Background
Diseases associated with the circulatory system are the main causes of worldwide morbidity and mortality, implying the need for vascular implants. Thus, the production of vascular biomaterials has proven to be a promising alternative to therapies used in studies and research related to vascular physiology.
Objectives The present project aims to achieve the artificial development of blood vessels through the recellularization of vascular scaffolds derived from bovine placental vessels.
Methods The chorioallantoic surface of the bovine placenta was used to produce decellularized biomaterials. For recellularization, 2.5 x 104 endothelial cells were seeded above each decellularized vessel fragment during three or seven days, when culture were interrupted, and the fragments were fixed for cell attachment analysis. Decellularized and recellularized biomaterials were evaluated by basic histology, scanning electron microscopy, and immunohistochemistry.
Results The decellularization process produced vessels that maintained natural structure and elastin content, and no cells or gDNA remains were observed. Endothelial precursor cells were also attached to lumen and external surface of the decellularized vessel.Conclusion: Our results show a possibility of future uses of this biomaterial in cardiovascular medicine, as in the development of engineered vessels.
Decellularized Extracellular Matrix; Bioengineering; Blood Vessels
Resumo
Fundamento As doenças associadas ao aparelho circulatório são as principais causas de morbidade e mortalidade em todo o mundo, implicando a necessidade de implantes vasculares. Assim, a produção de biomateriais vasculares tem se mostrado uma alternativa promissora às terapias utilizadas em estudos e pesquisas relacionados à fisiologia vascular.
Objetivos O presente projeto visa ao desenvolvimento artificial de vasos sanguíneos pela recelularização de scaffolds vasculares derivados de vasos placentários bovinos.
Métodos A superfície corioalantoide da placenta bovina foi utilizada para produzir biomateriais descelularizados. Para a recelularização, 2,5 x 104 células endoteliais foram semeadas acima de cada fragmento de vaso descelularizado durante três ou sete dias, quando a cultura foi interrompida e os fragmentos foram fixados para análise de adesão celular. Biomateriais descelularizados e recelularizados foram avaliados por histologia básica, microscopia eletrônica de varredura e imuno-histoquímica.
Resultados o processo de descelularização produziu vasos que mantiveram a estrutura natural e o conteúdo de elastina, e não foram observadas células e gDNA remanescentes. Além disso, células precursoras endoteliais se ligaram ao lúmen e à superfície externa do vaso descelularizado.
Conclusão nossos resultados mostram a possibilidade de usos futuros desse biomaterial na medicina cardiovascular, como, por exemplo, no desenvolvimento de vasos artificiais.
Matriz Extracelular Descelularizada; Bioengenharia; Vasos Sanguíneos
Introduction
Noncommunicable diseases (NCDs) have been increased mainly due to a sedentary lifestyle, industrial food, high-calorie intake, alcohol, and tobacco consumption. Among NCDs, those related to the circulatory system’s failure are the main causes of worldwide morbidity and mortality.1 This failure is mainly treated by vascular surgery and viable vessels are needed, which are generally derived from autologous peripheral vessel dissection and implantation in the affected site. However, commonly infectious complications, necrosis, and dehiscence are described at the vessel removal site. In some cases, a stent is placed in the injured vessel instead of a peripheral vessel fragment; however, possible complications include fractures and intimal hyperplasia.4,5
In this scenario, significant advances have been made by bioengineering in the production of new functional or functionalized organs, such as engineered blood vessel development to support functional vascularization.6-8 So far, small-scale vessels have been produced, most of which are formed from derivatives of rigid synthetic polymers.6,9 Otherwise, engineered vessels that maintain their structural and cellular function for long periods have not yet been produced.
Thus, the development of vascular biomaterials by recellularization, and especially by bioprinting, have proven to be promising alternatives to support therapies used in diseases and studies related to vascular physiology.9,10 The present study thus aimed to produce vascular biomaterials derived from decellularized bovine placental vessels that could be used as its natural tridimensional structure or as biogels.
