利用组织粘连屏障对组织瓣进行非破坏性、连续的活体成像

IntraVital Pub Date : 2012-07-01 DOI:10.4161/intv.21769
M. Kotsuma, N. Parashurama, B. Smith, John G. Wo, Ken Ito, S. Gambhir
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引用次数: 9

摘要

活体显微术(IVM)是活体动态事件成像的强大工具,得益于各种组织制备技术的灵活性。例如,“组织瓣”(tissue flap, TF)方法最初只需要很少的组织准备,就能提供高空间分辨率和生理成像,但连续的TF成像大大增加了病理性炎症的影响,导致术后粘连和组织损伤。我们采用了材料科学的方法,在转基因荧光小鼠正常和发育中的乳房以及荧光原位小鼠淋巴瘤模型的连续成像过程中,在TF下植入了一种市买的薄膜生物聚合物组织粘附屏障(TAB)。我们术后在TF下方应用TAB将TF与腹膜分离。当每3-4天重新成像TF,每次放置新的标签,我们观察到出血减少,纤维结缔组织和软组织损伤。TAB的存在可以在短时间间隔内对正骨位置的EGFP+-淋巴瘤细胞和相关的脉管系统进行顺序成像。特别是,随着时间的推移,它可以可视化和跟踪成年小鼠和发育小鼠乳腺中相同的单个荧光分支;同样,它也能追踪淋巴结。我们的结论是,这种简单的方法提供了巨大的潜力,以连续跟踪罕见的,微观的,组织范围内的事件在薄壁组织或间质。潜在的应用包括跟踪移植癌细胞的增殖和运动,干细胞驱动的组织生长,以及高空间和时间分辨率的肿瘤细胞-基质细胞相互作用。
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Nondestructive, serial in vivo imaging of a tissue-flap using a tissue adhesion barrier
Intravital Microscopy (IVM) is a powerful tool for imaging of dynamic events in living subjects and benefits from flexibility of various tissue preparation techniques. For example, a “tissue flap” (TF) approach initially affords high spatial resolution and physiological imaging with minimal tissue preparation, but serial TF imaging greatly increases the effects of pathological inflammation, resulting in postoperative adhesions and tissue injury. We took a materials science approach by implanting a commercially available, thin film, biopolymer tissue adhesion barrier (TAB) beneath the TF during serial imaging of the normal and developing breast in transgenic fluorescent mice, and with a fluorescent orthotopic mouse lymphoma model. We applied the TAB post-operatively beneath the TF to isolate the TF from the underlying peritoneum. When re-imaging the TF every 3–4 d, with a new TAB placed each time, we observed reduced hemorrhage, fibrous connective tissue and soft tissue damage. The presence of the TAB enabled sequential imaging of orthopically located EGFP+-lymphoma cells and associated vasculature at short intervals. In particular, it enabled visualization and tracking of the same individual fluorescent branches of the mammary gland in both adult and developing mice over time; likewise, it enabled tracking of lymph nodes. We conclude that this simple method affords great potential to serially track rare, microscopic, tissue-wide events in parenchyma or stroma. Potential applications include tracking proliferation and motility of transplanted cancer cells, stem cell-driven tissue growth, and tumor cell-stromal cell interactions at high spatial and temporal resolution.
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