| Generation of the Compression-induced Dedifferentiated Adipocytes (CiDAs) Using Hypertonic Medium
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Author:
Date:
2021-02-20
[Abstract] Current methods to obtain mesenchymal stem cells (MSCs) involve sampling, culturing, and expanding of primary MSCs from adipose, bone marrow, and umbilical cord tissues. However, the drawbacks are the limited numbers of total cells in MSC pools, and their decaying stemness during in vitro expansion. As an alternative resource, recent ceiling culture methods allow the generation of dedifferentiated fat cells (DFATs) from mature adipocytes. Nevertheless, this process of spontaneous dedifferentiation of mature adipocytes is laborious and time-consuming. This paper describes a modified protocol for in vitro dedifferentiation of adipocytes by employing an additional physical stimulation, which takes advantage of augmenting the stemness-related Wnt/β-catenin signaling. Specifically, this ...
[摘要] [摘要]目前的方法,以获得间充质干细胞(MSC)包括采样,培养,和扩大主要由脂肪,骨髓,和脐带组织的MSCs。然而,缺点是在总细胞在MSC池,和它们的衰减干性的数量有限在维生素- [R Ò扩张。作为替代资源,最近的天花板培养方法允许从成熟的脂肪细胞中生成去分化的脂肪细胞(DFAT)。然而,这种成熟脂肪细胞自发去分化的过程既费力又费时。本文描述了一种用于经修改协议在体外通过采用附加的物理刺激,其中脂肪细胞去分化TA KES扩充所述干性相关的优点的Wnt /β-catenin信号。具体来说,该协议利用含聚乙二醇(PEG)的高渗介质引入细胞外物理刺激以获得更高的效率,并引入更简单的脂肪细胞去分化程序。
[背景]脂肪组织由于其丰度大且侵袭性相对较低,因此是间充质干细胞(MSC)最具吸引力的来源之一(Shen等,2011 ;González-Cruz等,2012; Konno等人,2013)。脂肪来源的MSC,即从皮下脂肪组织的基质血管级分中分离,已被证实同时显示多谱系潜能的体外和体内(Anghileri等人,2008;冈萨雷斯。等人,2009;冈萨雷斯-雷伊等等人,2010; Jumabay等人,2010; Mao等人,2017和2019 ;Darnell等人,2018 ...
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| Hair Follicle Stem Cell Isolation and Expansion
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Author:
Date:
2018-05-20
[Abstract] Stem cells are widely used for numerous clinical applications including limbal stem cell deficiency. Stem cell derived from the bulge region of the hair follicle have the ability to differentiate into a variety of cell types including interfollicular epidermis, hair follicle structures, sebaceous glands and corneal epithelial cells when provided the appropriate cues. Hair follicle stem cells are being studied as a valuable source of autologous stem cells to treat disease. The protocol described below details the isolation and expansion of these cells for eventual clinical application. We used a dual-reporter mouse model to visualize both isolation and eventual differentiation of these cells in a limbal stem cell-deficient mouse model.
[摘要] 干细胞被广泛用于许多临床应用,包括角膜缘干细胞缺陷。 当提供适当的提示时,源自毛囊凸出区域的干细胞具有分化成多种细胞类型的能力,包括滤泡间表皮,毛囊结构,皮脂腺和角膜上皮细胞。 正在研究毛囊干细胞作为自体干细胞治疗疾病的宝贵来源。 下面描述的方案详细描述了这些细胞的最终临床应用的分离和扩增。 我们使用双报告小鼠模型来观察这些细胞在角膜缘干细胞缺陷小鼠模型中的分离和最终分化。
【背景】干细胞被广泛用于多种翻译和临床应用。一种这样的临床应用是用于治疗角膜缘干细胞缺陷(LSCD)。当角膜缘干细胞群存在功能障碍或丧失时,LSCD发生,这对于由于先天性或获得性病理而维持健康的眼表非常重要。 LSCD的主要治疗策略是从患者健康眼睛的角膜缘活检组织培养自体上皮细胞片(Pellegrini等人,1997; Shortt等人,2007) 。这种策略的局限性在于它只适用于患有单侧LSCD的患者。那些有双侧LSCD的患者必须依靠免疫相关活体供体或尸体组织的同种异体角膜缘活检。由于全身性免疫抑制治疗的需要和供体组织的有限可用性,治疗成功率降低。一些研究小组一直在研究使用培养的口腔粘膜细胞治疗LSCD并取得了一些成功。然而,这些细胞通常不能表达角膜上皮分化标记角蛋白12(Inatomi等,2006),并且经常导致外周血管新生的发展(Nakamura等人, ,2004; ...
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| Dual-sided Voltage-sensitive Dye Imaging of Leech Ganglia
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Author:
Date:
2018-03-05
[Abstract] In this protocol, we introduce an effective method for voltage-sensitive dye (VSD) loading and imaging of leech ganglia as used in Tomina and Wagenaar (2017). Dissection and dye loading procedures are the most critical steps toward successful whole-ganglion VSD imaging. The former entails the removal of the sheath that covers neurons in the segmental ganglion of the leech, which is required for successful dye loading. The latter entails gently flowing a new generation VSD, VF2.1(OMe).H, onto both sides of the ganglion simultaneously using a pair of peristaltic pumps. We expect the described techniques to translate broadly to wide-field VSD imaging in other thin and relatively transparent nervous systems.
[摘要] 在这个协议中,我们介绍了一种有效的方法,用于Tomina和Wagenaar(2017)中使用的电压敏感染料(VSD)加载和水蛭神经节成像。 解剖和染料加载程序是成功完成全神经节VSD成像的关键步骤。 前者需要去除覆盖水蛭节段神经节神经元的鞘,这是成功染料加载所需的。 后者需要使用一对蠕动泵同时轻柔地将新一代VSD VF2.1(OMe).H流入神经节的两侧。 我们期望所描述的技术广泛地转化为其他薄且相对透明的神经系统中的宽视场VSD成像。
【背景】双面显微镜是一种宽视野荧光成像系统,由一对精确对准的显微镜组成,用于观察来自对面的神经元制剂并且一次显示不同的焦平面(Tomina and Wagenaar,2017)。通过将该光学系统与新一代电压敏感染料(VSD),VoltageFluor(Miller等人,2012; Woodford等人,2015),荧光可以同时从不同深度的神经元捕获编码具有高保真度膜电压的信号。我们将这种泛神经元记录系统应用于药用水蛭的神经系统,我们利用电生理学方法诱发虚构行为并定量控制可识别神经元的膜电位(Tomina and ...
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