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Asymmetric Lipid Bilayer01:35

Asymmetric Lipid Bilayer

7.3K
Biological membranes show uneven distribution of different types of lipids in the inner and outer layers, resulting in transverse asymmetric membranes. The treatment of the erythrocyte membrane with the enzyme phospholipase confirmed the asymmetric nature of the lipid bilayer. The enzyme hydrolyzes lipids into fatty acids and hydrophilic groups. The phospholipase acts only on the outer layer of the membrane, while the inner layer remains intact. The phospholipase treatment resulted in 80%...
7.3K
SNAREs and Membrane Fusion01:43

SNAREs and Membrane Fusion

11.0K
Once a transport vesicle has recognized its target organelle, the vesicular membrane needs to fuse with the target membrane to unload the cargo. Transmembrane proteins called SNAREs present on organelle membranes and their vesicles, mediate vesicle fusion.
SNAREs exist in pairs that symmetrically interact and catalyze the fusion of the lipid bilayers in vesicle and target organelle. v-SNARE in the vesicle membrane are single polypeptide chains that bind to a complementary t-SNARE, composed of 2...
11.0K
Mechanisms of Drug Absorption: Paracellular, Transcellular, and Vesicular Transport01:23

Mechanisms of Drug Absorption: Paracellular, Transcellular, and Vesicular Transport

592
Drugs need to permeate cell membranes to reach their target sites after administration. Orally administered drugs must transcend intestinal epithelial membrane barriers to infiltrate the systemic circulation. Drugs with a molecular weight of less than 500 Daltons diffuse through gaps between neighboring cells, called paracellular pathways.
However, most drugs use the transcellular route, traversing directly through the cell membranes via two mechanisms: passive and active transport. Passive...
592
Pore Transport and Ion-Pair Transport01:17

Pore Transport and Ion-Pair Transport

515
Pore transport and ion-pair formation are critical mechanisms for the absorption and distribution of drugs in the body.
Pore transport, also known as convective transport, is a process where small molecules like urea, water, and sugars rapidly cross cell membranes as though there were channels or pores in the membrane. Although direct microscopic evidence is limited  but the concept of pores or channels is widely accepted based on physiological evidence. Despite the lack of direct...
515
Fluid Mosaic Model01:19

Fluid Mosaic Model

12.0K
Scientists identified the plasma membrane in the 1890s and its principal chemical components (lipids and proteins) by 1915. The model for plasma membrane structure, proposed in 1935 by Hugh Davson and James Danielli, was the first model to be widely accepted in the scientific community. The model was based on the plasma membrane's "railroad track" appearance in early electron micrographs. Davson and Danielli theorized that the plasma membrane's structure resembled a sandwich...
12.0K
Membrane Fluidity01:26

Membrane Fluidity

11.3K
Membrane fluidity is explained by the fluid mosaic model of the cell membrane, which describes the plasma membrane structure as a mosaic of components—including phospholipids, cholesterol, proteins, and carbohydrates—that gives the membrane a fluid character.
Mosaic nature of the membrane
The mosaic characteristic of the membrane helps the plasma membrane remain fluid. The integral proteins and lipids exist as separate but loosely-attached molecules in the membrane. The membrane is...
11.3K

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相关实验视频

Updated: Jul 21, 2025

Phase Behavior of Charged Vesicles Under Symmetric and Asymmetric Solution Conditions Monitored with Fluorescence Microscopy
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Phase Behavior of Charged Vesicles Under Symmetric and Asymmetric Solution Conditions Monitored with Fluorescence Microscopy

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在选择性透气气囊中的水性两相系统.

Berta Tinao1, Juan L Aragones1, Laura R Arriaga1

  • 1Department of Theoretical Condensed Matter Physics, Condensed Matter Physics Center (IFIMAC) and Instituto Nicolás Cabrera, Universidad Autónoma de Madrid, 28049 Madrid, Spain.

ACS macro letters
|July 27, 2023
PubMed
概括
此摘要是机器生成的。

微流体囊泡可以创建可调节的水性双相系统 (ATPS),用于研究相位行为. 透膜可以动态控制相位分离,模仿细胞过程.

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In vitro Reconstitution of Cytoskeletal Networks inside Phase Separated Giant Unilamellar Vesicles (GUVs)
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In vitro Reconstitution of Cytoskeletal Networks inside Phase Separated Giant Unilamellar Vesicles (GUVs)

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Lipid Bilayer Vesicle Generation Using Microfluidic Jetting
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Lipid Bilayer Vesicle Generation Using Microfluidic Jetting

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相关实验视频

Last Updated: Jul 21, 2025

Phase Behavior of Charged Vesicles Under Symmetric and Asymmetric Solution Conditions Monitored with Fluorescence Microscopy
10:08

Phase Behavior of Charged Vesicles Under Symmetric and Asymmetric Solution Conditions Monitored with Fluorescence Microscopy

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In vitro Reconstitution of Cytoskeletal Networks inside Phase Separated Giant Unilamellar Vesicles (GUVs)
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In vitro Reconstitution of Cytoskeletal Networks inside Phase Separated Giant Unilamellar Vesicles (GUVs)

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Lipid Bilayer Vesicle Generation Using Microfluidic Jetting
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Lipid Bilayer Vesicle Generation Using Microfluidic Jetting

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科学领域:

  • 生物物理学的生物物理.
  • 化学工程是化学工程的重要组成部分.
  • 细胞生物学 细胞生物学

背景情况:

  • 水性双相系统 (ATPS) 对于分离生物分子至关重要.
  • 囊泡为研究复杂系统提供了分隔.
  • 了解动态相位行为是细胞功能的关键.

研究的目的:

  • 开发微流体囊泡用于封装和研究ATPS.
  • 为了研究膜透度对ATPS动态的影响.
  • 探索ATPS动态在细胞过程中的潜力.

主要方法:

  • 使用微流体技术生成封装ATPS的囊泡.
  • 使用具有对ATPS组件选择性透性的膜.
  • 在受控的外流条件下观察相隔动态.

主要成果:

  • 囊泡有效地封装大分子混合物用于ATPS相位行为分析.
  • 选择性膜透性允许控制逆转超出平衡的相位分离.
  • 通过组件外流证明了相位分离的自发逆转.

结论:

  • 微流体ATPS囊泡为研究相位动力学提供了一个多功能平台.
  • 可以利用膜控制的ATPS动态来进行细胞分离.
  • 这项工作提供了关于调节细胞代谢和信号通路的见解.