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相关概念视频

Passive Diffusion: Overview and Kinetics01:17

Passive Diffusion: Overview and Kinetics

379
Passive diffusion is a critical process that allows small lipophilic drugs to cross the cell membrane along a concentration gradient. This mechanism's efficiency depends on four primary factors: the membrane's surface area, the drug's lipid-water partition coefficient, the concentration gradient, and the membrane's thickness.
When administered orally, drugs establish a substantial concentration gradient between the gastrointestinal (GI) lumen and the bloodstream, expediting...
379
Drug Absorption Mechanism: Passive Membrane Transport01:23

Drug Absorption Mechanism: Passive Membrane Transport

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Passive transport is a method of drug absorption where small, lipid-soluble drugs can move across the cell membrane. This movement happens along the concentration gradient, which is a natural flow from higher to lower concentration areas. The speed at which the drug moves is directly related to its lipid–water partition coefficient. This means that the more a drug dissolves in lipids, the faster it diffuses or spreads throughout the body. It is important to note that most drugs are either...
3.6K
Cellular Membranes and Drug Transport01:24

Cellular Membranes and Drug Transport

266
Drugs must traverse multiple biological barriers, such as multi-layered skin, single-layered intestinal epithelium, and the plasma membrane, to reach their target sites within the body. The plasma membrane, a highly structured composite of phospholipids, carbohydrates, and proteins, is the cell's protective boundary, facilitating selective substance exchange.
Phospholipids arrange themselves into a bilayer, with hydrophilic heads oriented outward and hydrophobic tails facing inward.
266
Mechanisms of Drug Absorption: Paracellular, Transcellular, and Vesicular Transport01:23

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

376
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...
376
Physiological Pharmacokinetic Models: Incorporating Hepatic Transporter-Mediated Clearance01:07

Physiological Pharmacokinetic Models: Incorporating Hepatic Transporter-Mediated Clearance

26
Drug transporters are critical in drug absorption, distribution, and excretion processes. They should be included in physiological-based pharmacokinetic (PBPK) models, which help predict human drug disposition. However, predicting this is challenging during drug development, especially when liver transport is involved. However, with a realistic representation of body transport processes, an accurate model may be possible.
A recent model describes pravastatin's hepatobiliary excretion,...
26
Drug Delivery: Overview01:16

Drug Delivery: Overview

276
The selection of a drug's delivery route depends upon its physicochemical properties, including lipid or water solubility and ionization, as well as the therapeutic requirement, such as immediate or sustained effect. These routes can be divided into three primary categories: enteral, parenteral, and topical.
Enteral delivery involves administering drugs directly through swallowing, sublingual placement, or buccal application. Orally administered drugs predominantly navigate the...
276

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Updated: May 30, 2025

Author Spotlight: Advancing Cell Membrane Biophysics - Exploring Interactions and Challenges Through Experimental and Computational Approaches
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用于建模脂质介导活性药物成分输送的计算方法.

Markéta Paloncýová1, Mariana Valério2,3, Ricardo Nascimento Dos Santos4

  • 1Regional Center of Advanced Technologies and Materials, Czech Advanced Technology and Research Institute (CATRIN), Palacký University Olomouc, Šlechtitelů 27, 779 00 Olomouc, Czech Republic.

Molecular pharmaceutics
|January 29, 2025
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概括
此摘要是机器生成的。

计算方法对于设计有效的脂质纳米载体 (LNC) 对于药物输送至关重要. 本综述涵盖基于物理的模拟和机器学习方法,以优化LNC的组成,结构和功能,用于先进的疗法.

关键词:
可离子化脂质的离子化脂质脂质纳米载体的纳米载体脂质纳米颗粒是一种纳米粒子.脂质体组是什么? 脂质体组是什么?分子模拟分子模拟囊囊是什么意思

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科学领域:

  • 药物输送和纳米技术
  • 计算化学和材料科学计算化学和材料科学

背景情况:

  • 脂质纳米载体 (LNC) 能够提供具有挑战性的活性药物成分 (API),包括具有溶解性差,高毒性或不稳定的活性药物成分.
  • 对LNC中的组成-结构-功能关系的全面理解对于合理设计至关重要,但目前缺乏.

研究的目的:

  • 审查和介绍用于调查,选和设计LNC的可用的计算方法.
  • 突出基于物理学的方法的优缺点,特别是分子动力学模拟.
  • 引入机器学习作为优化LNC设计的数据驱动方法.

主要方法:

  • 基于物理学的计算方法的详细描述,包括全原子和粗粒度分子动力学模拟.
  • 讨论获得可靠的模拟结果所需的考虑因素.
  • 介绍机器学习方法,用于分析实验和理论数据,以指导LNC设计.

主要成果:

  • 分子动力学模拟提供了对不同分辨率的LNC行为的见解.
  • 机器学习可以处理各种数据集,以确定最佳的LNC配方.
  • 计算和实验数据的整合是推动LNC设计的关键.

结论:

  • 计算工具,包括分子动力学和机器学习,对于LNC的合理设计至关重要.
  • 解决目前理解组成-结构-功能关系的差距将提高LNC的性能.
  • 未来的研究应该集中在优化脂质介导药物递送系统的实验和计算方法的协同作用上.