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Abstract

Tissue-engineered arteries using natural scaffolds could overcome the drawbacks of autografts or artificial conduits used in the repair of many congenital cardiac defects and coronary artery bypass grafts. In this study, we present a novel approach based on the use of decellularized xenogeneic matrix scaffolds preconditioned with human peripheral blood stem cells for future cardiovascular therapy. Cellular components of porcine carotid arteries (n = 40) were removed with physical, chemical and enzymatic means. The decellularized arteries were preconditioned by perfusion with human peripheral blood solution for 10 days. The decellularized and preconditioned grafts were characterized for their histological and functional integrity. To demonstrate proof-of-concept, we used a sub-acute (96 h) rabbit model where either only decellularized porcine arteries or preconditioned with autologous rabbit blood solution were implanted in the abdominal aorta of the animals. The rabbits were examined by Doppler ultrasound and histology. Histology and molecular analysis showed absence of cells and preservation of extracellular cell matrix (ECM) proteins in decellularized porcine arteries. Preconditioning of arteries with human blood showed a thin lining of intima with blood and cells. In the rabbit implant model, although blood flow was detected in all rabbits at 24 h, the animals implanted with only decellularized arteries showed lumen filled with thrombus. However, in preconditioned arteries, thrombosis was not seen at either 24 or 96 h. Taken together, these results suggest that these decellularization and preconditioning protocols using autologous blood may be adaptable for successful tissue-engineering of xeno-arteries for human application. However, further research to improve preconditioning efficiency and long-term animal studies are needed.

Keywords

tissue-engineering cardiovascular therapy rabbit animal model decellularization pre-conditioning human peripheral blood stem cells

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References

Roth

Mensah

Johnson

, et al. Global burden of cardiovascular diseases and risk factors, 1990-2019: update from the GBD 2019 study. J Am Coll Cardiol 2020; 76(25): 2982–3021.

Dimeling

Bakaeen

Khatri

, et al.

CABG: when, why, and how?

Cleve Clin J Med 2021; 88(5): 295–303.

Virani

Alonso

Benjamin

, et al. Heart disease and stroke Statistics-2020 update: a report from the American heart association. Circulation 2020; 141(9): e139–e596.

Yuan

Chen

Liu

, et al. Strategies in cell-free tissue-engineered vascular grafts. J Biomed Mater Res 2020; 108(3): 426–445.

Hadinata

Hayward

PAR

Hare

, et al. Choice of conduit for the right coronary system: 8-year analysis of radial artery patency and clinical outcomes trial. Ann Thorac Surg 2009; 88(5): 1404–1409.

Niklason

Lawson

. Bioengineered human blood vessels. Science 2020; 370(6513): eaaw8682.

Zhang

Chen

Hong

, et al. Decellularized extracellular matrix scaffolds: recent trends and emerging strategies in tissue engineering. Bioact Mater 2022; 10: 15–31.

Gilbert

Sellaro

Badylak

. Decellularization of tissues and organs. Biomaterials 2006; 27(19): 3675–3683.

Cheng

Cai

, et al. Decellularization of porcine carotid arteries using low-concentration sodium dodecyl sulfate. Int J Artif Organs 2021; 44(7): 497–508.

10.

Massaro

Kochová

Pálek

, et al. Decellularization of porcine carotid arteries: from the vessel to the high-quality scaffold in five hours. Front Bioeng Biotechnol 2022; 10: 833244.

11.

Daugs

Hutzler

Meinke

, et al. Detergent-based decellularization of bovine carotid arteries for vascular tissue engineering. Ann Biomed Eng 2017; 45(11): 2683–2692.

12.

Mallis

Michalopoulos

Pantsios

, et al. Recellularization potential of small diameter vascular grafts derived from human umbilical artery. Bio Med Mater Eng 2019; 30(1): 61–71.

13.

Keshi

Tang

Weinhart

, et al. Surface modification of decellularized bovine carotid arteries with human vascular cells significantly reduces their thrombogenicity. J Biol Eng 2021; 15(1): 26.

14.

Iijima

Aubin

Steinbrink

, et al. Bioactive coating of decellularized vascular grafts with a temperature-sensitive VEGF-conjugated hydrogel accelerates autologous endothelialization in vivo. J Tissue Eng Regen Med 2018; 12(1): e513–e522.

15.

Sugiura

Matsumura

Miyamoto

, et al. Tissue-engineered vascular grafts in children with congenital heart disease: intermediate term Follow-up. Semin Thorac Cardiovasc Surg 2018; 30(2): 175–179.

16.

Olausson

Patil

Kuna

, et al. Transplantation of an allogeneic vein bioengineered with autologous stem cells: a proof-of-concept study. Lancet 2012; 380(9838): 230–237.

17.

Silva

Chrobok

Ahlén

, et al. ATMP development and pre-GMP environment in academia: a safety net for early cell and gene therapy development and manufacturing. Immunooncol Technol 2022; 16: 100099.

18.

Olausson

Kuna

Travnikova

, et al. In vivo application of tissue-engineered veins using autologous peripheral whole blood: a proof of concept study. EBioMedicine 2014; 1(1): 72–79.

19.

Kumar Kuna

Sumitran-Holgersson

. Decellularization and recellularization methodology for human saphenous veins. J Vis Exp. 2018; 137: 57803.

20.

Garcia

Peña

Laborda

, et al. Experimental study and constitutive modelling of the passive mechanical properties of the porcine carotid artery and its relation to histological analysis: implications in animal cardiovascular device trials. Med Eng Phys 2011; 33(6): 665–676.

