Do you have stray voltage in
your home or dairy?
Call us or e-mail us
today at 1-800-909-1011 to
find out more information about stray voltage and order your stray
voltage meter to test and see if stray voltage is effecting your
milk production.
We also provide the service of testing your farm for stray voltage.
Contact us for more information to see when we will be in your area.
Symptoms of stray voltage Production losses are the result
of animals altering their behavior because of the small shocks or
tingles associated with high cow-contact voltages.. Some of the
changes in animal behavior are: (1) cows are excessively nervous
during milking (dancing around in the stall); (2) cows are reluctant
to enter the parlor or stall; (3) cows are reluctant to use waterers
or to consume feed; and (4) poor milk letdown. Dairy producers should
remember that these changes in animal behavior can also occur due
to problems with milking equipment, changes in milking routine,
spoilage of feed, or pollution of drinking water. Therefore, all
potential sources of behavioral changes should be investigated.
Read
information below that is published research about the effects of
Stray Voltage on cattle and milk production.
Effects of Electrical Shock on Cattle
Dr. Donald Hillman, Ph.D., Professor Emeritus, Department of Animal
Science, Michigan State University,East Lansing, Michigan 48824
Conclusions from Careful Examination of Published Research
[An article, Review of Stray Voltage Research, Effects on Livestock,
by Robert J. Fick, Director of the Michigan Agricultural Electric
Council (an employee of the electric power industry) and Visiting
Assistant Professor, Agricultural Engineering Department, Michigan
State University, and Truman C. Surbrook, Professor, Agricultural
Engineering Department, is on the MSU information network and in other
Michigan State University publications.
Conclusions of that article are challenged for understating effects
of low voltage on health and performance of dairy cattle on farms.
Conclusions are too dependent on limited research of doubtful merit
while ignoring findings and implications of other valid, conflicting
research. Such representations jeopardize administration of justice
to owners of herds so afflicted and risk the establishment by the
Michigan Public Service Commission or others of nonactionable voltages
which are biased in favor of electric power suppliers. Such actions
threaten access of plaintiffs to due process and are financially detrimental
to dairy farm users and their families affected by such extraneous
voltage. D.H. 1/30/99]
Research workers have documented effects of electrical shock on cattle
and reported in scientific journals. They have called the electrical
shock of concern here stray voltage. More precise and inclusive
it is termed “extraneous voltage” defined as any out of place voltage
within environment of the animal regardless of cause, source, or magnitude
(recommended by Bodman, Ref. 5). As cattle vary widely in response
to voltage and to the same voltage on different days, opinions vary
by research workers on effects of electrical shock on cattle. Our
analyses indicate that major experiments had few enough cows that
important differences in milk production, reproduction, and herd health
may not have been detectable. Other conclusions are not excluded.
The following is a summary of those findings: Commonly Cited Cow Responses
to Electrical Shock were summarized by Appleman and Gustafson (3):
1) Intermittent periods of reduced production; 2) reasons unexplained;
3) increased incidences of dairy cow
; 4) elevated somatic cell count
[in milk samples]; 5) lengthened milking times; 6) incomplete milk
letdown; 7) extreme nervousness in milking parlor [stepping, or raising
of feet, switching of tail, kicking off milkers]; 8) reluctance to
enter the milking parlor; 9) rapid exit from the parlor; 10) reluctance
to use water bowls or metallic feeders; and 11) altered consummatory
behavior [such as lapping water or splashing rather than normal drinking
behavior]. Authors observed effects of stray voltage on four general
areas: milking performanceand behavior, herd health, nutritional intake,
and yield of product. Reproduction should be added to the list. Cows
exhibit clear responses to applications between 2 and 4 mA of current
according to Scott, Gorewit, and Drenkard (21). Variation between
responses of cows to 4 and 8 mA shocks was large. Same cow response
differed markedly to the same current on different days for Drenkard
et al. (7). Lefcourt (12) reported that as little as 0.199 volts and
0.693 mA electrical current was mildly shocking and 0.272 volts (.964
mA) resulted in distinct shock reactions in one cow in five tests
for behavioral response to electrical shock. He found resistance from
250 to 405 Ohms and concluded that a cow with little electrical resistance
is twice as susceptible to stray voltage as is a cow with high electrical
resistance. He further concluded: “Therefore, because stray voltages
on a farm do not exceed .5 V does not mean that the farmer will be
free of stray voltage problems. In addition, because sensitivity to
electrical current varies with parts of the body through which it
passes, it is possible that cows might be even more sensitive to stray
voltage if the current passes through the teat or tongue.” Electricians
commonly include a 500 Ohm resistor in the circuit when measuring
voltage in areas of cow contact as if the resistor represents resistance
of the cow.
