Abstract

Local anesthesia is generally considered to involve specific binding to receptors, most probably to the sodium channel whose gate is opened. Against the receptor theories, nonspecific membrane perturbation, represented by the membrane stabilization concept, has also been proposed. The fact that part of the aromatic amine local anesthetics exists as a positively charged form is consistent with receptor binding because biological membranes usually carry negative surface charges. Nevertheless, atypical local anesthetics, such as alcohols, tranquilizers, antihistaminics, barbiturates, narcotics, general anesthetics, etc., also block nerve conduction. The diversity of drugs is difficult to reconcile with the idea that receptor binding is the sole mechanism of local anesthesia. Presumably, local anesthesia is caused by multiple mechanisms. Coexistence of charged and uncharged species of local anesthetics at a physiological condition has been a matter of concern as to which is the biologically active species. Despite the importance of accurate dissociation constants to differentiate between the actions of the two species, systematic effort to determine this parameter has been few. In the last funding period, we used the nonlogarithmic linear titration method to measure accurate dissociation constants. The effort will continue. The main objective of the present project, however, is to evaluate the interaction of charged local anesthetics with membranes and macromolecules. Membrane perturbation studies so far reported are concerned predominantly with uncharged species. With the availability of our data on dissociation constants, charged molecule amounts can be estimated with reasonable accuracy. Studies on the interaction with lipid monolayers, vesicle membranes, planar lipid bilayers, and macromolecules will be continued. The present project will also include studies of anesthetic effects upon liquid membranes with mobile ion carriers. The experimental methods consist of the standard surface and colloid chemistry and were used successfully during the previous funding period.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM027670-11
Application #
3274887
Study Section
Surgery, Anesthesiology and Trauma Study Section (SAT)
Project Start
1980-04-01
Project End
1991-03-31
Budget Start
1990-04-01
Budget End
1991-03-31
Support Year
11
Fiscal Year
1990
Total Cost
Indirect Cost

  Institution

Name
University of Utah
Department
Type
Schools of Medicine
DUNS #
City
Salt Lake City
State
UT
Country
United States
Zip Code
84112

  Publications

Shibata, A; Yamamoto, M; Yamashita, T et al. (1992) Biphasic effects of alcohols on the phase transition of poly(L-lysine) between alpha-helix and beta-sheet conformations. Biochemistry 31:5728-33
Chiou, J S; Tatara, T; Sawamura, S et al. (1992) The alpha-helix to beta-sheet transition in poly(L-lysine): effects of anesthetics and high pressure. Biochim Biophys Acta 1119:211-7
Tamura, K; Kaminoh, Y; Kamaya, H et al. (1991) High pressure antagonism of alcohol effects on the main phase-transition temperature of phospholipid membranes: biphasic response. Biochim Biophys Acta 1066:219-24
Shibata, A; Morita, K; Yamashita, T et al. (1991) Anesthetic-protein interaction: effects of volatile anesthetics on the secondary structure of poly(L-lysine). J Pharm Sci 80:1037-41
Yoshida, T; Okabayashi, H; Kamaya, H et al. (1991) Interfacial dehydration by anesthetics: an electrocapillary study of surface charge density of adsorbed monolayer. J Pharm Sci 80:852-4
Suezaki, Y; Tamura, K; Takasaki, M et al. (1991) A statistical mechanical analysis of the effect of long-chain alcohols and high pressure upon the phase transition temperature of lipid bilayer membranes. Biochim Biophys Acta 1066:225-8
Kaminoh, Y; Kitagawa, N; Nishimura, S et al. (1991) Two-state model for nerve excitation and local anesthetic action. Ann N Y Acad Sci 625:315-7
Chiou, J S; Kuo, C C; Lin, S H et al. (1991) Interfacial dehydration by alcohols: hydrogen bonding of alcohols to phospholipids. Alcohol 8:143-50
Suezaki, Y; Tatara, T; Kaminoh, Y et al. (1990) A solid-solution theory of anesthetic interaction with lipid membranes: temperature span of the main phase transition. Biochim Biophys Acta 1029:143-8
Chiou, J S; Ma, S M; Kamaya, H et al. (1990) Anesthesia cutoff phenomenon: interfacial hydrogen bonding. Science 248:583-5

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