Materials and Methods
Sample and cells
For vessel isolation, bovine placenta, with an estimated age of 270 days of pregnancy, was obtained at a slaughterhouse. For cytocompatibility assays, two endothelial progenitor cells were used: canine yolk sac (SV) and canine yolk sac cells with vascular endothelial growth factor (VEGF) and enhanced green fluorescent protein (eGFP) overexpression (SV-VEGF).11 All experiments were approved by the Committee on Ethics in the Use of Animals of the Faculty of Veterinary Medicine and Animal Science at the University of São Paulo, logged under protocol number 9715100718.
Decellularization protocol
The chorioallantoic surface of the bovine placenta was used to produce decellularized biomaterials. The chorioallantois was individualized and the umbilical arteries cannulated with #14 catheters and attached to the ORCA bioreactor (Harvard Aparattus, USA). Initially, perfusion was performed with a phosphate buffer solution (PBS: 136.9 mM NaCl, 26.8 mM KCl, 14.7 MM KH2PO4, and 8.1 mM Na2HPO4.7H2O; pH 7.2) with a constant volume of 0.5 ml/min until complete cleaning of the vascular system, approximately 24 hours. A 0.01% solution of sodium dodecyl sulfate (SDS, Sigma-Aldrich 11767289001) was then perfused in distilled water, also under 0.5ml/min for 24 hours. Subsequently the solution was changed to 0.1% SDS for two days, to 0.25% for one day, to 0.5% for 1 day, and to 1.0% for one day, respectively. The decellularized chorioallantois was then perfused with 1% Triton X-100 (#0694-1L, Amresco-Solon, USA) for three hours. Finally, it was washed with PBS for 24 hours, making a total of 10 days.
After decellularization, the entire vascular system from the allantochorionic surface was isolated from the cotyledon and the membrane. The vessels were then preserved in 4% paraformaldehyde (PFA) for decellularization validation or snap frozen for cytocompatibility assay and hydrogel production.
Decellularization validation
For decellularization validation by histological analysis, the PFA preserved samples were routinely dehydrated, diaphanized, and paraffin embedded. These were then sectioned using a manual microtome (Leica RM2125 RT) into 5 µm thick slices and transferred to histological slides. To verify the absence of visible cell nuclei, the slides were stained in Hematoxylin and Eosin (H&E) or 4’,6’-diamino-2-fenil-indol (DAPI) stained and observed under a Nikon Eclipse 80l microscope under light or epifluorescence, respectively.
The decellularization validation was also performed by quantifying the remaining genomic deoxyribonucleic acid (gDNA), which was extracted by salt precipitation, adapted from Olerup and Zetterquist,12 as described by Barreto et al.13
Recellularization assay
First, decellularized vessel fragments of 4 cm were sterilized by washing with PBS supplement with 2% antibiotics (penicillin and streptomycin), followed by a 70% alcohol bath and ultraviolet (UV) light.
For recellularization, 2.5 x 104 SV cells or 2.5 x 104 SV-VEGF cells were seeded above each decellularized vessel fragment for three or seven days, when the cultures were interrupted and the fragments were fixed for cell attachment analysis. Culture was performed with alpha minimum essential medium (α-MEM) (LGC Biotechnology), supplemented with 10% fetal bovine serum and 1% streptomycin/penicillin antibiotic, under 37°C and 5% CO2.
Recellularization validation
To verify cell attachment, some recellularized vessel fragments were DAPI stained and observed under laser confocal microscope (Olympus Fluo View 1000 - FV1000). Other fragments were fixed in Karnovsky (4% PFA and 2.5% glutaraldehyde in 0.1 M sodium cacodylate buffer at pH 7.2) and then post-fixed in 1% osmium tetroxide (SEM R 148- HATFIELD, USA) for 90 minutes. These were then dehydrated in an increasing series of Ethanol under agitation, passed through an automated drying process (MSCPD 300, Leica), and metallized with gold (#K550, Emitech-Ashford, UK). Immunohistochemistry was also performed13 to verify elastin on the vessel wall and VEGF from the SV-VEGF cell line.
