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Cellular Membranes and Drug Transport01:24

Cellular Membranes and Drug Transport

2.0K
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.
2.0K
Facilitated Diffusion01:16

Facilitated Diffusion

1.6K
The plasma membrane, a critical structure in cellular biology, houses an array of transporters, or carrier proteins, interspersed within its lipid bilayer. These proteins play a crucial role in solute transport through facilitated diffusion, a form of passive diffusion that uses transporters to move the molecules across the membrane.
In this process, substrates such as organic compounds and ions interact with a transporter on one side, triggering conformational changes in proteins that enable...
1.6K
Pore Transport and Ion-Pair Transport01:17

Pore Transport and Ion-Pair Transport

1.5K
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...
1.5K
Carrier-Mediated Transport01:06

Carrier-Mediated Transport

1.5K
Carrier-mediated transport is a pivotal process in drug absorption, particularly for lipid-insoluble drugs, and encompasses facilitated diffusion and active transport. Facilitated diffusion allows drugs to move along their concentration gradient without energy expenditure, while active transport utilizes ATP to drive drug movement against this gradient.
Active transport involves two types of membrane-spanning transporters: uptake and efflux. Uptake transporters are expressed in the small...
1.5K
Drug Absorption Mechanism: Passive Membrane Transport01:23

Drug Absorption Mechanism: Passive Membrane Transport

7.8K
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...
7.8K
Mechanisms of Drug Absorption: Paracellular, Transcellular, and Vesicular Transport01:23

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

2.4K
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...
2.4K

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Related Experiment Video

Updated: Mar 29, 2026

A Method for Determination and Simulation of Permeability and Diffusion in a 3D Tissue Model in a Membrane Insert System for Multi-well Plates
10:33

A Method for Determination and Simulation of Permeability and Diffusion in a 3D Tissue Model in a Membrane Insert System for Multi-well Plates

Published on: February 23, 2018

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Impedance-Controlled Molecular Transport Across Multilayer Skin Membranes.

Slobodanka Galovic1, Milena Cukic Radenkovic2, Edin Suljovrujic1

  • 1Vinca Institute of Nuclear Sciences-National Institute of the Republic of Serbia, University of Belgrade, Mike Petrovica Alasa 12-14, 522, 11001 Belgrade, Serbia.

Membranes
|March 27, 2026
PubMed
Summary

This study introduces a new impedance-based model for transdermal drug delivery (TDD), offering a more physically accurate representation of skin layers. The model improves understanding of drug transport by considering the dynamic role of the dermis and hypodermis.

Keywords:
cumulative drug uptakediffusion impedancemultilayer diffusionskin membranetransdermal drug delivery

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Models and Methods to Evaluate Transport of Drug Delivery Systems Across Cellular Barriers
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Models and Methods to Evaluate Transport of Drug Delivery Systems Across Cellular Barriers

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Last Updated: Mar 29, 2026

A Method for Determination and Simulation of Permeability and Diffusion in a 3D Tissue Model in a Membrane Insert System for Multi-well Plates
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Models and Methods to Evaluate Transport of Drug Delivery Systems Across Cellular Barriers

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Author Spotlight: Optimizing Porous Substrate Electroporation Through Micro and Nanochannels for Enhanced Monitoring and Intermediate Stage Characterization

Published on: September 27, 2024

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Area of Science:

  • Pharmacology
  • Biophysics
  • Mathematical Modeling

Background:

  • Current analytical models for transdermal drug delivery (TDD) often oversimplify deeper skin layers (dermis and hypodermis) using ideal sink or interfacial resistance assumptions.
  • These simplifications obscure the actual physical mechanisms governing molecular transport through these composite layers.

Purpose of the Study:

  • To develop a physically grounded, impedance-based analytical model for diffusion across multilayer skin membranes.
  • To dynamically couple the epidermal barrier with a finite diffusive backing layer representing the dermis-hypodermis composite.
  • To provide a unified and extensible framework for analyzing multilayer transport systems in TDD.

Main Methods:

  • Developed an impedance-based analytical model linking transport conductivity, storage capacity, and layer thickness.
  • Preserved continuity of concentration and flux at all interfaces.
  • Utilized Laplace domain analysis for closed-form expressions of concentration and flux, with inverse transformation for time-domain cumulative drug uptake.

Main Results:

  • The model identifies distinct short- and long-time transport regimes.
  • Commonly used Dirichlet and Robin boundary conditions were shown as limiting cases, unable to capture the full behavior of the backing layer.
  • Robin formulations were found to neglect the storage capacity and time-dependent impedance of the backing layer.

Conclusions:

  • Replacing ad hoc boundary conditions with a physically grounded impedance framework offers a more accurate analysis of TDD.
  • The developed model provides a unified and extensible method for analyzing multilayer transport, with potential extensions to anomalous diffusion.
  • This approach enhances the understanding of molecular transport in complex biological systems beyond TDD.