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相关概念视频

Fluid Movement Between Compartments01:18

Fluid Movement Between Compartments

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The force applied by fluids against a surface, known as hydrostatic pressure, initiates the transfer of fluid among different compartments. Within our blood vessels, the blood's hydrostatic pressure is a result of the heart's pumping action. At the arteriolar end of capillaries, hydrostatic pressure (capillary blood pressure) exceeds the opposing colloid osmotic pressure created primarily by plasma proteins like albumin. This discrepancy in pressure propels plasma and nutrients from the...
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Capillarity in Fluid01:19

Capillarity in Fluid

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Capillarity describes the movement of liquid in small spaces without external forces acting on it. The capillarity is driven by surface tension and adhesive interactions between the liquid and surrounding solid surfaces. This effect is often seen in narrow tubes, porous materials, and fine particles.
Surface tension is crucial to capillarity. It results from cohesive forces between liquid molecules at the liquid-air boundary, forming a skin that resists external forces. When the capillary tube...
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Types of Fluids01:27

Types of Fluids

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Fluids can be classified into Newtonian and non-Newtonian fluids based on their response to shear stress. Newtonian fluids have a linear relationship between shear stress and the shear strain rate, following Newton's law of viscosity. Their viscosity remains constant regardless of the shear rate, making their behavior predictable and easier to analyze. Common examples include water, air, oil, and gasoline.
In contrast, non-Newtonian fluids do not follow Newton's law of viscosity, and...
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The Fluid Mosaic Model01:34

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The fluid mosaic model was first proposed as a visual representation of research observations. The model comprises the composition and dynamics of membranes and serves as a foundation for future membrane-related studies. The model depicts the structure of the plasma membrane with a variety of components, which include phospholipids, proteins, and carbohydrates. These integral molecules are loosely bound, defining the cell’s border and providing fluidity for optimal function.
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Transcellular transport of solutes is the movement of substances like monosaccharides and amino acids through polarized cells. This transport mechanism is primarily seen in epithelial and endothelial cells aided by membrane transport proteins such as channels and transporters. The tight junctions between these cells confine the membrane proteins to the two sides of the cell. The epithelial cells have distinct apical and basolateral domains. In contrast, the endothelial cells show the luminal...
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Characteristics of Fluids

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Fluids differ from solids primarily in their molecular structure and stress response. Solids have tightly packed molecules with strong intermolecular forces, maintaining their shape and resisting deformation. In contrast, fluids have molecules spaced farther apart with weaker forces, allowing them to flow and deform easily.
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Updated: Oct 31, 2025

BioMEMS and Cellular Biology: Perspectives and Applications
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BioMEMS and Cellular Biology: Perspectives and Applications

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细胞流体

Nikola A Dudukovic1, Erika J Fong1, Hawi B Gemeda1

  • 1Lawrence Livermore National Laboratory, Livermore, CA, USA.

Nature
|July 1, 2021
PubMed
概括
此摘要是机器生成的。

细胞流体利用3D打印的单元细胞结构来精确控制多相流,运输和反应. 这种创新平台可以为气液运输和选择性物质沉积等应用程序编程流体行为.

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科学领域:

  • 多相流和反应工程
  • 生物启发和仿生系统
  • 先进的材料和制造

背景情况:

  • 自然系统在各种尺度上表现出优化的多相传输.
  • 现有的微流体设备在工程复杂的多相过程中是有限的.
  • 复制流体控制的生物系统仍然是一个重大挑战.

研究的目的:

  • 介绍细胞流体作为确定性多相流量控制的新平台.
  • 通过结构化的细胞设计来证明流体运输的可编程性.
  • 探索气体液体运输,蒸发冷却和二氧化碳捕获中的应用.

主要方法:

  • 开发用于流体控制的基于单元细胞的3D打印结构.
  • 细胞类型,大小和密度的设计,以编程流动行为.
  • 气体-液体运输,毛细管驱动的流量和主动的实验演示.
  • 选择性金属化用于细胞流体装置中的模式生成.

主要成果:

  • 已证明可编程的气液传输,包括透气和吸收.
  • 在3D细胞流体设备中展示了优选的液体和气体路径.
  • 在预先编程的模式上实现选择性金属化.
  • 通过设计和预测建模验证了流体运输的确定性控制.

结论:

  • 细胞流体提供精确的可编程控制多相运输和3D反应.
  • 建筑细胞材料与预测建模相结合是确定性流体控制的关键.
  • 这种平台有可能在多相过程中彻底改变空间和时间控制.