Physiologic Doses of Transforming Growth Factor-β Improve the Composition of Engineered Articular Cartilage.

IF 3.5 3区 医学 Q3 CELL & TISSUE ENGINEERING
Tianbai Wang, Sedat Dogru, Zhonghao Dai, Sung Yeon Kim, Nicholas A Vickers, Michael B Albro
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Abstract

Conventionally, for cartilage tissue engineering applications, transforming growth factor beta (TGF-β) is administered at doses that are several orders of magnitude higher than those present during native cartilage development. While these doses accelerate extracellular matrix (ECM) biosynthesis, they may also contribute to features detrimental to hyaline cartilage function, including tissue swelling, type I collagen (COL-I) deposition, cellular hypertrophy, and cellular hyperplasia. In contrast, during native cartilage development, chondrocytes are exposed to moderate TGF-β levels, which serve to promote strong biosynthetic enhancements while mitigating risks of pathology associated with TGF-β excesses. Here, we examine the hypothesis that physiologic doses of TGF-β can yield neocartilage with a more hyaline cartilage-like composition and structure relative to conventionally administered supraphysiologic doses. This hypothesis was examined on a model system of reduced-size constructs (∅2 × 2 mm or ∅3 × 2 mm) comprised of bovine chondrocytes encapsulated in agarose, which exhibit mitigated TGF-β spatial gradients allowing for an evaluation of the intrinsic effect of TGF-β doses on tissue development. Reduced-size (∅2 × 2 mm or ∅3 × 2 mm) and conventional-size constructs (∅4-∅6 mm × 2 mm) were subjected to a range of physiologic (0.1, 0.3, 1 ng/mL) and supraphysiologic (3, 10 ng/mL) TGF-β doses. At day 56, the physiologic 0.3 ng/mL dose yielded reduced-size constructs with native cartilage-matched Young's modulus (EY) (630 ± 58 kPa) and sulfated glycosaminoglycan (sGAG) content (5.9 ± 0.6%) while significantly increasing the sGAG-to-collagen ratio, leading to significantly reduced tissue swelling relative to constructs exposed to the supraphysiologic 10 ng/mL TGF-β dose. Furthermore, reduced-size constructs exposed to the 0.3 ng/mL dose exhibited a significant reduction in fibrocartilage-associated COL-I and a 77% reduction in the fraction of chondrocytes present in a clustered morphology, relative to the supraphysiologic 10 ng/mL dose (p < 0.001). EY was significantly lower for conventional-size constructs exposed to physiologic doses due to TGF-β transport limitations in these larger tissues (p < 0.001). Overall, physiologic TGF-β appears to achieve an important balance of promoting requisite ECM biosynthesis, while mitigating features detrimental to hyaline cartilage function. While reduced-size constructs are not suitable for the repair of clinical-size cartilage lesions, insights from this work can inform TGF-β dosing requirements for emerging scaffold release or nutrient channel delivery platforms capable of achieving uniform delivery of physiologic TGF-β doses to larger constructs required for clinical cartilage repair.

生理剂量的 TGF-β 可改善人造关节软骨的组成。
传统上,在软骨组织工程应用中,TGF-β 的剂量比原生软骨发育过程中的剂量高出几个数量级。虽然这些剂量会加速细胞外基质(ECM)的生物合成,但也可能导致对透明软骨功能不利的特征,包括组织肿胀、I型胶原(COL-I)沉积、细胞肥大和细胞增生。与此相反,在软骨的原生发育过程中,软骨细胞暴露于适度的 TGF-β 水平,这有助于促进生物合成的强大功能,同时降低与 TGF-β 过量相关的病理风险。在此,我们研究了一个假设,即生理剂量的 TGF-β 可产生新软骨,其成分和结构与传统的超生理剂量相比更类似于透明软骨。我们在琼脂糖包裹的牛软骨细胞组成的缩小尺寸构建体(Ø2×2 毫米或 Ø3×2毫米)模型系统中检验了这一假设,该构建体显示出减轻的 TGF-β 空间梯度,从而可以评估 TGF-β 剂量对组织发育的内在影响。对缩小尺寸(Ø2×2mm 或 Ø3×2mm)和常规尺寸的构建体(Ø4-Ø6mm×2mm)施加一系列生理(0.1、0.3、1ng/mL)和超生理(3、10ng/mL)TGF-β剂量。第56天时,生理剂量为0.3ng/mL的构建物尺寸缩小,杨氏模量(EY)(630±58kPa)和硫酸化GAG(sGAG)含量(5.9±0.6%)与原生软骨相匹配,同时sGAG与胶原比率显著增加,与暴露于超生理剂量10ng/mL TGF-β的构建物相比,组织肿胀明显减少。此外,与超生理剂量 10ng/mL 相比,暴露于 0.3ng/mL 剂量的小尺寸构建体显示出纤维软骨相关 COL-I 的显著减少,以及以成团形态存在的软骨细胞比例减少了 77%(由于 TGF-β 在这些较大组织中的运输限制,暴露于生理剂量的常规尺寸构建体的 pY 显著较低(p.1))。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Tissue Engineering Part A
Tissue Engineering Part A Chemical Engineering-Bioengineering
CiteScore
9.20
自引率
2.40%
发文量
163
审稿时长
3 months
期刊介绍: Tissue Engineering is the preeminent, biomedical journal advancing the field with cutting-edge research and applications that repair or regenerate portions or whole tissues. This multidisciplinary journal brings together the principles of engineering and life sciences in the creation of artificial tissues and regenerative medicine. Tissue Engineering is divided into three parts, providing a central forum for groundbreaking scientific research and developments of clinical applications from leading experts in the field that will enable the functional replacement of tissues.
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