膜 10 巻, 4 号

心筋細胞膜の電気特性

There have been multiple ionic current systems which contribute to the electrogenesis of the heart. Their precise mechanisms and roles in the cardiac action potential are difficult to define, because of the complexity of their regulatory functions and, in part, due to inadequate voltage control of the preparations under the study. Recent advent of the isolation procedure of a single cardiac cell and of the application of the voltage clamp method as well as the patch clamp technique to the myocytes has made it possible to approach the fundamental problems as to the function of the single ionic channel. The action potential of the heart muscle is mainly formed by flows of the fast Na⁺ current, the slow inward current and the K⁺ currents. The amplitudes and time-courses of these currents are determined by electrochemical gradient of each ion across the cell membrane and conductance changes governed by membrane voltage and time. In addition to above factors, the status of cellular energy supply, hormone-receptor bindings and intracellular free ionic concentrations such as Ca²⁺ have now been recognized as important determinants of gating mechanisms of the channel. The currents activated by these factors may play an essential role for the electrical activity of the heart not only under the physiological condition, but also under the pathological conditions.

プラズマ重合膜

Plasma polymerization to make organic coatings has become an important practical technique for the deposition of pinhole-free conformable thin films of superior physical, chemical, mechanical, electrical, and electronical properties. They are now providing many useful functions as dielectric layers, optical coatings, reverse osmosis and ultrafiltration membranes, antireflection coatings, and photovoltaic cells. The purpose of this paper is to briefly review basic principle and apparatus of plasma polymerization and to introduce useful applications of the products.

神経興奮と膜の力学的変化

The squid giant axon was found to change its diameter by about 1 nm upon electrical stimulation. An increasing phase was followed by a decreasing phase in a few milliseconds. This response was shown to be associated with a 1 mPa change in intracellular pressure (increase in diameter with increase in pressure). Both responses could be enhanced by Ca²⁺ and suppressed by tetrodotoxin applied externally. They became large after removal of the axoplasm. Under the voltage clamp condition, the pressure response appeared in a potential dependent manner. The potential dependence was parabolic, indicating that electrostriction is involved in the mechanical response. Application of a K⁺-rich solution or a lidocaine containing solution suppressed the response induced by voltage clamp pulses. These findings suggested that the thickness of the membrane in the phospholipid part changes as the potential changes. These mechanical responses may have some roles in determining the kinetics of ionic channels.

リポソームの医学応用

Since the emergence of the concept of liposomes in 1965, a rapidly increasing information has been accumulating regarding the physicochemical properties of liposomes. A vast knowledge on the artificial lipid vesicles has advanced the prospect of their practical use as carriers of enzymes and drugs in therapeutic as well as preventive medicine. However, various difficulties have to be overcome before liposomes are applied to patients. This chapter will bring together the main research works exclusively related to the aspect of medical application of liposomes as a carrier system.

カルボン酸を有する合成高分子膜のパーベーパレーション法による水-酢酸混合液の分離

Separation of water-acetic acid mixture through a membrane was carried out. Membranes obtained from poly (acrylic acid-co-acrylonitrile) and poly (acrylic acid-co-styrene) were effective for a selective separation of water from aqueous acetic acid solution by means of pervaporation method. Permeation of water and acetic acid through membranes from poly (acrylic acid-co-acrylonitrile) was interpreted by a carrier mechanism, in which carboxylic acid moiety in the membrane played a role as a fixed carrier for both permeates. Water was permeated through poly (acrylic acid-co-styrene) membranes by TYPE II mechanism, in other words, an all or nothing mechansim, while acetic acid was permeated without having any specific interaction with the membrane.