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Semen characteristics and fertility in the bull

Published online by Cambridge University Press:  27 March 2009

M. W. H. Bishop
Affiliation:
A.R.C. Unit of Animal Reproduction, School of Agriculture, Cambridge
R. C. Campbell
Affiliation:
A.R.C. Unit of Animal Reproduction, School of Agriculture, Cambridge
J. L. Hancock
Affiliation:
A.R.C. Unit of Animal Reproduction, School of Agriculture, Cambridge
A. Walton
Affiliation:
A.R.C. Unit of Animal Reproduction, School of Agriculture, Cambridge

Extract

1. Certain characteristics of bull semen have been examined at four artificial insemination centres in England. One hundred and twenty-one samples of semen, comprising 168 ejaculates from seventysix bulls of seven breeds, were examined. The semen from 119 tested samples was subsequently used to inseminate 4604 cows.

The following semen characteristics were studied: volume of ejaculate; concentration of spermatozoa; incidence of dead spermatozoa; incidence of morphologically abnormal spermatozoa; initial fructose concentration; resistance of spermatozoa to temporature shock; methylene-blue reduction; O2 uptake; fructose utilization; visual evaluation of motility; impedance change frequency; and fertilizing capacity (conception rate).

A clinical examination was made of the reproductive organs of each bull.

2. Variations in the concentration of living spermatozoa and in the incidence of dead spermatozoa were found to account for most of the variations in the metabolic activity of semon: they also largely explained differences in physical activity as assessed by visual estimation of motility or by impedance change frequency.

3. Although the rates of methylene-blue reduction, O2 uptake and fructolysis showed a close correlation with the numbers of living spermatozoa present, O2 uptake and fructolysis per living cell decreased with increasing cell concentration.

4. Variations in metabolic activity showed no correlation with variations in the morphological characteristics of the spermatozoa, except in the case of spermatozoa with bent tails. These forms occurred in some samples as a result of staining treatment, but their incidence was positively correlated with the O2 uptake and fructolysis per living cell.

5. There was evidence that highly active spermatozoa are more resistant to temperature shock than less active spermatozoa.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1954

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