1.Tissue engineering applications in the genitourinary tract system.
Yonsei Medical Journal 2000;41(6):789-802
The concept of cell transplantation using tissue engineering techniques has provided numerous possibilities in the area of urologic tissue reconstruction. Tissue engineering applications in the genitourinary tract system have been investigated in almost every tissue in order to improve, restore and replace existing tissue function. Although most reconstructive efforts still remain in the experimental stage, several technologies have been transferred to the bedside with satisfactory outcome. In this article, we describe tissue engineering approaches attempted in the genitourinary system for reconstruction.
Animal
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Biomedical Engineering*
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Bladder
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Fetus
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Gene Therapy/methods
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Genitalia
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Human
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Kidney
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Ureter
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Urethra
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Urogenital System*
2.Cell-based therapy for kidney disease.
Hyun Chul CHUNG ; In Kap KO ; Anthony ATALA ; James J YOO
Korean Journal of Urology 2015;56(6):412-421
The prevalence of renal disease continues to increase worldwide. When normal kidney is injured, the damaged renal tissue undergoes pathological and physiological events that lead to acute and chronic kidney diseases, which frequently progress to end stage renal failure. Current treatment of these renal pathologies includes dialysis, which is incapable of restoring full renal function. To address this issue, cell-based therapy has become a potential therapeutic option to treat renal pathologies. Recent development in cell therapy has demonstrated promising therapeutic outcomes, in terms of restoration of renal structure and function impaired by renal disease. This review focuses on the cell therapy approaches for the treatment of kidney diseases, including various cell sources used, as well recent advances made in preclinical and clinical studies.
Cell- and Tissue-Based Therapy/*methods
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Fetal Stem Cells/transplantation
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Humans
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Kidney/cytology
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Kidney Diseases/*therapy
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Pluripotent Stem Cells/transplantation
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Stem Cell Transplantation/methods
3.In situ tissue regeneration through host stem cell recruitment.
In Kap KO ; Sang Jin LEE ; Anthony ATALA ; James J YOO
Experimental & Molecular Medicine 2013;45(11):e57-
The field of tissue engineering has made steady progress in translating various tissue applications. Although the classical tissue engineering strategy, which involves the use of culture-expanded cells and scaffolds to produce a tissue construct for implantation, has been validated, this approach involves extensive cell expansion steps, requiring a lot of time and laborious effort before implantation. To bypass this ex vivo process, a new approach has been introduced. In situ tissue regeneration utilizes the body's own regenerating capacity by mobilizing host endogenous stem cells or tissue-specific progenitor cells to the site of injury. This approach relies on development of a target-specific biomaterial scaffolding system that can effectively control the host microenvironment and mobilize host stem/progenitor cells to target tissues. An appropriate microenvironment provided by implanted scaffolds would facilitate recruitment of host cells that can be guided to regenerating structural and functional tissues.
Animals
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Guided Tissue Regeneration/*methods
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Humans
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Stem Cell Transplantation/*methods
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Stem Cells/*cytology/metabolism
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Tissue Engineering/methods
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Tissue Scaffolds
4.Regenerative Medicine Strategies for Treating Neurogenic Bladder.
James J YOO ; Jennifer OLSON ; Anthony ATALA ; Bupwan KIM
International Neurourology Journal 2011;15(3):109-119
Neurogenic bladder is a general term encompassing various neurologic dysfunctions of the bladder and the external urethral sphincter. These can be caused by damage or disease. Therapeutic management options can be conservative, minimally invasive, or surgical. The current standard for surgical management is bladder augmentation using intestinal segments. However, because intestinal tissue possesses different functional characteristics than bladder tissue, numerous complications can ensue, including excess mucus production, urinary stone formation, and malignancy. As a result, investigators have sought after alternative solutions. Tissue engineering is a scientific field that uses combinations of cells and biomaterials to encourage regeneration of new, healthy tissue and offers an alternative approach for the replacement of lost or deficient organs, including the bladder. Promising results using tissue-engineered bladder have already been obtained in children with neurogenic bladder caused by myelomeningocele. Human clinical trials, governed by the Food and Drug Administration, are ongoing in the United States in both children and adults to further evaluate the safety and efficacy of this technology. This review will introduce the principles of tissue engineering and discuss how it can be used to treat refractory cases of neurogenic bladder.
