Nerves, metabolic rate

Pyrethroids have low oral toxicity to mammals, and in general their insect (topical) to mammal (oral) toxicity ratio is much higher than that of the other major classes of insecticides [25]. As the reason, at least the following mechanisms are conceivable (1) negative temperature dependence - differences in body temperature between insects and mammals makes the insect nerves much more sensitive, (2) metabolic rate - insects metabolize the insecticide more slowly than mammals, and the metabolizing enzyme systems are different, and (3) differences in body size - insects will have less chance to metabolize the insecticides before reaching the target site [26]. 

For a cell at rest, KT is pumped in and Na+ is pumped out. (Perhaps up to one half of the basal metabolic rate in man (1700 kcal d-1 7100 kj d ) is expended in pumping Na+.) Localized reversals of this process coincide with control and trigger of electrical impulses intracellular Na+ level is particularly low in nerve and muscle so that entry of a small amount of Na+ causes a large increase in concentration. The shock observed after severe burning is because K ions are lost from within... 

Basal metabolic rate is the energy expenditure by the body when at rest, but not asleep, under controlled conditions of thermal neutrality, and about 12 hours after the last meal. It is the energy requirement for the maintenance of metabolic integrity, nerve and muscle tone, circulation and respiration (see Figure 1.2 for the contribution... 

It is already evident that the turnover rate of a transmitter is only a crude measure of its release rate. Further limitations are that there is appreciable intraneuronal metabolism of some neurotransmitters notably, the monoamines. In such cases, turnover will overestimate release rate. Another problem, again affecting monoamines, is that some of the released neurotransmitter is taken back into the nerve terminals and recycled. This leads to an underestimate of release rate. Despite these drawbacks, studies of turnover rates uncovered some important features of transmitter release. In particular, they provided the first evidence for distinct functional pools of monoamines, acetylcholine and possibly other neurotransmitters a release pool, which could be rapidly mobilised for release, and a storage or reserve pool which had a slower turnover rate. 

The major routes for the synthesis and metabolism of noradrenaline in adrenergic nerves [375], together with the names of the enzymes concerned, are shown in Figure 3.1. Under normal conditions the rate controlling step in noradrenaline synthesis is the first, and the tissue noradrenaline content can be markedly lowered by inhibition of tyrosine hydroxylase [376]. Tissue noradrenaline levels can also be lowered, but to a lesser extent, by inhibition of dopamine-(3-oxidase [377, 378]. However, the noradrenaline depletion produced by guanethidine is unlikely to result from inhibition of synthesis, since intra-cisternal injection of guanethidine does not prevent the accumulation of noradrenaline which follows brain monoamine oxidase inhibition, even though it does cause depletion of brain noradrenaline [323]. 

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