Results
After decellularization, no visible nuclei were observed in the vessel fragments, neither by hematoxylin and eosin (HE) nor by DAPI stains (Central Illustration - D2). Moreover, less than 50 ng of gDNA per mg of the decellularized vessel was quantified (Figure 1). Regarding the conservation of the vascular arrangement of the bovine placenta vessels, it was observed, even in vessels up to 5 mm in diameter (Figure 1-F), viewed through scanning electron microscopy, that the decellularized vessels showed structural maintenance and a porous lumen (Central Illustration – A4).
– Decellularization of the bovine placenta vessels: A: bar = 10 cm, placenta dissected, and umbilical artery and vein cannulated. B: bar = 10 cm, beginning of the decellularization process. C-E: bar = 10 cm, progression of decellularization. F: bar = 10 cm, completion of decellularization, with maintenance of the structure. G: genomic deoxyribonucleic acid (gDNA) in the vascular scaffolds of the chorioallantoic surface of the decellularized bovine placenta.
After recellularization, even on day three of the culture, it was possible to observe the cells on the decellularized vessel surface and lumen; however, visually, the number of cells increased on day seven. The SV-VEGF cells were also more numerous than the SV cells, both on day three and seven. Those cells were observed both by HE and DAPI stains (Central Illustration – D1 and F2).
The elastin distribution pattern was similar in native, decellularized, and recellularized placental vessels (Central Illustration – A3, B3 and D3).
Discussion
Bovine placenta is an organ that, after decellularization, can be used as a source of biomaterial, especially vascular scaffolds. Even after the decellularization process, both the cotyledons,13 as well as the chorioallantoic membrane,14 maintained their structure and extracellular matrix composition preserved. Here, we produced decellularized vessels with structure and elastin maintenance, even in small diameter vessels. Those decellularized vessels had cytocompatibility with endothelial precursor cells (SV and SV-VEGF cells), and the morphological and behavioral results of these cell lines had already been described and remain in accordance with those presented by recellularization in other biomaterials, as demonstrated by Fratini et al.15
Furthermore, another alternative to use this decellularized vessel is its digestion to produce biogels that are rich in collagen and can be used to produce bioengineered vessels with different diameters and sizes.6,16,17
Conclusion
The bovine placenta vessels can produce viable and cytocompatible decellularized biomaterials that can be a source of structurally natural vascular biomaterials, as well as future prospects for bioengineered vessels.
Acknowledgements
All microscope imaging was supported by the Advanced Center of Image Diagnosis (CADI-FMVZ-USP).
References
-
1 Malta DC, Silva Jr JB. Brazilian Strategic Action Plan to Combat Chronic Non-Communicable Diseases and the global targets set to confront these diseases by 2025: A Review. Epidemiol Ser Saúde. 2013;22(1):151-64. doi: 10.5123/S1679-49742013000100016.
» https://doi.org/10.5123/S1679-49742013000100016 - 2 Brasil. Plano de Ações Estratégicas para o Enfrentamento das Doenças Crônicas Não Transmissíveis (DCNT) no Brasil 2011-2022. Brasília: Ministério da Saúde; 2011.
- 3 World Health Organization. Global Status Report on Noncommunicable Diseases 2010. Genova: World Health Organization; 2011.
- 4 Imada BC, Chen SR. Regional Vascular Anatomy. In: Gilani R,Mills JL Sr, editors. Vascular Complications of Surgery and Intervention. New York: Springer; 2022. p. 3-35.
- 5 Bertanha M. Perspectivas de Uso de Células-Tronco em Cirurgia Vascular. J Vasc Bras. 2016;15(3):173-5. doi: 10.1590/1677-5449.006516.
- 6 Kolesky DB, Homan KA, Skylar-Scott MA, Lewis JA. Three-Dimensional Bioprinting of Thick Vascularized Tissues. Proc Natl Acad Sci USA. 2016;113(12):3179-84. doi: 10.1073/pnas.1521342113.