Ohms should be at least 250-500, although resistances presumably
change regularly as a cow picks up one or more feet either in walking
or attempting to escape electrical current. Further, if the filament
of a light bulb represents resistance on the circuit, then the heat
and light produced by the resistor hardly can be considered no consequence
in the circuit. A possible relationship between regular low amperages,
e.g. 1 or 2 mA, causing pain (hot-foot ?), separation of hoof laminae,
abnormal hoof growth, and other anomalies associated with stray voltage
on farms cannot be ruled out by published research. Use of resistors
in voltage meters would underestimate likely effects of low voltage
on cattle. Also, transient voltages measured during low peak usage
often increase significantly in late afternoon when heavier loads
are consumed from same lines in the neighborhood. In the latter experiments
of Lefcourt et al., (14) 28% of the cows (2 of 7 cows) became so distressed
by 10 mA electrical current that they could not be handled safely
and had to be removed from the experiment. And Gorewit et al. (8)
reported that 2 of 30 cows in one test and 4 of 44 first parity cows
in another test refused to drink at 4, 5, or 6 V for 36 h and were
given an alternative water source; that cows might have died should
be part of the outcome. Such difference may not be statistically significant
but may be economically significant (loss of $7,200 in cows plus $18,000
of milk) with no other water source available as under farm conditions.
Effects on Milk Yield and Milk Fat: In New Zealand (25, 26)
as the number of electrical shocks 1 min before milking increased,
workers found milk ejection increasingly was suppressed. Milk yields
were 10% less when Phillips (19) applied three volts between milking
claw and the rear feet of the cow during milking. Lefcourt and Akers
(13) reported that 5 mA current resultedin 11% to 17% decrease of
milk yield: “Milk yield and milking time were decreased in cows subjected
to stimulation by intermittent voltage.” Similarly, Aneshansley et
al. (1) reported to the American Society of Agricultural Engineers,
(ASAE #87-3034, page 6, Milk Production)--“week 5 was significantly
lower than week 2 for all cows that received voltages greater than
0.” The authors’ graphic presentation of “Milk Production Decline,”
Figure 11, is in the Appendices. Milk production changed (up to 3.5
kg/day) and at all voltages: 0.5, 1, 2, and 4 volts compared to the
controls. Weeks 1 and 2 were pre-trial adjustment, weeks 3, 4, & 5
were voltage treatments, and weeks 6 & 7 were posttreatment. Trends
were apparent for “Water Consumption,” Figures 2A vs 2B (Appendices),
“Feed Consumption” Figures 12A vs 12B (Appendices), and possibly “Milk
Fat” Figure 14A vs 14B (Appendices). Gorewit et al. (8) on the same
experiments in the Journal of Dairy Science did not mention the significant
differences at week 5 and did not present the graphic figures from
the ASAE report. However, they did report that two animals receiving
4 volts did not drink for 36 h, at which time their voltages were
disconnected. [And] “All other animals drank within 36 h and showed
no significant long-term difference in the monitored parameters.”
This is not consistent with the Aneshansley report (1) where milk
production was affected by a wide range of low voltages. Addition
of 44 more cows to their numbers for a 2 d water and feed consumption
and milk production “experiment” where they found four more cows that
did not drink for 36 hours drew their conclusion: “... no significant
long-term difference in monitored parameters.” Variances, small numbers,
and limited time exposure render contribution doubtful for describing
on-farm expectations from stray voltage. Behr (4), a forensic economist,
studied research notes and data provided by Cornell workers under
Court subpoenas and concluded that “The turnover of cows in the samples
is too high to support a claim of controlled full-lactation experimentation.”
He determined that the number of cows per slot (40 slots) averaged
3.6 for the 394 days and 141 cows which passed through the experiment
from 9/2/88 to 9/30/89. This computes to a 365 d “cull” rate of 3.3
cows per slot, or 230% compared to the more usual 30%, or at about
8 times the normal farm cull rate. And Behr concluded that the turnover
rate “is so far in excess of feasible farm conditions it renders the
Cornell Research results irrelevant even if they were valid.” A list
of the “Final 40" cows in means was not provided in either published
article nor request for such data. However, lactation records were
provided for 40 cows identified as �93"The Final 40." For these, differences
between groups for published 305-d lactations were surprisingly small
as if means were restricted from varying as they would with normal
residual variation among cows. Authors’ conclusion that none of voltages
0, 1, 2, and 4 V affected milk production 7312, 8527, 6938, and 7725
kg probably should elaborate that design did not enable such evaluation
through this trial. Conclusion that voltage did not affect milk yield
may have misled where it was testimony by expert witnesses in court.
