Testis-on-chip platform to study ex vivo primate spermatogenesis and endocrine dynamics

Swati Sharma , Bastien Venzac , Thomas Burgers , Stefan Schlatt , Séverine Le Gac
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引用次数: 3

Abstract

Here, we report a testis-on-chip platform for the ex vivo culture of seminiferous tubules isolated from human and non-human primate testis. Tissues are cultured in a dedicated chamber with continuous perfusion via a vascular-like channel. The platform is fabricated from PDMS using a 3D printed mold, after design has been optimized, e.g., for the barrier between the culture chamber and the perfusion channel. COMSOL modeling revealed no direct negative impact of the flow on the tissues for the applied flowrate in the device, shear rate remaining in the physiological range. Culture experiments were performed using adult human seminiferous tubules from gender dysphoria patients and prepubertal seminiferous tubules from a 6-month-old marmoset for up to 11 and 9 days, respectively. First, microscopic, and live imaging revealed the presence of viable cell populations in both types of samples. Next, marmoset tissues were exposed to stimulatory conditions through perfusion of gonadotropins at different doses. The tissue response was characterized by histological analysis after their recovery from the device and testosterone and estradiol analysis in the effluent. Histological observations suggested improved maintenance of marmoset testicular tissues under stimulatory conditions, which similarly resulted in an increase in both testosterone and estradiol production, with yet different patterns for the low-dose and high-dose stimulation. The herein reported testis-on-chip platform shows great promise to evaluate endocrine and toxic effects on the testis.

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睾丸芯片平台研究体外灵长类动物精子发生和内分泌动力学
在这里,我们报告了一个睾丸芯片平台,用于从人类和非人类灵长类动物睾丸中分离的精管的离体培养。组织在专用腔室中培养,通过血管样通道连续灌注。该平台由PDMS制成,使用3D打印模具,经过优化设计,例如,培养室和灌注通道之间的屏障。COMSOL模型显示,装置中施加的流量对组织没有直接的负面影响,剪切速率保持在生理范围内。培养实验分别使用来自性别焦虑症患者的成人精管和来自6月龄狨猴的青春期前精管进行,培养时间分别为11天和9天。首先,显微镜和实时成像显示,两种类型的样品中都存在活细胞群。接下来,通过灌注不同剂量的促性腺激素,将狨猴组织暴露在刺激条件下。组织反应的特点是组织学分析后,他们从设备和睾丸激素和雌二醇的流出分析恢复。组织学观察表明,在刺激条件下,狨猴睾丸组织的维持得到改善,这同样导致睾酮和雌二醇的产生增加,但低剂量和高剂量刺激的模式不同。本文报道的睾丸芯片平台在评估睾丸内分泌和毒性作用方面显示出很大的希望。
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
Organs-on-a-chip
Organs-on-a-chip Analytical Chemistry, Biochemistry, Genetics and Molecular Biology (General), Cell Biology, Pharmacology, Toxicology and Pharmaceutics (General)
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