Passive transport, through cell membranes

In the simplest transport mechanism called diffusion or passive transport, molecules can diffuse from a higher concentration to a lower concentration. For example, small molecules such as O2, CO2, urea, and water diffuse via passive transport through cell membranes. If their concentrations are greater outside the cell than inside, they diffuse into the cell. If their concentrations are higher within the cell, they diffuse out of the cell. 

Fig. 15.2. Physicochemical molecular descriptors affect the transport route utilised across the intestinal epithelium. To passively diffuse through the membrane (1), the compound (here illustrated with testosterone) should preferably be small, with a molecular weight <500 Da, as well as uncharged and fairly lipophilic. However, compounds that are too lipophilic can stick to the membrane and will not pass through the cells. The paracellular route (2), here exemplified with mannitol, is mainly utilised by smaller (Mw < 200 Da)...

A parameter (usually symbolized by P, and often containing a subscript to indicate the specific ion) that is a measure of the ease with which an ion can cross a unit area of membrane by simple (or passive) diffusion through a membrane experiencing a 1.0 M concentration gradient. For a particular biological membrane, the permeabilities are dependent on the concentration and activity of various channel or transporter proteins. In an electrically active cell (e.g., a neuron), increasing the permeability of K+ or CF will usually result in hyperpolarization of the membrane. Increasing will cause depolarization. 

In aqueous solution around pH 7, WR 1065 is doubly protonated (net charge Z = 2). Its uptake by mammalian cells is kinetically of first-order and increases with [H+]-1/2. This has been taken as evidence that the transport through plasma membrane probably occurs by a passive diffusion of the uncharged diamine (Calabro-Jones et al. 1988). 

The compounds can cross the membranes by passive processes, which depend only on the concentration gradient on both sides of the barrier, or by active ones, which are mediated by the interaction of the compound with a protein. The passive processes of the epithelial cells in the gastrointestinal tract include passive transport through the cell (trans-cellular pathway) or in the space between the cells (para-cellular pathway) [18]. 

The permeability of compounds through cell membranes is of great interest and importance for the elucidation of many biologic ceU functions. Most metabolically important substances are transported across membranes by active transport. Many other intrinsic compounds, as well as most drugs, are known to pass the membrane by passive diffusion. 

Passive transport through the cell membrane rarely requires any form of energy. It takes place along electrochemical gradients through either free or facilitated diffusion. 

For apolar modifications such as methylphosphonates, cellular uptake by passive diffusion through the cellular membrane has been proposed [378]. Flowever, it has been shown that transport through phospholipid membranes proceeds slowly (efflux t]/2 > 4 days) and does differ only slightly from the diffusion of unmodified ODNs [367]. Cellular uptake of methyl-phosphonate oligomers labeled with fluorescent dyes was found to depend on temperature. The oligomers were found in endosomal compartments within the cells [379]. 

Substances move through cell membranes by diffusion (passive transport), facilitated transport, and active transport. 

AletabolicFunctions. The chlorides are essential in the homeostatic processes maintaining fluid volume, osmotic pressure, and acid—base equihbria (11). Most chloride is present in body fluids a Htde is in bone salts. Chloride is the principal anion accompanying Na" in the extracellular fluid. Less than 15 wt % of the CF is associated with K" in the intracellular fluid. Chloride passively and freely diffuses between intra- and extracellular fluids through the cell membrane. If chloride diffuses freely, but most CF remains in the extracellular fluid, it follows that there is some restriction on the diffusion of phosphate. As of this writing (ca 1994), the nature of this restriction has not been conclusively estabUshed. There may be a transport device (60), or cell membranes may not be very permeable to phosphate ions minimising the loss of HPO from intracellular fluid (61). 

Camenisch, G., Folkers, G., Van de Waterbeemd, H. Comparison of passive drug transport through Caco-2 cells and artificial membranes. Int. J. Pharm. 1997, 147, 61-70. 

Figure 1 General pathways through which molecules can actively or passively cross a monolayer of cells. (A) Endocytosis of solutes and fusion of the membrane vesicle with the opposite plasma membrane in an active process called transcytosis. (B) Similar to A, but the solute associates with the membrane via specific (e.g., receptor) or nonspecific (e.g., charge) interactions. (C) Passive diffusion between the cells through the paracellular space. (C, C") Passive diffusion (C ) through the cell membranes and cytoplasm or (C") via partitioning into and lateral diffusion within the cell membrane. (D) Active or carrier-mediated transport of an otherwise poorly membrane permeable solute into and/or out of a cellular barrier.

Water and electrolytes. Each day in an average adult, about 5.51 of food and fluids move from the stomach to the small intestine as chyme. An additional 3.5 1 of pancreatic and intestinal secretions produce a total of 9 1 of material in the lumen. Most of this (>7.5 1) is absorbed from the small intestine. The absorption of nutrient molecules, which takes place primarily in the duodenum and jejunum, creates an osmotic gradient for the passive absorption of water. Sodium may be absorbed passively or actively. Passive absorption occurs when the electrochemical gradient favors the movement of Na+ between the absorptive cells through "leaky" tight junctions. Sodium is actively absorbed by way of transporters in the absorptive cell membrane. One type of transporter carries a Na+ ion and a Cl ion into the cell. Another carries a Na+ ion, a K+ ion, and two Cl ions into the cell. 

Potassium ion secretion. Potassium ions are secreted in the distal tubule and the collecting duct. These ions diffuse down their concentration gradient from the peritubular capillaries into the interstitial fluid. They are then actively transported up their concentration gradient into the tubular epithelial cells by way of the Na+, K+ pump in the basolateral membrane. Finally, potassium ions exit the epithelial cells by passive diffusion through K+ channels in the luminal membrane and enter tubular fluid to be excreted in the urine. 

Models of lipid bilayers have been employed widely to investigate diffusion properties across membranes through assisted and non-assisted mechanisms. Simple monovalent ions, e.g., Na+, K+, and Cl, have been shown to play a crucial role in intercellular communication. In order to enter the cell, the ion must preliminarily permeate the membrane that acts as an impervious wall towards the cytoplasm. Passive transport of Na+ and Cl ions across membranes has been investigated using a model lipid bilayer that undergoes severe deformations upon translocation of the ions across the aqueous interface [126]. This process is accompanied by thinning defects in the membrane and the formation of water fingers that ensure appropriate hydration of the ion as it permeates the hydrophobic environment. 

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