the entire population of BM-MNC (n = 15), BM-MNC excluding monocytes (n = 15), or only monocytes (n = 15) and implanted as infrarenal inferior vena cava (IVC) interposition grafts into severe combined immunodeficiency/bg mice. Grafts were evaluated at 1 week, 10 weeks, or 6 months via ultrasonography and microcomputed tomography, as well as by histologic and immunohistochemical techniques., Results: All grafts remained patent without stenosis or aneurysm formation. Neovessels contained a luminal endothelial lining surrounded by concentric smooth muscle cell layer and collagen similar to that seen in the native mouse IVC. Graft diameters differed significantly between those scaffolds seeded with only monocytes (1.022 +/- 0.155 mm) and those seeded without monocytes (0.771 +/- 0.121 mm; P = .021) at 6 months., Conclusions: Monocytes may play a role in maintaining graft patency. Incorporation of such findings into the development of second-generation TEVGs will promote graft patency and success., (Copyright 2010 Elsevier Inc. All rights reserved.)

Published

2010

30. Cell-seeding techniques in vascular tissue engineering.

Author

Villalona GA, Udelsman B, Duncan DR, McGillicuddy E, Sawh-Martinez RF, Hibino N, Painter C, Mirensky T, Erickson B, Shinoka T, and Breuer CK

Subjects

Blood Vessel Prosthesis, Blood Vessels cytology, Bone Marrow Transplantation methods, Cell Culture Techniques instrumentation, Cell Culture Techniques methods, Endothelial Cells transplantation, Guided Tissue Regeneration instrumentation, Guided Tissue Regeneration methods, Humans, Models, Biological, Myocytes, Smooth Muscle cytology, Myocytes, Smooth Muscle transplantation, Tissue Engineering instrumentation, Blood Vessels physiology, Cell Transplantation methods, Tissue Engineering methods, Tissue Scaffolds

Abstract

Previous studies have demonstrated the benefits of cell seeding in the construction of tissue-engineered vascular grafts (TEVG). However, seeding methods are diverse and no method is clearly superior in either promoting seeding efficiency or improving long-term graft function. As we head into an era during which a variety of different TEVG are under investigation in clinical trials around the world, it is important to consider the regulatory issues surrounding the translation of these technologies. In this review, we summarize important advances in the field of vascular tissue engineering, with particular attention on cell-seeding techniques for TEVG development and special emphasis placed on regulatory issues concerning the clinical translation of these various methods.

Published

2010

31. Tissue-engineered vascular grafts transform into mature blood vessels via an inflammation-mediated process of vascular remodeling.

Author

Roh JD, Sawh-Martinez R, Brennan MP, Jay SM, Devine L, Rao DA, Yi T, Mirensky TL, Nalbandian A, Udelsman B, Hibino N, Shinoka T, Saltzman WM, Snyder E, Kyriakides TR, Pober JS, and Breuer CK

Subjects

Animals, Blood Vessels metabolism, Blood Vessels pathology, Bone Marrow Cells cytology, Bone Marrow Cells metabolism, Bone Marrow Cells ultrastructure, Cell Culture Techniques, Cell Differentiation, Cells, Cultured, Chemokine CCL2 metabolism, Humans, Immunohistochemistry, Inflammation physiopathology, Mice, Mice, SCID, Microscopy, Electron, Scanning, Platelet Endothelial Cell Adhesion Molecule-1 metabolism, Tissue Scaffolds, Transplantation, Heterologous, Blood Vessel Prosthesis, Blood Vessel Prosthesis Implantation methods, Blood Vessels physiopathology, Tissue Engineering methods

Abstract

Biodegradable scaffolds seeded with bone marrow mononuclear cells (BMCs) are the earliest tissue-engineered vascular grafts (TEVGs) to be used clinically. These TEVGs transform into living blood vessels in vivo, with an endothelial cell (EC) lining invested by smooth muscle cells (SMCs); however, the process by which this occurs is unclear. To test if the seeded BMCs differentiate into the mature vascular cells of the neovessel, we implanted an immunodeficient mouse recipient with human BMC (hBMC)-seeded scaffolds. As in humans, TEVGs implanted in a mouse host as venous interposition grafts gradually transformed into living blood vessels over a 6-month time course. Seeded hBMCs, however, were no longer detectable within a few days of implantation. Instead, scaffolds were initially repopulated by mouse monocytes and subsequently repopulated by mouse SMCs and ECs. Seeded BMCs secreted significant amounts of monocyte chemoattractant protein-1 and increased early monocyte recruitment. These findings suggest TEVGs transform into functional neovessels via an inflammatory process of vascular remodeling.