- 7 Debbi L, Zohar B, Shuhmaher M, Shandalov Y, Goldfracht I, Levenberg S. Integrating Engineered Macro Vessels with Self-Assembled Capillaries in 3D Implantable Tissue for Promoting Vascular Integration In-Vivo. Biomaterials. 2022;280:121286. doi: 10.1016/j.biomaterials.2021.121286.
- 8 Moore MJ, Tan RP, Yang N, Rnjak-Kovacina J, Wise SG. Bioengineering Artificial Blood Vessels from Natural Materials. Trends Biotechnol. 2022;40(6):693-707. doi: 10.1016/j.tibtech.2021.11.003.
- 9 Solis DM, Czekanski A. 3D and 4D Additive Manufacturing Techniques for Vascular-Like Structures – A Review. Bioprinting. 2022;25: e00182.
- 10 Novosel EC, Kleinhans C, Kluger PJ. Vascularization is the Key Challenge in Tissue Engineering. Adv Drug Deliv Rev. 2011;63(4-5):300-11. doi: 10.1016/j.addr.2011.03.004.
- 11 Fratini P, Carreira AC, Alcântara D, Oliveira e Silva FM, Rodrigues MN, Miglino MA. Endothelial Differentiation of Canine Yolk Sac Cells Transduced with VEGF. Res Vet Sci. 2016;104:71-6. doi: 10.1016/j.rvsc.2015.11.010.
- 12 Olerup O, Zetterquist H. HLA-DR Typing by PCR Amplification with Sequence-Specific Primers (PCR-SSP) in 2 Hours: An Alternative to Serological DR Typing in Clinical Practice Including Donor-Recipient Matching in Cadaveric Transplantation. Tissue Antigens. 1992;39(5):225-35. doi: 10.1111/j.1399-0039.1992.tb01940.x.
- 13 Barreto RDSN, Romagnolli P, Mess AM, Miglino MA. Decellularized Bovine Cotyledons May Serve as Biological Scaffolds with Preserved Vascular Arrangement. J Tissue Eng Regen Med. 2018;12(4):e1880-e1888. doi: 10.1002/term.2618.
- 14 Ballesteros AC, Puello HRS, Lopez-Garcia JA, Bernal-Ballen A, Mosquera DLN, Forero DMM, et al. Bovine Decellularized Amniotic Membrane: Extracellular Matrix as Scaffold for Mammalian Skin. Polymers. 2020;12(3):590. doi: 10.3390/polym12030590.
- 15 Fratini P, Rigoglio NN, Matias GSS, Carreira ACO, Rici REG, Miglino MA. Canine Placenta Recellularized Using Yolk Sac Cells with Vascular Endothelial Growth Factor. Biores Open Access. 2018;7(1):101-6. doi: 10.1089/biores.2018.0014.
- 16 Choudhury D, Tun HW, Wang T, Naing MW. Organ-Derived Decellularized Extracellular Matrix: A Game Changer for Bioink Manufacturing? Trends Biotechnol. 2018;36(8):787-805. doi: 10.1016/j.tibtech.2018.03.003.
- 17 Pati F, Jang J, Ha DH, Won Kim S, Rhie JW, Shim JH, et al. Printing Three-Dimensional Tissue Analogues with Decellularized Extracellular Matrix Bioink. Nat Commun. 2014;5:3935. doi: 10.1038/ncomms4935.
-
Study associationThis article is part of the thesis of doctoral submitted by Tarley Santos Oliveira, from Faculdade de Medicina Veterinária e Zootecnia da Universidade de São Paulo.
-
Sources of funding: This study was funded by Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP number 2014/50844-3) and partially funded by Coordenação de Aperfeiçoamento de Pessoal de Nível Superior.
Publication Dates
-
Publication in this collection
09 June 2023 -
Date of issue
2023
History
-
Received
23 Nov 2022 -
Reviewed
10 Feb 2023 -
Accepted
05 Apr 2023