Dual optical elastography detects TGF - β -induced alterations in the biomechanical properties of skin scaffolds.

IF 3 3区 医学 Q2 BIOCHEMICAL RESEARCH METHODS Journal of Biomedical Optics Pub Date : 2024-09-18 DOI:10.1117/1.jbo.29.9.095002
Taye T Mekonnen,Yogeshwari S Ambekar,Christian Zevallos-Delgado,Achuth Nair,Fernando Zvietcovich,Hoda Zarkoob,Manmohan Singh,Yi Wei Lim,Marc Ferrer,Salavat R Aglyamov,Giuliano Scarcelli,Min Jae Song,Kirill V Larin
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Abstract

Significance The skin's mechanical properties are tightly regulated. Various pathologies can affect skin stiffness, and understanding these changes is a focus in tissue engineering. Ex vivo skin scaffolds are a robust platform for evaluating the effects of various genetic and molecular interactions on the skin. Transforming growth factor-beta ( TGF - β ) is a critical signaling molecule in the skin that can regulate the amount of collagen and elastin in the skin and, consequently, its mechanical properties. Aim This study investigates the biomechanical properties of bio-engineered skin scaffolds, focusing on the influence of TGF - β , a signaling molecule with diverse cellular functions. Approach The TGF - β receptor I inhibitor, galunisertib, was employed to assess the mechanical changes resulting from dysregulation of TGF - β . Skin scaffold samples, grouped into three categories (control, TGF - β -treated, and TGF - β + galunisertib-treated), were prepared in two distinct culture media-one with aprotinin (AP) and another without. Two optical elastography techniques, namely wave-based optical coherence elastography (OCE) and Brillouin microscopy, were utilized to quantify the biomechanical properties of the tissues. Results Results showed significantly higher wave speed (with AP, p < 0.001 ; without AP, p < 0.001 ) and Brillouin frequency shift (with AP, p < 0.001 ; without AP, p = 0.01 ) in TGF - β -treated group compared with the control group. The difference in wave speed between the control and TGF - β + galunisertib with ( p = 0.10 ) and without AP ( p = 0.36 ) was not significant. Moreover, the TGF - β + galunisertib-treated group exhibited lower wave speed without and with AP and reduced Brillouin frequency shift than the TGF - β -treated group without AP, further strengthening the potential role of TGF - β in regulating the mechanical properties of the samples. Conclusions These findings offer valuable insights into TGF - β -induced biomechanical alterations in bio-engineered skin scaffolds, highlighting the potential of OCE and Brillouin microscopy in the development of targeted therapies in conditions involving abnormal tissue remodeling and fibrosis.
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双光学弹性成像技术可检测 TGF - β 诱导的皮肤支架生物力学特性变化。
意义皮肤的机械特性受到严格调控。各种病变都会影响皮肤硬度,了解这些变化是组织工程学的重点。体外皮肤支架是评估各种基因和分子相互作用对皮肤影响的可靠平台。转化生长因子-β(TGF - β)是皮肤中的一种关键信号分子,它能调节皮肤中胶原蛋白和弹性蛋白的数量,进而调节皮肤的机械性能。方法采用 TGF - β 受体 I 抑制剂 galunisertib 来评估 TGF - β 失调导致的力学变化。皮肤支架样本分为三类(对照组、TGF - β 处理组和 TGF - β + 加仑尼塞替布处理组),分别在两种不同的培养基中制备--一种含有阿普罗宁(AP),另一种没有。结果表明,与对照组相比,TGF - β 处理组的波速(含 AP,p < 0.001;不含 AP,p < 0.001)和布里渊频移(含 AP,p < 0.001;不含 AP,p = 0.01)明显更高。对照组与 TGF - β + galunisertib(有 AP 时)(p = 0.10)和无 AP 时(p = 0.36)的波速差异不显著。此外,TGF - β + galunisertib 处理组在无 AP 和有 AP 的情况下波速较低,布里渊频移较无 AP 的 TGF - β 处理组小,这进一步加强了 TGF - β 在调节样品机械性能方面的潜在作用。结论 这些发现为了解 TGF - β 在生物工程皮肤支架中诱导的生物力学改变提供了有价值的见解,凸显了 OCE 和布里渊显微镜在开发涉及异常组织重塑和纤维化的靶向疗法方面的潜力。
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来源期刊
CiteScore
6.40
自引率
5.70%
发文量
263
审稿时长
2 months
期刊介绍: The Journal of Biomedical Optics publishes peer-reviewed papers on the use of modern optical technology for improved health care and biomedical research.
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