Published

2010

32. Late-term results of tissue-engineered vascular grafts in humans.

Author

Hibino N, McGillicuddy E, Matsumura G, Ichihara Y, Naito Y, Breuer C, and Shinoka T

Subjects

Adolescent, Blood Vessel Prosthesis, Bone Marrow Cells, Child, Child, Preschool, Female, Humans, Infant, Lactic Acid therapeutic use, Magnetic Resonance Imaging, Male, Membranes, Artificial, Polyesters, Polymers therapeutic use, Pulmonary Artery surgery, Vascular Patency, Venae Cavae surgery, Heart Ventricles abnormalities, Tissue Engineering methods, Tissue Scaffolds

Abstract

Objective: The development of a tissue-engineered vascular graft with the ability to grow and remodel holds promise for advancing cardiac surgery. In 2001, we began a human trial evaluating these grafts in patients with single ventricle physiology. We report the late clinical and radiologic surveillance of a patient cohort that underwent implantation of tissue-engineered vascular grafts as extracardiac cavopulmonary conduits., Methods: Autologous bone marrow was obtained and the mononuclear cell component was collected. Mononuclear cells were seeded onto a biodegradable scaffold composed of polyglycolic acid and epsilon-caprolactone/L-lactide and implanted as extracardiac cavopulmonary conduits in patients with single ventricle physiology. Patients were followed up by postoperative clinic visits and by telephone. Additionally, ultrasonography, angiography, computed tomography, and magnetic resonance imaging were used for postoperative graft surveillance., Results: Twenty-five grafts were implanted (median patient age, 5.5 years). There was no graft-related mortality (mean follow-up, 5.8 years). There was no evidence of aneurysm formation, graft rupture, graft infection, or ectopic calcification. One patient had a partial mural thrombosis that was successfully treated with warfarin. Four patients had graft stenosis and underwent successful percutaneous angioplasty., Conclusion: Tissue-engineered vascular grafts can be used as conduits in patients with single ventricle physiology. Graft stenosis is the primary mode of graft failure. Further follow-up and investigation for the mechanism of stenosis are warranted., (Published by Mosby, Inc.)

Published

2010

33. Tissue-engineered arterial grafts: long-term results after implantation in a small animal model.

Author

Mirensky TL, Nelson GN, Brennan MP, Roh JD, Hibino N, Yi T, Shinoka T, and Breuer CK

Subjects

Animals, Cells, Cultured, Female, Humans, Mice, Mice, SCID, Models, Animal, Muscle, Smooth, Vascular, Myocytes, Smooth Muscle, Pilot Projects, Tissue Scaffolds, Blood Vessel Prosthesis, Blood Vessel Prosthesis Implantation, Tissue Engineering

Abstract

Background: Use of prosthetic vascular grafts in pediatric vascular surgical applications is limited because of risk of infection, poor durability, potential for thromboembolic complications, and lack of growth potential. Construction of an autologous neovessel using tissue engineering technology offers the potential to create an improved vascular conduit for use in pediatric vascular applications., Methods: Tissue-engineered vascular grafts were assembled from biodegradable tubular scaffolds fabricated from poly-L-lactic acid mesh coated with epsilon-caprolactone and L-lactide copolymer. Thirteen scaffolds were seeded with human aortic endothelial and smooth muscle cells and implanted as infrarenal aortic interposition grafts in SCID/bg mice. Grafts were analyzed at time-points ranging from 4 days to 1 year after implantation., Results: All grafts remained patent without evidence of thromboembolic complications, graft stenosis, or graft rupture as documented by serial ultrasound and computed tomographic angiogram, and confirmed histologically. All grafts demonstrated extensive remodeling leading to the development of well-circumscribed neovessels with an endothelial inner lining, neomedia containing smooth muscle cells and elastin, and a collagen-rich extracellular matrix., Conclusions: The development of second-generation tissue-engineered vascular grafts shows marked improvement over previous grafts and confirms feasibility of using tissue engineering technology to create an improved arterial conduit for use in pediatric vascular surgical applications.

