一个新的模型异位,慢性,活体多光子成像骨髓血管和结构的分裂股骨。

IntraVital Pub Date : 2015-06-30 eCollection Date: 2015-05-01 DOI:10.1080/21659087.2015.1066949
Mirela Bălan, Friedemann Kiefer
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引用次数: 2

摘要

股骨骨髓是成年哺乳动物造血的主要部位,建立一个用于活体可视化的模型是一个严峻的挑战,因为它需要克服骨不透明和骨髓的不可接近性。此外,对骨髓发育和分化过程进行有意义的分析需要长时间重复观察同一部位,我们称之为慢性成像。为了克服这些问题,我们开发了一种慢性活体成像模型,可以观察分离的股骨,异位移植到宿主小鼠的背侧皮褶腔中。通过多光子显微镜进行重复的长期观察,这种成像技术结合了更大组织深度的优越成像能力和低光毒性。移植的异位股骨因其无菌环境而稳定,并迅速连接到宿主脉管系统,允许进一步发展和观察扩展过程。在优化移植年龄和移植程序后,我们观察到移植股骨中新编织骨的发育和二级骨化中心的成熟,在此之前出现了一个几乎完全由股内皮细胞组成的窦状血管网络。两周后,移植细胞仍然充满了供体和宿主的基质细胞和造血细胞。在这段时间内,移植部分保留了具有单系和多系分化能力的骨髓祖细胞。总之,我们的模型允许骨髓血管生成和造血功能的重复活体成像。它代表了一个有希望的起点,为发展改进的慢性光学成像模型的股骨骨髓。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A novel model for ectopic, chronic, intravital multiphoton imaging of bone marrow vasculature and architecture in split femurs.

Creating a model for intravital visualization of femoral bone marrow, a major site of hematopoiesis in adult mammalian organisms, poses a serious challenge, in that it needs to overcome bone opacity and the inaccessibility of marrow. Furthermore, meaningful analysis of bone marrow developmental and differentiation processes requires the repetitive observation of the same site over long periods of time, which we refer to as chronic imaging. To surmount these issues, we developed a chronic intravital imaging model that allows the observation of split femurs, ectopically transplanted into a dorsal skinfold chamber of a host mouse. Repeated, long term observations are facilitated by multiphoton microscopy, an imaging technique that combines superior imaging capacity at greater tissue depth with low phototoxicity. The transplanted, ectopic femur was stabilized by its sterile environment and rapidly connected to the host vasculature, allowing further development and observation of extended processes. After optimizing transplant age and grafting procedure, we observed the development of new woven bone and maturation of secondary ossification centers in the transplanted femurs, preceded by the sprouting of a sinusoidal-like vascular network, which was almost entirely composed of femoral endothelial cells. After two weeks, the transplant was still populated with stromal and haematopoietic cells belonging both to donor and host. Over this time frame, the transplant partially retained myeloid progenitor cells with single and multi-lineage differentiation capacity. In summary, our model allowed repeated intravital imaging of bone marrow angiogenesis and hematopoiesis. It represents a promising starting point for the development of improved chronic optical imaging models for femoral bone marrow.

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