Milk fat was depressed from voltages (Aneshansley et al. (2)) during
measurement of cow sensitivity to electricity during milking. “Milk
fat was lower when currents were applied to first lactation cows [-.2%]
and significantly lower [-.5% (p<.05)] for multiple lactation cows.”
Decreases of fat test reduced the market value of milk at least $.20
to $1.60 per 45.5 kg of milk sold; $40 to $320 per cow for a typical
herd averaging 9,091 kg milk/cow/year. Similarly, milk fat was less
for all voltages (1, 2, and 4 V) vs 0 controls in the full lactation
trial by Gorewit et al. (9, Table 2). The average percent for the
three periods given for 2 volts is miscalculated and should be 3.7%
rather than 4.0%. Average for controls was 3.8% fat in milk. Milk
fat depression is a common response to heat stress (24), and apparently
it occurs in cows subjected to electrical stress as well. Depressed
milk fat is common in farm herds subjected to stray voltage, but it
has been attributable to variations of dietary fiber and electrolyte
imbalances, not mentioned in the Cornell reports but assumed to be
equally distributed among treatments. Because cows were fed supplemental
grain individually from an automatic transponder feeder, differences
in amount of grain fed could have affected fat test. Depression of
milk fat by electrical stress, if real, may be further supporting
evidence of the adrenocortical stress syndrome as increased blood
cortisol is produced by electrical stress. Effects on Health and StressRelated
Disorders: Persistent, intermittent electrical shock produces typical
stress syndrome characterized by increase of blood adrenal hormones:
cortisol (hydrocortisone) (7) and epinephrine (adrenalin) (7,14).
Henke Drenkard and Gorewit, et al. (7) found blood cortisol increased
by 4 and 8 milliamps (mA) electrical current applied for 5 of every
30 sec during milking. While increased mean cortisol of 4 mA treatment
during milking (6.44, 8.78, and 10.86 ng/ml) was not different from
controls, with 6 cows and treatments switched every 8th day for 3
wk, (p>.05) a trend is apparent, and the 8 mA group mean was significantly
different. Cortisol continued to rise for 16 to 20 h posttreatment
when means were 13.25, 14.31, and 18.38 ng/ml for the 0, 4, and 8
mA shock. More somatic cells in milk of cows from the control group
suggest that dairy cow
might have played a role in the controls as
evident by the larger SCC standard deviation and its possible effects
on blood cortisol and statistical analysis. The authors noted that:
In work prior to this trial, most cows exhibited behavioral responses
to electrical current at 4 mA.
In the full lactation report on Cow Health and Reproduction (9) Cornell
authors noted, “When an experimental cow got dairy cow
, she was removed
from the experimental pen and placed with other mastitic herd cows.”
“Also, the waterer for any mastitic cows was not connected to any
voltage.” Apparently, effects of exposure to voltage on the severity
or recovery of sick animals was not considered important nor was the
effect of replacing mastitic experimental cows with other cows in
the analysis of data. Gorewit’s statement, “All indications of cow
health that were measured (somatic cell counts, cases of dairy cow
,
repeat dairy cow
, hoof problems, and body weight) showed no detrimental
effect that was due to voltage,” needs to be qualified to advise readers
“given the large variations and few cows on our experiment.” Calculation
(22) of “sample size” necessary to show significant differences between
controls and treatment means for the measured “Services per Conception”
where treatment means and SEM(standard error of the means) are in
Table 2, p. 2729, revealed that 48 cows per treatment would be required
to show significant differences ( p<.05) to be sure that means will
be significantly different 90% of the time. In the USDA (14) experiment,
blood glucocorticoids of 0 mA controls were abnormally elevated, nearly
twice baseline of treatment groups (controls=13.9 baseline) compared
to treatment baselines of 9.9, 6.0, 6.0, 6.9, and 8.3 ng/ml for 2.5,
5.0, 7.5, 10.0, and 12.5 mA treatments for 10 seconds, 1 hour prior
to milking. These high cortisol controls made significant differences
between treatment baseline-minus-peak versus controls impossible for
any voltage treatments with “standard error of the mean (range) 4.5-5.5
ng/ml.” Results were based on seven cows divided into two groups shocked
bi-weekly. Calculation of the sample size required to show statistical
significance indicates that 25 cows per treatment would have been
required to be sure that means are different 90% of the time (22).