Published

2009

34. Midterm clinical result of tissue-engineered vascular autografts seeded with autologous bone marrow cells.

Author

Shin'oka T, Matsumura G, Hibino N, Naito Y, Watanabe M, Konuma T, Sakamoto T, Nagatsu M, and Kurosawa H

Subjects

Adolescent, Adult, Child, Child, Preschool, Feasibility Studies, Female, Humans, Infant, Male, Time Factors, Blood Vessels, Bone Marrow Transplantation, Tissue Engineering methods, Vascular Diseases surgery

Abstract

Objective: Prosthetic and bioprosthetic materials currently in use lack growth potential and therefore must be repeatedly replaced in pediatric patients as they grow. Tissue engineering is a new discipline that offers the potential for creating replacement structures from autologous cells and biodegradable polymer scaffolds. In May 2000, we initiated clinical application of tissue-engineered vascular grafts seeded with cultured cells. However, cell culturing is time-consuming, and xenoserum must be used. To overcome these disadvantages, we began to use bone marrow cells, readily available on the day of surgery, as a cell source. The aim of the study was to assess the safety and feasibility of this technique for creating vascular tissue under low-pressure systems such as pulmonary artery or venous pressure., Methods: Since September 2001, tissue-engineered grafts seeded with autologous bone marrow cells have been implanted in 42 patients. The patients or their parents were fully informed and had given consent to the procedure. A 5-mL/kg specimen of bone marrow was aspirated with the patient under general anesthesia before the skin incision. The polymer tube serving as a scaffold for the cells was composed of a copolymer of l -lactide and -caprolactone (50:50). This copolymer is degraded by hydrolysis. The matrix is more than 80% porous, and the diameter of each pore is 20 to 100 microm. Polyglycolic acid woven fabric with a thickness of 0.5 mm was used for reinforcement. Twenty-three tissue-engineered conduits (grafts for extracardiac total cavopulmonary connection) and 19 tissue-engineered patches were used for the repair of congenital heart defects. The patients' ages ranged from 1 to 24 years (median 5.5 years). All patients underwent a catheterization study, computed tomographic scan, or both, for evaluation after the operation. The patients received anticoagulation therapy for 3 to 6 months after surgery., Results: Mean follow-up after surgery was 490 +/- 276 days (1.3-31.6 months, median 16.7 months). There were no complications such as thrombosis, stenosis, or obstruction of the tissue-engineered autografts. One late death at 3 months after total cavopulmonary connection was noted in patient with hypoplastic left heart syndrome; this was unrelated to the tissue-engineered graft function. There was no evidence of aneurysm formation or calcification on cineangiography or computed tomography. All tube grafts were patent, and the diameter of the tube graft increased with time (110% +/- 7 % of the implanted size)., Conclusion: Biodegradable conduits or patches seeded with autologous bone marrow cells showed normal function (good patency to a maximum follow-up of 32 months). As living tissues, these vascular structures may have the potential for growth, repair, and remodeling. The tissue-engineering approach may provide an important alternative to the use of prosthetic materials in the field of pediatric cardiovascular surgery. Longer follow-up is necessary to confirm the durability of this approach.

Published

2005

35. The tissue-engineered vascular graft using bone marrow without culture.

Author

Hibino N, Shin'oka T, Matsumura G, Ikada Y, and Kurosawa H

Subjects

Animals, Calcium analysis, Caproates chemistry, Caproates therapeutic use, Cell Culture Techniques methods, Collagen Type IV analysis, Collagen Type IV biosynthesis, DNA analysis, Dogs, Femoral Vein cytology, Hydroxyproline analysis, Immunohistochemistry, Lactic Acid chemistry, Lactic Acid therapeutic use, Lactones chemistry, Lactones therapeutic use, Microscopy, Electron, Models, Animal, Platelet Endothelial Cell Adhesion Molecule-1 analysis, Polyesters, Polyglycolic Acid chemistry, Polyglycolic Acid therapeutic use, Polymers chemistry, Polymers therapeutic use, Random Allocation, Tissue and Organ Procurement methods, Vena Cava, Inferior surgery, Bioprosthesis standards, Blood Vessel Prosthesis standards, Blood Vessel Prosthesis Implantation methods, Bone Marrow Cells physiology, Bone Marrow Cells ultrastructure, Bone Marrow Transplantation methods, Tissue Engineering methods, Transplantation, Autologous methods

