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美国卫生研究院文献>Cerebrospinal Fluid Research
>Is solute movement within the extracellular spaces of brain gray matter brought about primarily by diffusion or flow? A commentary on Analysis of convective and diffusive transport in the brain interstitium Fluids and Barriers of the CNS (2019) 16:6 by L. Ray J.J. Iliff and J.J. Heys
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Is solute movement within the extracellular spaces of brain gray matter brought about primarily by diffusion or flow? A commentary on Analysis of convective and diffusive transport in the brain interstitium Fluids and Barriers of the CNS (2019) 16:6 by L. Ray J.J. Iliff and J.J. Heys
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机译:大脑灰质细胞外空间内的溶质运动主要是由扩散或流动引起的吗? L. RayJ.J.的评论中枢神经系统的对流和扩散运输(CNS的液体和屏障)(2019)16:6。 Iliff和J.J.嘿
Solutes can enter and leave gray matter in the brain by perivascular routes. The glymphatic hypothesis supposes that these movements are a consequence of inward flow along periarterial spaces and an equal outward flow along perivenous spaces. The flow through the parenchyma between periarterial and perivenous spaces is the same as the inflow and the outflow. Ray et al. (Fluids Barriers CNS 16:6, ) have investigated how this flow could interact with diffusion using numerical simulations of real-time iontophoresis experiments that monitor the concentrations of tetramethylammonium ions (TMA+) injected into the parenchyma via iontophoresis. For this purpose they have devised a description of the parenchyma incorporating perivascular spaces. Their simulations show that superficial flow velocities of about 50 µm min−1 are needed to produce changes in TMA+ fluxes comparable to those accounted for by diffusion. In the glymphatic hypothesis the proposed flow through the parenchyma can be estimated from the clearance of solutes that are present in the perivenous outflow at the same concentration as in the interstitial fluid of the parenchyma. Reported clearances are approximately 1 µL min−1 g−1. This flow can be converted to a superficial flow velocity using the area available for the flow, which can be estimated using Ray et al.’s description of the tissue as 40 cm2 g−1. The best available estimate of the flow velocity is thus 0.25 µm min−1 which is 200 times smaller than the flow that produces effects comparable to diffusion for TMA+. Thus it follows in Ray et al.’s description of the parenchyma that diffusion rather than flow accounts for TMA+ movements. Because the diffusion constant depends only weakly on molecular weight the same is expected to apply even for solutes somewhat larger than serum albumin.
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机译:溶质可以通过血管周围途径进入和离开大脑灰质。淋巴管假说假设这些运动是沿动脉周围空间向内流动和沿静脉空间相等向外流动的结果。在动脉周围和静脉间隙之间通过薄壁组织的流量与流入和流出相同。雷等。 (Fluids Barriers CNS 16:6,)已经通过实时离子电渗实验的数值模拟研究了这种流动如何与扩散相互作用,该实验监测通过四氟甲烷注入薄壁组织的四甲基铵离子(TMA + )的浓度。离子电渗疗法。为此,他们设计了结合血管周围空间的薄壁组织的描述。他们的模拟表明,要使TMA + 通量产生与扩散相当的变化,需要约50μmmin -1 的表观流速。在淋巴管假说中,可以通过清除存在于静脉流出物中的溶质的浓度来估计通过实质的拟议流量,该溶质的清除浓度与实质的组织液中的浓度相同。报告的间隙约为1 µL min -1 g -1 。可以使用可用于流动的面积将该流量转换为表面流速,可以使用Ray等人将组织的描述估算为40 cm 2 g -1 。因此,最佳的流速估计值是0.25μmmin -1 ,比产生与TMA + 的扩散效果相当的流量小200倍。因此,在Ray等人对薄壁组织的描述中,遵循的是扩散而不是流动是TMA + 运动的原因。由于扩散常数仅在很小的程度上取决于分子量,因此即使对于比血清白蛋白稍大的溶质,也希望采用相同的扩散常数。
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