Adult
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Biocompatible Materials
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Child
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Humans
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Meningomyelocele
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Mucus
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Neurologic Manifestations
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Regeneration
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Regenerative Medicine
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Research Personnel
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Tissue Engineering
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United States
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United States Food and Drug Administration
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Urethra
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Urinary Bladder
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Urinary Bladder, Neurogenic
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Urinary Calculi
5.Tissue Engineering: Current Strategies and Future Directions
Jennifer L OLSON ; Anthony ATALA ; James J YOO
Chonnam Medical Journal 2011;47(1):1-13
Novel therapies resulting from regenerative medicine and tissue engineering technology may offer new hope for patients with injuries, end-stage organ failure, or other clinical issues. Currently, patients with diseased and injured organs are often treated with transplanted organs. However, there is a shortage of donor organs that is worsening yearly as the population ages and as the number of new cases of organ failure increases. Scientists in the field of regenerative medicine and tissue engineering are now applying the principles of cell transplantation, material science, and bioengineering to construct biological substitutes that can restore and maintain normal function in diseased and injured tissues. In addition, the stem cell field is a rapidly advancing part of regenerative medicine, and new discoveries in this field create new options for this type of therapy. For example, new types of stem cells, such as amniotic fluid and placental stem cells that can circumvent the ethical issues associated with embryonic stem cells, have been discovered. The process of therapeutic cloning and the creation of induced pluripotent cells provide still other potential sources of stem cells for cell-based tissue engineering applications. Although stem cells are still in the research phase, some therapies arising from tissue engineering endeavors that make use of autologous, adult cells have already entered the clinical setting, indicating that regenerative medicine holds much promise for the future.
Adult
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Amniotic Fluid
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Biocompatible Materials
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Bioengineering
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Cell Transplantation
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Clone Cells
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Cloning, Organism
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Embryonic Stem Cells
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Female
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Humans
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Regenerative Medicine
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Stem Cells
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Tissue Donors
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Tissue Engineering
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Transplants
6.Microfluidic Systems for Assisted Reproductive Technologies: Advantages and Potential Applications
Russel C. SEQUEIRA ; Tracy CRISWELL ; Anthony ATALA ; James J. YOO
Tissue Engineering and Regenerative Medicine 2020;17(6):787-800
Microfluidic technologies have emerged as a powerful tool that can closely replicate the in-vivo physiological conditions of organ systems. Assisted reproductive technology (ART), while being able to achieve successful outcomes, still faces challenges related to technical error, efficiency, cost, and monitoring/assessment. In this review, we provide a brief overview of the uses of microfluidic devices in the culture, maintenance and study of ovarian follicle development for experimental and therapeutic applications. We discuss existing microfluidic platforms for oocyte and sperm selection and maintenance, facilitation of fertilization by in-vitro fertilization/intracytoplastimc sperm injection, and monitoring, selection and maintenance of resulting embryos. Furthermore, we discuss the possibility of future integration of these technologies onto a single platform and the limitations facing the development of these systems. In spite of these challenges, we envision that microfluidic systems will likely evolve and inevitably revolutionize both fundamental, reproductive physiology/toxicology research as well as clinically applicable ART.