21.

Tomasek

Tonar

Grajciarová

, et al. Histological mapping of porcine carotid arteries - an animal model for the assessment of artificial conduits suitable for coronary bypass grafting in humans. Ann Anat 2020; 228: 151434.

22.

Latimer

Nelson

Moore

, et al. Effect of collagen and elastin content on the burst pressure of human blood vessel seals formed with a bipolar tissue sealing system. J Surg Res 2014; 186(1): 73–80.

23.

Mallis

Katsimpoulas

Kostakis

, et al. Vitrified human umbilical arteries as potential grafts for vascular tissue engineering. Tissue Eng Regen Med 2020; 17(3): 285–299.

24.

Soares da Costa

Reis

Pashkuleva

. Sulfation of glycosaminoglycans and its implications in human health and disorders. Annu Rev Biomed Eng 2017; 19: 1–26.

25.

Uhl

Zhang

Pouliot

, et al. Functional role of glycosaminoglycans in decellularized lung extracellular matrix. Acta Biomater 2020; 102: 231–246.

26.

Ciszek

Cieślicki

Krajewski

, et al. Critical pressure for arterial wall rupture in major human cerebral arteries. Stroke 2013; 44(11): 3226–3228.

27.

Kuo

Sun

, et al. Optimized decellularization protocol including alpha-Gal epitope reduction for fabrication of an acellular porcine annulus fibrosus scaffold. Cell Tissue Bank 2017; 18(3): 383–396.

28.

Hashimoto

Tsuchiya

Doi

, et al. Alteration of the extracellular matrix and alpha-gal antigens in the rat lung scaffold reseeded using human vascular and adipogenic stromal cells. J Tissue Eng Regen Med 2019; 13(11): 2067–2076.

29.

Liliensiek

Nealey

Murphy

. Characterization of endothelial basement membrane nanotopography in rhesus macaque as a guide for vessel tissue engineering. Tissue Eng 2009; 15(9): 2643–2651.

30.

Ackroyd

Gill

Griffiths

, et al. Quantitative common carotid artery blood flow: prediction of internal carotid artery stenosis. J Vasc Surg 1986; 3(6): 846–853.

31.

Hakansson

Simsa

Bogestål

, et al. Individualized tissue-engineered veins as vascular grafts: a proof of concept study in pig. J Tissue Eng Regen Med 2021; 15(10): 818–830.

32.

Rambol

Hisdal

Sundhagen

, et al. Recellularization of decellularized venous grafts using peripheral blood: a critical evaluation. EBioMedicine 2018; 32: 215–222.

33.

Kong

Melo

Gnecchi

, et al. Cytokine-induced mobilization of circulating endothelial progenitor cells enhances repair of injured arteries. Circulation 2004; 110(14): 2039–2046.

34.

Sturtzel

. Endothelial cells. Adv Exp Med Biol 2017; 1003: 71–91.

35.

Hristov

Erl

Weber

. Endothelial progenitor cells: mobilization, differentiation, and homing. Arterioscler Thromb Vasc Biol 2003; 23(7): 1185–1189.

36.

Fernandez Pujol

Lucibello

Gehling

, et al. Endothelial-like cells derived from human CD14 positive monocytes. Differentiation 2000; 65(5): 287–300.

37.

dela Paz

D'Amore

. Arterial versus venous endothelial cells. Cell Tissue Res 2009; 335(1): 5–16.

38.

van der Lei

Robinson

Bartels

, et al. Microarterial grafting into the carotid artery of the rabbit: some considerations concerning species-dependent thrombogenicity. Br J Plast Surg 1989; 42(1): 59–64.

39.

Fang

Fan

, et al. Evaluation of a hybrid small caliber vascular graft in a rabbit model. J Thorac Cardiovasc Surg 2020; 159(2): 461–473.

40.

Amensag

Goldberg

O'Malley

, et al. Pilot assessment of a human extracellular matrix-based vascular graft in a rabbit model. J Vasc Surg 2017; 65(3): 839–847.

41.

Zheng

Miao

Zhou

, et al. [experimental study on evolution of nano-biomimetic tissue engineered blood vessel after abdominal aorta transplantation in rabbits]. Zhongguo Xiu Fu Chong Jian Wai Ke Za Zhi 2008; 22(11): 1364–1368.

42.

Yang

Yan

Zhao

, et al. Microsurgical reconstruction of hepatic artery in A-A LDLT: 124 consecutive cases without HAT. World J Gastroenterol 2010; 16(21): 2682–2688.

43.

Gimbrone

Anderson

Topper

, et al. Special communicationthe critical role of mechanical forces in blood vessel development, physiology and pathology. J Vasc Surg 1999; 29(6): 1104–1151.

44.

Heng

Yazid

Abdul Rahman

, et al. Coatings in decellularized vascular scaffolds for the establishment of a functional endothelium: a scoping review of vascular graft refinement. Front Cardiovasc Med 2021; 8: 677588.

45.

Pashneh-Tala

MacNeil

Claeyssens

. The tissue-engineered vascular graft-past, present, and future. Tissue Eng Part B 2016; 22(1): 68–100.

46.

Row

Peng

Schlaich

, et al. Arterial grafts exhibiting unprecedented cellular infiltration and remodeling in vivo: the role of cells in the vascular wall. Biomaterials 2015; 50: 115–126.

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Human blood preconditioned porcine arteries as potential conduits for human transplantation: Proof of concept in rabbit

Abstract

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