Preparation and characterization of small-diameter decellularized scaffolds for vascular tissue engineering in an animal model

Xu, Shuangyue; Lu, Fangna; Cheng, Lianna; Li, Chenglin; Zhou, Xihui; Wu, Yuan; Chen, Haishan; Zhang, Kaichuang; Wang, Lumin; Xia, Junjie; Yan, Guoliang; Qi, Zhongquan

doi:10.1186/s12938-017-0344-9

Cited by 36 publications

(30 citation statements)

References 53 publications

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“…Over the past decade, several groups have demonstrated the feasibility of completely acellular, off-the-shelf grafts in various animal models as well as human clinical trials. Decellularized and devitalized tissue-engineered constructs have been utilized with increasing frequency and have demonstrated improved patency and regeneration potential (1)(2)(3)(4)(5)(6)(7)(8)(9)(10)(11)(12)(13). Devitalized constructs are based on bioengineered tissue constructs that are stripped of the cellular components while leaving extracellular matrix (ECM) components intact and then implanted into the animal model of choice (14).…”

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confidence: 99%

Implantation of VEGF‐functionalized cell‐free vascular grafts: regenerative and immunological response

Smith

Nasiri

et al. 2019

FASEB j.

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Recently, our group demonstrated that immobilized VEGF can capture flowing endothelial cells (ECs) from the blood in vitro and promote endothelialization and patency of acellular tissue–engineered vessels (A‐TEVs) into the arterial system of an ovine animal model. Here, we demonstrate implantability of submillimeter diameter heparin and VEGF‐decorated A‐TEVs in a mouse model and discuss the cellular and immunologic response. At 1 mo postimplantation, the graft lumen was fully endothelialized, as shown by expression of EC markers such as CD144, eNOS, CD31, and VEGFR2. Interestingly, the same cells coexpressed leukocyte/macrophage (Mϕ) markers CD14, CD16, VEGFR1, CD38, and EGR2. Notably, there was a stark difference in the cellular makeup between grafts containing VEGF and those containing heparin alone. In VEGF‐containing grafts, infiltrating monocytes (MCs) converted into anti‐inflammatory M2‐Mϕs, and the grafts developed well‐demarcated luminal and medial layers resembling those of native arteries. In contrast, in grafts containing only heparin, MCs converted primarily into M1‐Mϕs, and the endothelial and smooth muscle layers were not well defined. Our results indicate that VEGF may play an important role in regulating A‐TEV patency and regeneration, possibly by regulating the inflammatory response to the implants.—Smith, R. J., Jr., Yi, T., Nasiri, B., Breuer, C. K., Andreadis, S. T. Implantation of VEGF‐functionalized cell‐free vascular grafts: regenerative and immunological response. FASEB J. 33, 5089–5100 (2019). http://www.fasebj.org

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confidence: 99%

Implantation of VEGF‐functionalized cell‐free vascular grafts: regenerative and immunological response

Smith

Nasiri

et al. 2019

FASEB j.

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“…For the scaffold choice, among the various possible approaches, ex vivo ‐ derived materials such as decellularized vessels have the structural and mechanical advantage of being composed of a native extracellular matrix (ECM) and possess bioactive molecules that aid tissue homeostasis and regeneration (Bejleri & Davis, ; Chen & Liu, ; M. C. Moore et al, ). Indeed, positive cell interactions with a structurally appropriate ECM aid and guide the regenerative response (Dahan et al, ; Uzarski, Van De Walle, & McFetridge, ; Xu et al, ). Clinical success of decellularized tissues has been reported in a range of applications, including trachea (Gonfiotti et al, ; Hamilton et al, ), heart valve (Dohmen, Lembcke, Holinski, Pruss, & Konertz, ; Tudorache et al, ), right ventricular outflow tract (Bibevski et al, ; Konertz et al, ) as well as vascular grafts (Olausson et al, , ).…”

Section: Introductionmentioning

confidence: 99%

“…Indeed, positive cell interactions with a structurally appropriate ECM aid and guide the regenerative response (Dahan et al, 2017;Uzarski, Van De Walle, & McFetridge, 2013;Xu et al, 2017). Clinical success of decellularized tissues has been reported in a range of applications, including trachea (Gonfiotti et al, 2014;Hamilton et al, 2015), heart valve (Dohmen, Lembcke, Holinski, Pruss, & Konertz, 2011;Tudorache et al, 2016), right ventricular outflow tract (Bibevski et al, 2017;Konertz et al, 2011) as well as vascular grafts (Olausson et al, 2014(Olausson et al, , 2012.…”