Abstract

Objective: To overcome the shortcomings of current vascular grafts, tissue-engineering methods have been applied to cardiovascular regions. We previously reported the creation of a tissue-engineered vascular graft by using vascular mixed cells. However, the cost and manpower for harvesting and culturing the cells was too burdensome. To overcome these drawbacks, we have developed a new method for creating a tissue-engineered vascular graft by using bone marrow cells, which can be obtained easily and used immediately, without cell culture., Methods: Biodegradable polymers seeded with different types of cells (group V, cultured venous cells; group B, bone marrow cells without culture; and group C, non-cell-seeded graft [as control]) were implanted into the inferior venae cavae of dogs. The grafts were explanted at 4 weeks and assessed histologically and biochemically., Results: In the histologic examination, a regular layer of Masson-staining collagen fiber and a layer of factor VII-stained endothelial and ant-alpha-smooth muscle cell antigen-immunoreactive cells stained in groups V and B like native vascular tissue, whereas no such stained regular lining was detected in group C. A 4-hydroxyproline assay in group C showed significantly lower levels than in groups V and B or native tissue ( P < .05). The DNA content of the tissue-engineered vascular graft tended to be higher in group C than in groups V and B or in native tissue., Conclusions: In the creation of tissue-engineered vascular grafts, the method of using bone marrow cells seems to be useful and superior to that of using vascular cells because bone marrow cells can be used directly, without culture.

Published

2005

36. Extracardiac total cavopulmonary connection using a tissue-engineered graft.

Author

Isomatsu Y, Shin'oka T, Matsumura G, Hibino N, Konuma T, Nagatsu M, and Kurosawa H

Subjects

Adolescent, Adult, Blood Vessel Prosthesis, Bone Marrow Cells cytology, Cells, Cultured, Child, Child, Preschool, Heart Defects, Congenital surgery, Heart Ventricles abnormalities, Humans, Infant, Blood Vessel Prosthesis Implantation, Heart Bypass, Right, Tissue Engineering

Abstract

Objective: Extracardiac and lateral tunnel total cavopulmonary connection are currently 2 major options for patients with a single ventricle physiology. However, each procedure has some disadvantages over the other. We developed a new technique of extracardiac total cavopulmonary connection using a tissue-engineered graft to overcome some of the disadvantages previously associated with both the extracardiac and lateral tunnel procedures., Methods: Between February 2001 and October 2002, 8 patients underwent an extracardiac total cavopulmonary connection using a tissue-engineered graft in our institution. Collected bone marrow cells (1 x 10(8) mononucleocytes) from a patient (approximately 1-4 mL/kg body weight) were seeded onto a biodegradable scaffold composed of polycaprolactone-polylactic acid copolymer reinforced with woven polylactic acid. After a 2- to 4-hour cultivation, the seeded scaffold was implanted as an extracardiac conduit during the total cavopulmonary connection operation., Results: There were no hospital or late deaths. At a mean follow-up of 13.4 months (range 4-25 months), all patients are alive and asymptomatic with no need for repeat surgery. A postoperative catheter examination or computed tomography showed all tissue-engineered grafts to be patent and revealed no stenosis, obstruction, or aneurysmal change in the 8 patients., Conclusion: We believe that extracardiac total cavopulmonary connection using a tissue-engineered graft has the potential to overcome some of the disadvantages previously associated with extracardiac or lateral tunnel total cavopulmonary connection. However, an extended follow-up period is required to clarify the long-term clinical outcome for the tissue-engineered graft.

Published

2003

37. [Clinical practice of transplantation of regenerated blood vessels using bone marrow cells].

Author

Shinoka T, Matsumura K, Hibino N, Naito Y, Murata A, Kosaka Y, and Kurosawa H

Subjects

Animals, Child, Preschool, Dogs, Female, Humans, Male, Pulmonary Artery surgery, Sheep, Bone Marrow Cells physiology, Tissue Engineering methods

Published

2003

38. Successful application of tissue engineered vascular autografts: clinical experience.

Author

Matsumura G, Hibino N, Ikada Y, Kurosawa H, and Shin'oka T

Subjects

Adolescent, Child, Child, Preschool, Female, Humans, Transplantation, Autologous, Blood Vessel Prosthesis, Bone Marrow Transplantation methods, Cardiac Surgical Procedures methods, Saphenous Vein transplantation, Tissue Engineering methods, Tissue Transplantation methods, Transplants

