Decellularisation and Characterisation of Porcine Pleura as Bioscaffolds in Tissue Engineering

IF 3.1 3区 生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Thirapurasundari Vikranth, Tina Dale, Nicholas R. Forsyth
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引用次数: 0

Abstract

Persistent air leaks caused by thoracic surgery, physical trauma, or spontaneous pneumothoraces are a cause of patient morbidity with need for extended chest tube durations and surgical interventions. Current treatment measures involve mechanical closure of air leaks in the compromised pleura. Organ and membrane decellularisation offers a broad range of biomimetic scaffolds of allogeneic and xenogeneic origins, exhibiting innate tissue-specific characteristics. We explored a physicochemical method for decellularising porcine pleural membranes (PPM) as potential tissue-engineered surrogates for lung tissue repair. Decellularised PPM (dPPM) was characterised with histology, quantitative assays, mechanical testing, and sterility evaluation. Cytotoxicity and recellularisation assays assessed biocompatibility of decellularised PPM (dPPM). Haematoxylin and Eosin (H&E) staining showed an evident reduction in stained nuclei in the dPPM, confirmed with nuclear staining and analysis ( ∗∗∗∗p < 0.0001). Sulphated glycosaminoglycans (sGAG) and collagen histology demonstrated minimal disruption to the gross structural assembly of core extracellular matrix (ECM) in dPPM. Confocal imaging demonstrated realignment of ECM fibres in dPPM against native control. Quantitative analysis defined a significant change in the angular distribution ( ∗∗∗∗p < 0.0001) and coherence ( ∗∗∗p < 0.001) of fibre orientations in dPPM versus native ECM. DNA quantification indicated ≥85% reduction in native nuclear dsDNA in dPPM ( ∗∗p < 0.01). Collagen and sGAG quantification indicated reductions of both ( ∗∗p < 0.01). dPPM displayed increased membrane thickness ( ∗∗∗p < 0.001). However, Young’s modulus (459.67 ± 10.36 kPa) and ultimate tensile strength (4036.22 ± 155.1 kPa) of dPPM were comparable with those of native controls at (465.82 ± 10.51 kPa) and (3912.9 ± 247.42 kPa), respectively. In vitro cytotoxicity and scaffold biocompatibility assays demonstrated robust human mesothelial cell line (MeT-5A) attachment and viability. DNA quantification in reseeded dPPM with MeT-5A cells exhibited significant increase in DNA content at day 7 ( ∗∗p < 0.01) and day 15 ( ∗∗∗∗p < 0.0001) against unseeded dPPM. Here, we define a decellularisation protocol for porcine pleura that represents a step forward in their potential tissue engineering applications as bioscaffolds.

Abstract Image

猪胸膜作为组织工程中的生物支架的脱细胞和特性分析
胸腔手术、物理创伤或自发性气胸造成的持续漏气是导致患者发病的原因之一,患者需要延长胸管插管时间和进行手术干预。目前的治疗措施包括用机械方法关闭受损胸膜上的气漏。器官和膜脱细胞为异体和异种来源的生物仿生支架提供了广泛的选择,并表现出与生俱来的组织特异性。我们探索了一种将猪胸膜(PPM)脱细胞的理化方法,将其作为肺组织修复的潜在组织工程代用品。脱细胞猪胸膜(dPPM)通过组织学、定量检测、机械测试和无菌评估进行表征。细胞毒性和再细胞化试验评估了脱细胞 PPM(dPPM)的生物相容性。血色素和伊红(H&E)染色显示,dPPM 中染色的细胞核明显减少,核染色和分析证实了这一点 ( ∗∗∗∗p < 0.0001)。硫酸化糖胺聚糖(sGAG)和胶原组织学显示,dPPM 中细胞外基质(ECM)核心结构组装的破坏极小。共焦成像显示,与原生对照组相比,dPPM 中的 ECM 纤维重新排列。定量分析确定了 dPPM 与原生 ECM 相比,纤维方向的角度分布 ( ∗∗∗∗p < 0.0001) 和连贯性 ( ∗∗∗p < 0.001) 发生了显著变化。DNA 定量表明,dPPM 中的原生核 dsDNA 减少了≥85%(∗∗∗p < 0.01)。胶原蛋白和 sGAG 定量表明两者都减少了(∗∗∗p < 0.01)。然而,dPPM 的杨氏模量(459.67 ± 10.36 kPa)和极限拉伸强度(4036.22 ± 155.1 kPa)分别为(465.82 ± 10.51 kPa)和(3912.9 ± 247.42 kPa),与原生对照组相当。体外细胞毒性和支架生物相容性测试表明,人间皮细胞系(MeT-5A)附着力和存活率很强。与未铺设的 dPPM 相比,在第 7 天(∗∗p < 0.01)和第 15 天(∗∗∗∗p < 0.0001),重新铺设的带有 MeT-5A 细胞的 dPPM 中的 DNA 定量显示 DNA 含量显著增加。在此,我们确定了猪胸膜的脱细胞方案,这代表着猪胸膜作为生物支架的潜在组织工程应用向前迈进了一步。
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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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