Radiotelemetry temperature responses of mammary gland and body to intramammary injection of Escherichia coli endotoxin or Streptococcus agalactiae in lactating dairy cows
1993
Lefcourt, A.M. | Bitman, J. | Wood, D.L. | Stroud, B. | Schultze, D.
To investigate the feasibility of using changes in body or mammary temperature to detect mastitis, radiotransmitters were implanted midway between rear udder quarters and in the peritoneal cavity of 5 Holstein cows (1 to 3 months in lactation) housed in an environmental chamber (16 +/- 2 C; lights on 7:00 AM to 11:00 PM). After a 6-week control period, Escherichia coli endotoxin (0.5 mg) was injected after the morning milking into left rear teat cisterns via the teat canal. Wisconsin mastitis test score and somatic cell count in all quarters increased significantly (P < 0.01) by the next milking. Effects were greatest in the endotoxin-exposed quarters. Milk yields for all quarters decreased significantly (P < 0.01) by the first milking after endotoxin injection. Udder and body temperatures at milkings were similar and were not affected by treatment. When temperatures were averaged for the 5 cows for each of 120 time points/d, average temperatures, relative to time of injection of endotoxin, were increased by 0.5 C above baseline at 2.75 hours, peaked at + 2.9 C at 6.50 hours, and remained high through 9.25 hours after injection. Power spectra calculated for individual cows on a daily basis universally indicated an increase in power at low frequencies on the day of injection. Subsequently, Streptococcus agalactiae (200 colony-forming units) was injected into right rear teat cisterns. Wisconsin mastitis test score increased at the second milking after injection. Cell count and quarter milk yield decreased by the third milking. As with endotoxin, injection of S agalactiae could not be detected via a change in temperature at milkings. Of the 5 cows, 3 had a peak in temperature after injection of S agalactiae. Average temperatures for these 3 cows relative to time of injection, were increased by 0.5 C above baseline at 24.25 hours, peaked at + 1.4 C at 26.25 hours, and remained high through 28.75 hours after injection. Power spectra calculated for the day in which a temperature peak was detected for these 3 cows indicated an increase in power at low frequencies, compared with spectra for all other days. Similar increases in power were also detected for the 2 cows that did not have temperature peaks. When clinical signs of mastitis are obvious at milking, there is little advantage of using body temperature for detection of infection. When clinical signs are not obvious, body temperature is often only minimally increased. Thus, monitoring body temperature at milkings adds little to the ability to detect mastitis. Of more interest is the ability to detect transient temperature increases that often develop in association with less-severe infections. Also, as early treatment increases the likelihood of successful treatment, detection of the onset of temperature increases would be advantageous for treatment of severe infections. Detection of a transient temperature peak requires taking temperature readings every 2 hours. To detect mastitis when a temperature peak does not occur requires measurement every 15 minutes to calculate power spectra. The ability to detect the onset of acute clinical infections and subclinical infections, using frequent temperature readings, indicates that development of a practical radiotelemetry system for use on farms may be warranted, depending on cost. The added potential of using body temperature to monitor general health and to detect estrus enhances the economic feasibility of developing such a system.
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