Abstract

Foreign materials often used in cardiovascular surgery may cause unwanted side effects and reduced growth potential. To resolve these problems, we have designed a tissue-engineering technique that utilizes bone marrow cells (BMCs) in clinical treatments. To obtain tissue-engineered material, we harvested saphenous vein samples from patients, which were then minced, cultured and seeded onto a biodegradable scaffold. The first operation was performed in May 1999 as previously described (N. Engl. J. Med. 344 (7) (2001) 532) and this method was repeated on two other patients. From November 2001, we used aspirated BMCs as the cell source, which were seeded onto the scaffold on the day of surgery. This method was applied in 22 patients. There was no morbidity such as thrombogenic complications, stenosis or obstruction of tissue-engineered autografts, and no mortality due to these techniques. These results indicate that BMCs seeded onto a biodegradable scaffold to establish tissue-engineered vascular autografts (TEVAs) is an ideal strategy, and present strong evidence for the justification and validity of our protocol in clinical trials of tissue engineering.

Published

2003

39. Successful clinical application of tissue-engineered graft for extracardiac Fontan operation.

Author

Naito Y, Imai Y, Shin'oka T, Kashiwagi J, Aoki M, Watanabe M, Matsumura G, Kosaka Y, Konuma T, Hibino N, Murata A, Miyake T, and Kurosawa H

Subjects

Abnormalities, Multiple surgery, Blood Vessel Prosthesis Implantation adverse effects, Child, Graft Occlusion, Vascular diagnosis, Heart Atria abnormalities, Heart Septal Defects, Atrial surgery, Heart Septal Defects, Ventricular surgery, Heart Ventricles abnormalities, Humans, Male, Treatment Outcome, Vena Cava, Superior abnormalities, Anastomosis, Surgical methods, Blood Vessel Prosthesis Implantation methods, Fontan Procedure methods, Graft Occlusion, Vascular surgery, Hepatic Veins surgery, Pulmonary Artery surgery, Reoperation methods, Tissue Engineering methods

Published

2003

40. [First successful clinical application of tissue engineered blood vessel].

Author

Hibino N, Imai Y, Shin-oka T, Aoki M, Watanabe M, Kosaka Y, Matsumura G, Konuma T, Toyama S, Murata A, Naito Y, and Miyake T

Subjects

Child, Preschool, Female, Fontan Procedure, Humans, Blood Vessel Prosthesis Implantation, Double Outlet Right Ventricle surgery, Heart Ventricles abnormalities, Pulmonary Artery surgery, Plastic Surgery Procedures methods, Tissue Engineering methods

Abstract

With this tissue engineering (TE) technique, the peripheral pulmonary artery was successfully reconstructed, using the patient's own venous cells in a 4-year-old girl, 2 years after Fontan procedure. A 4-year-old girl was given a diagnosis of single right ventricle, double-outlet right ventricle and pulmonary atresia. She underwent left modified Blalock-Taussig shunt at a month old, pulmonary artery angioplasty at a year and 3 months old, and bidirectional cavopulmonary shunt at 2 years and a month old. She underwent again pulmonary artery angioplasty and Fontan operation at 3 years and 3 months. An angiographical examination 7 months after the operation revealed total occlusion of the right intermediate pulmonary artery. TE technique using autologous cells was indicated. The application of this procedure was approved by the ethical committee in Tokyo Women's Medical University. The patient's parents were thoroughly informed and signed a consent form. Approximately 2 cm of the peripheral vein was explanted under sterile conditions. The tissue was minced, placed in tissue culture dishes and cultured at 37 degrees C, 100% humidity and a 5% CO2 atmosphere for almost a month. The number of cells substantially increased to reach 12 millions for almost a month. The culture medium was changed every 3 days. The polymer tube that served as a scaffold for cells was composed of the copolymer of PCL-PLA (50:50) with reinforcement by woven PGA. The polymer conduit, 10 mm in diameter, 20 mm in length and 1 mm in thickness, was designated to biodegradate within 8 weeks. The number of seeded cells was approximately a million/cm2. The graft transplantation was performed 10 days after seeding cells. The occlusive right intermediate pulmonary artery was reconstructed with the TE vessel graft under extracorporeal circulation with a pump-oxygenator. The patient followed a satisfactory postoperative course. The postoperative angiography demonstrated that the graft was not constricted and dilated but that it preserved good patency. Long-term follow-up are necessary. We plan to continue to use the TE technique using autologous cells in the low pressure system like venous or pulmonary circulation. Because our results even in early experimental phase were valuable and promising, we believe that the TE approach may play an important role in the near future as an another alternative, together with transplantation and artificial organ, especially in the field of cardiovascular surgery that mostly needs replants.