Section: Introductionmentioning

confidence: 99%

Sequential adaptation of perfusion and transport conditions significantly improves vascular construct recellularization and biomechanics

Walle

Moore

McFetridge

2020

J Tissue Eng Regen Med

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Recellularization of ex vivo‐derived scaffolds remains a significant hurdle primarily due to the scaffolds subcellular pore size that restricts initial cell seeding to the scaffolds periphery and inhibits migration over time. With the aim to improve cell migration, repopulation, and graft mechanics, the effects of a four‐step culture approach were assessed. Using an ex vivo‐derived vein as a model scaffold, human smooth muscle cells were first seeded onto its ablumen (Step 1: 3 hr) and an aggressive 0–100% nutrient gradient (lumenal flow under hypotensive pressure) was created to initiate cell migration across the scaffold (Step 2: Day 0 to 19). The effects of a prolonged aggressive nutrient gradient created by this single lumenal flow was then compared with a dual flow (lumenal and ablumenal) in Step 3 (Day 20 to 30). Analyses showed that a single lumenal flow maintained for 30 days resulted in a higher proportion of cells migrating across the scaffold toward the vessel lumen (nutrient source), with improved distribution. In Step 4 (Day 31 to 45), the transition from hypotensive pressure (12/8 mmHg) to normotensive (arterial‐like) pressure (120/80 mmHg) was assessed. It demonstrated that recellularized scaffolds exposed to arterial pressures have increased glycosaminoglycan deposition, physiological modulus, and Young's modulus. By using this stepwise conditioning, the challenging recellularization of a vein‐based scaffold and its positive remodeling toward arterial biomechanics were obtained.

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“…The decellularization method has been employed to simulate this complex structure effectively. To date, many groups have reported that transplanted decellularized ECM biomaterials loaded with different cell types improved myocardial function . However, the efficiency and long‐term viability still remains as a major challenge.…”

Section: Introductionmentioning

confidence: 99%

“…To date, many groups have reported that transplanted decellularized ECM biomaterials loaded with different cell types improved myocardial function. 9,10 However, the efficiency and long-term viability still remains as a major challenge. Therefore, the first step toward understanding the biology and physiology of transplanted cells is through documenting survival, homing, differentiation, and migration potential of these cells.…”

Section: Introductionmentioning

confidence: 99%

Investigation of survival and migration potential of differentiated cardiomyocytes transplanted with decellularized heart scaffold

Akbay

Onur

2018

J Biomedical Materials Res

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Mesenchymal stem cell‐derived cardiomyocytes are employed as a source for myocardial cell transplantation as well as for tissue engineering in decellularized tissue scaffolds. The present study aimed at investigating the survival and migration potential of differentiated cardiomyocytes integrated to decellularized scaffolds after implantation into retroperitoneum of rats, and to assess the feasibility of their ectopic use for future cardiovascular tissue engineering. For this purpose, adipose tissue‐derived mesenchymal stem cells (AdMSCs) were first isolated. Cells were labeled by bromodeoxyuridine (BrdU). Decellularized cardiac tissue scaffolds were acquired by application of ionic and non‐ionic detergents and the labeled differentiated cells were seeded onto these tested decellularized scaffolds. After 1, 2, and 4 weeks of implantation, either cell free scaffold (CFS) or cell scaffold (CS) composites were examined by various techniques for ectopic migration potential of the implanted cells and interaction between the seeded cells on scaffolds. Throughout the first and second weeks of implantation, positively stained cells were observed in renal tissue samples. Observations, for cardiomyocytes‐specific gene expression during weeks 1, 2, and 4, showed potential increased over each time period. A reverse transcription polymerase chain reaction (RT‐PCR) results revealed an increased interaction between cells seeded on scaffolds, however CFS test groups showed no significant difference in gene expression. © 2018 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 107A: 561–570, 2019.

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Preparation and characterization of small-diameter decellularized scaffolds for vascular tissue engineering in an animal model

Cited by 36 publications

References 53 publications

Implantation of VEGF‐functionalized cell‐free vascular grafts: regenerative and immunological response

Implantation of VEGF‐functionalized cell‐free vascular grafts: regenerative and immunological response

Sequential adaptation of perfusion and transport conditions significantly improves vascular construct recellularization and biomechanics

Investigation of survival and migration potential of differentiated cardiomyocytes transplanted with decellularized heart scaffold

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