7.Microfluidic Systems for Assisted Reproductive Technologies: Advantages and Potential Applications
Russel C. SEQUEIRA ; Tracy CRISWELL ; Anthony ATALA ; James J. YOO
Tissue Engineering and Regenerative Medicine 2020;17(6):787-800
Microfluidic technologies have emerged as a powerful tool that can closely replicate the in-vivo physiological conditions of organ systems. Assisted reproductive technology (ART), while being able to achieve successful outcomes, still faces challenges related to technical error, efficiency, cost, and monitoring/assessment. In this review, we provide a brief overview of the uses of microfluidic devices in the culture, maintenance and study of ovarian follicle development for experimental and therapeutic applications. We discuss existing microfluidic platforms for oocyte and sperm selection and maintenance, facilitation of fertilization by in-vitro fertilization/intracytoplastimc sperm injection, and monitoring, selection and maintenance of resulting embryos. Furthermore, we discuss the possibility of future integration of these technologies onto a single platform and the limitations facing the development of these systems. In spite of these challenges, we envision that microfluidic systems will likely evolve and inevitably revolutionize both fundamental, reproductive physiology/toxicology research as well as clinically applicable ART.
8.Cell-derived Secretome for the Treatment of Renal Disease
Michael W. KIM ; In Kap KO ; Anthony ATALA ; James J. YOO
Childhood Kidney Diseases 2019;23(2):67-76
Kidney disease is a major global health issue. Hemodialysis and kidney transplantation have been used in the clinic to treat renal failure. However, the dialysis is not an effective long-term option, as it is unable to replace complete renal functions. Kidney transplantation is the only permanent treatment for end-stage renal disease (ESRD), but a shortage of implantable kidney tissues limits the therapeutic availability. As such, there is a dire need to come up with a solution that provides renal functions as an alternative to the current standards. Recent advances in cellbased therapy have offered new therapeutic options for the treatment of damaged kidney tissues. Particularly, cell secretome therapy utilizing bioactive compounds released from therapeutic cells holds significant beneficial effects on the kidneys. This review will describe the reno-therapeutic effects of secretome components derived from various types of cells and discuss the development of efficient delivery methods to improve the therapeutic outcomes.
Dialysis
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Global Health
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Kidney
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Kidney Diseases
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Kidney Failure, Chronic
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Kidney Transplantation
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Regenerative Medicine
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Renal Dialysis
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Renal Insufficiency
9.Applicability and Safety of in Vitro Skin Expansion Using a Skin Bioreactor: A Clinical Trial.
Cheol JEONG ; Ho Yun CHUNG ; Hyun Ju LIM ; Jeong Woo LEE ; Kang Young CHOI ; Jung Dug YANG ; Byung Chae CHO ; Jeong Ok LIM ; James J YOO ; Sang Jin LEE ; Anthony J ATALA
Archives of Plastic Surgery 2014;41(6):661-667
BACKGROUND: Tissue expansion is an effective and valuable technique for the reconstruction of large skin lesions and scars. This study aimed to evaluate the applicability and safety of a newly designed skin expanding bioreactor system for maximizing the graft area and minimizing the donor site area. METHODS: A computer-controlled biaxial skin bioreactor system was used to expand skin in two directions while the culture media was changed daily. The aim was to achieve an expansion speed that enabled the skin to reach twice its original area in two weeks or less. Skin expansion and subsequent grafting were performed for 10 patients, and each patient was followed for 6 months postoperatively for clinical evaluation. Scar evaluation was performed through visual assessment and by using photos. RESULTS: The average skin expansion rate was 10.54%+/-6.25%; take rate, 88.89%+/-11.39%; and contraction rate, 4.2%+/-2.28% after 6 months. Evaluation of the donor and recipient sites by medical specialists resulted in an average score of 3.5 (out of a potential maximum of 5) at 3 months, and 3.9 at 6 months. The average score for patient satisfaction of the donor site was 6.2 (out of a potential maximum of 10), and an average score of 5.2 was noted for the recipient site. Histological examination performed before and after the skin expansion revealed an increase in porosity of the dermal layer. CONCLUSIONS: This study confirmed the safety and applicability of the in vitro skin bioreactor, and further studies are needed to develop methods for increasing the skin expansion rate.
Bioreactors*
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Cicatrix
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Culture Media
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Humans
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Patient Satisfaction
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Porosity
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Skin Transplantation
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Skin*
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Specialization
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Tissue Donors
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Tissue Expansion
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Transplants