Published

2002

41. Tissue-engineered vascular autograft: inferior vena cava replacement in a dog model.

Author

Watanabe M, Shin'oka T, Tohyama S, Hibino N, Konuma T, Matsumura G, Kosaka Y, Ishida T, Imai Y, Yamakawa M, Ikada Y, and Morita S

Subjects

Animals, Dogs, Transplantation, Autologous, Bioprosthesis, Tissue Engineering, Vena Cava, Inferior

Abstract

Tissue-engineered vascular autografts (TEVAs) were made by seeding 4-6 x 10(6) of mixed cells obtained from femoral veins of mongrel dogs onto tube-shaped biodegradable polymer scaffolds composed of a polyglycolid acid (PGA) nonwoven fabric sheet and a copolymer of L-lactide and caprolactone (n = 4). After 7 days, the inferior vena cavas (IVCs) of the same dogs were replaced with TEVAs. After 3, 4, 5, and 6 months, angiographies were performed, and the dogs were sacrificed. The implanted TEVAs were examined both grossly and immunohistologically. The implanted TEVAs showed no evidence of stenosis or dilatation. No thrombus was found inside the TEVAs, even without any anticoagulation therapy. Remnants of the polymer scaffolds were not observed in all specimens, and the overall gross appearance similar to that of native IVCs. Immunohistological staining revealed the presence of factor VIII positive nucleated cells at the luminal surface of the TEVAs. In addition, lesions were observed where alpha-smooth muscle actin and desmin positive cells existed. Implanted TEVAs contained a sufficient amount of extracellular matrix, and showed neither occlusion nor aneurysmal formation. In addition, endothelial cells were found to line the luminal surface of each TEVA. These results strongly suggest that "ideal" venous grafts with antithrombogenicity can be produced.

Published

2001

42. [First successful clinical application of tissue engineered blood vessel]

Author

N, Hibino, Y, Imai, T, Shin-oka, M, Aoki, M, Watanabe, Y, Kosaka, G, Matsumura, T, Konuma, S, Toyama, A, Murata, Y, Naito, and T, Miyake

Subjects

Blood Vessel Prosthesis Implantation, Tissue Engineering, Child, Preschool, Heart Ventricles, Humans, Female, Pulmonary Artery, Plastic Surgery Procedures, Fontan Procedure, Double Outlet Right Ventricle

Abstract

With this tissue engineering (TE) technique, the peripheral pulmonary artery was successfully reconstructed, using the patient's own venous cells in a 4-year-old girl, 2 years after Fontan procedure. A 4-year-old girl was given a diagnosis of single right ventricle, double-outlet right ventricle and pulmonary atresia. She underwent left modified Blalock-Taussig shunt at a month old, pulmonary artery angioplasty at a year and 3 months old, and bidirectional cavopulmonary shunt at 2 years and a month old. She underwent again pulmonary artery angioplasty and Fontan operation at 3 years and 3 months. An angiographical examination 7 months after the operation revealed total occlusion of the right intermediate pulmonary artery. TE technique using autologous cells was indicated. The application of this procedure was approved by the ethical committee in Tokyo Women's Medical University. The patient's parents were thoroughly informed and signed a consent form. Approximately 2 cm of the peripheral vein was explanted under sterile conditions. The tissue was minced, placed in tissue culture dishes and cultured at 37 degrees C, 100% humidity and a 5% CO2 atmosphere for almost a month. The number of cells substantially increased to reach 12 millions for almost a month. The culture medium was changed every 3 days. The polymer tube that served as a scaffold for cells was composed of the copolymer of PCL-PLA (50:50) with reinforcement by woven PGA. The polymer conduit, 10 mm in diameter, 20 mm in length and 1 mm in thickness, was designated to biodegradate within 8 weeks. The number of seeded cells was approximately a million/cm2. The graft transplantation was performed 10 days after seeding cells. The occlusive right intermediate pulmonary artery was reconstructed with the TE vessel graft under extracorporeal circulation with a pump-oxygenator. The patient followed a satisfactory postoperative course. The postoperative angiography demonstrated that the graft was not constricted and dilated but that it preserved good patency. Long-term follow-up are necessary. We plan to continue to use the TE technique using autologous cells in the low pressure system like venous or pulmonary circulation. Because our results even in early experimental phase were valuable and promising, we believe that the TE approach may play an important role in the near future as an another alternative, together with transplantation and artificial organ, especially in the field of cardiovascular surgery that mostly needs replants.

Published

2002