Autologous regeneration of blood vessels in urinary bladder matrices provides early perfusion after transplant to the bladder

IF 3.1 3区 生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Stephanie L. Osborn, Leanna W. Mah, Erica V. Ely, Stefania Ana, Christina Huynh, Naveena S. Ujagar, Serena C. Chan, Philip Hsiao, Jonathan C. Hu, Yvonne Y. Chan, Blaine A. Christiansen, Eric A. Kurzrock
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Abstract

Large animal testing and clinical trials using bioengineered bladder for augmentation have revealed that large grafts fail due to insufficient blood supply. To address this critical issue, an in vivo staged implant strategy was developed and evaluated to create autologous, vascularized bioengineered bladder tissue with potential for clinical translation. Pig bladders were used to create acellular urinary bladder matrices (UBMs), which were implanted on the rectus abdominus muscles of rats and pigs to generate cellular and vascular grafts. Rectus-regenerated bladder grafts (rrBGs) were highly cellularized and contained an abundance of CD31-positive blood vessels, which were shown to be functional by perfusion studies. Muscle patterns within grafts showed increased smooth muscle formation over time and specifically within the detrusor compartment, with no evidence of striated muscle. Large, autologous rrBGs were transplanted to the pig bladder after partial cystectomy and compared to transplantation of control UBMs at 2 weeks and 3 months post-transplant. Functional, ink-perfused blood vessels were found in the central portion of all rrBGs at 2 weeks, while UBM grafts were significantly deteriorated, contracted and lacked central cellularization and vascularization. By 3 months, rrBGs had mature smooth muscle bundles and were morphologically similar to native bladder. This staged implantation technique allows for regeneration and harvest of large bladder grafts that are morphologically similar to native tissue with functional vessels capable of inosculating with host bladder vessels to provide quick perfusion to the central area of the large graft, thereby preventing early ischemia and contraction.

膀胱基质血管的自体再生提供了膀胱移植后的早期灌注
使用生物工程膀胱进行增强的大型动物试验和临床试验表明,由于血液供应不足,大型移植物失败。为了解决这一关键问题,研究人员开发并评估了一种体内分期植入策略,以创建具有临床转化潜力的自体血管化生物工程膀胱组织。用猪膀胱制备脱细胞膀胱基质(ubm),将其植入大鼠和猪腹直肌,形成细胞和血管移植物。直肠再生膀胱移植物(rrBGs)高度细胞化,含有丰富的cd31阳性血管,灌注研究显示其功能良好。移植物内的肌肉形态显示,随着时间的推移,平滑肌的形成增加,特别是在逼尿肌室内,没有横纹肌的证据。在部分膀胱切除术后,将大的自体自体膀胱移植物移植到猪膀胱中,并在移植后2周和3个月与对照膀胱移植物进行比较。在2周时,所有rrBGs的中心部分都发现了功能性的,墨水灌注的血管,而UBM移植物明显恶化,收缩,缺乏中心细胞化和血管化。到3个月时,rrBGs有成熟的平滑肌束,形态与天然膀胱相似。这种分期植入技术允许再生和收获形态与天然组织相似的大膀胱移植物,其功能血管能够与宿主膀胱血管相结合,为大移植物的中心区域提供快速灌注,从而防止早期缺血和收缩。
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来源期刊
CiteScore
7.50
自引率
3.00%
发文量
97
审稿时长
4-8 weeks
期刊介绍: Journal of Tissue Engineering and Regenerative Medicine publishes rapidly and rigorously peer-reviewed research papers, reviews, clinical case reports, perspectives, and short communications on topics relevant to the development of therapeutic approaches which combine stem or progenitor cells, biomaterials and scaffolds, growth factors and other bioactive agents, and their respective constructs. All papers should deal with research that has a direct or potential impact on the development of novel clinical approaches for the regeneration or repair of tissues and organs. The journal is multidisciplinary, covering the combination of the principles of life sciences and engineering in efforts to advance medicine and clinical strategies. The journal focuses on the use of cells, materials, and biochemical/mechanical factors in the development of biological functional substitutes that restore, maintain, or improve tissue or organ function. The journal publishes research on any tissue or organ and covers all key aspects of the field, including the development of new biomaterials and processing of scaffolds; the use of different types of cells (mainly stem and progenitor cells) and their culture in specific bioreactors; studies in relevant animal models; and clinical trials in human patients performed under strict regulatory and ethical frameworks. Manuscripts describing the use of advanced methods for the characterization of engineered tissues are also of special interest to the journal readership.
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