Otherwise, the experiment provides no scientific basis for claiming
that any voltage had “no significant effect” on the hormones measured.
The inadequate controls and small number of cows would not allow any
other conclusion, except that two cows became so unmanageable as to
endanger workers at 10 mA that they were not subjected to 12.5 mA
currents, and the experiment was terminated without completing its
objective. Unmanageable cows were labeled “exceptional” as in the
Cornell reports, although they represented 28% of the cows on experiment.
Reproductive Efficiency may be inhibited by electrical stress because
repeated acute stress, with a brief significant rise of blood cortisol,
can disrupt the preovulatory luteinizing hormone (LH) surge and ovulation
in heifers (23) such as caused by transportation or severe climatic
conditions. These authors noted that previous investigators have found
that ACTH, cortisol, and progesterone, also released by the adrenal
cortex, can inhibit LH surge in the cow. Wilson et al. (27, 28) confirmed
that controlled heat stress inhibited ovarian function and reproductive
efficiency in cows and heifers by inhibiting follicle growth and development
and increasing incidence of delayed regression of corpus lutea. Reproductive
failure is a common complaint in herds affected by stray voltage and
can have severe economic consequences by reducing the number of off-spring
born, culling opportunity, and eventual number of cows in the herd.
Increasing adjusted calving interval resulted in net revenue losses
of $7.33 (US) per cow/day in a study of the economic effects of reproductive
efficiency (20). Data in the Cornell (10) study were too limited for
valid conclusions regarding effects of electrical stress on health
and reproduction. Also, cows that were not seen in estrus within 50
d after calving were given prostaglandins F2-alpha to destroy the
corpus luteum, stimulate estrus, and were inseminated in 5 to 7 d.
This procedure corrects the delayed (retained) corpus luteum problem
caused by stress as described by Wilson et al. and, therefore, corrects
the problem supposedly being measured by the experiment, rendering
it invalid and unrelated to objectives of the experiment. From the
means and variances for services per conception, 48 cows per treatment
would have been necessary to obtain statistical significance and be
sure that means would be different 90% of the time. Again, the few
cows and large variation limit data and concluding “no significant
difference” can be misleading. Effects on Resistance to Disease: Increased
blood cortisol caused by persistent stress, such as prolonged intermittent
electrical shock, results in an immediate leukocyte shift, longer
adrenocortical fatigue, and eventual reduction of peripheral white
blood cells. Serial injections with 100 and 200 IU of ACTH to stimulate
adrenocortical hormones reduced phagocytosis (engulfing) of bacteria
(staphylococcus aureus) by white blood cells 43% and 56% after the
sixth injection through a combination of decreased lymphocytes and
decreased phagocytosis, as demonstrated by Paape (17) and (18, Tables
3, 6, & 7) and Gwazdauskas et al. (11). ACTH is the hormone produced
by the pituitary gland, at the base of the brain, in response to stressful
stimuli. It stimulates the increase of cortisol and other hormones
produced by the adrenal glands. ACTH injection and heat stress of
cattle produced similar moderate leukocytosis and increases in somatic
cell counts of milk in Arizona studies (24). Electrical stress from
stray voltage may be similar to heat stress in which both feed and
water consumption dramatically were reduced, and milk energy output
declined nearly twice as much as digestible energy intake, resulting
in marked decrease of efficiency of utilization of energy, and in
considerably higher maintenance energy requirements (15). Corresponding
protein catabolism via gluconeogenesis, electrolyte imbalances, atrophy
of the thymicolymphatic system and gastrointestinal ulcers are all
known consequences of adrenocortical stimulation caused by such noxious
stressors as exposure to extreme cold, heat, xrays, burns, intense
sound or light, pain, forced muscular exercise, starvation, hemorrhage,
and anxiety. Electrical shock now can be added to the list of common
stressors. Eventually, we may learn that electrical shock may be a
contributor to abnormal incidences of metabolic disorders, lameness
or bone disorders, and an immune deficiency syndrome similar to AIDS
in humans. Water and Feed Consumption: Craine (6) reported that water
consumption from a watering trough charged with 6.0 volts was 68%
less than from the zero volt trough, and 48% less for the 6.0 volts
than from a 3.0 volt trough. Three volts reduced water consumption
about 20%. Norell et al. (16) taught cows to escape from 5.0 mA treatments
over a front to rear hooves pathway. During the test, cows were exposed
from 1.0 to 5.0 mA. Cows expressed the learned escape behavior in
23% of 2.0 mA current treatments and 97% of 5.0 mA treatments. When
the same series of current treatments was applied over a mouth-to-all
hooves pathway, cows responded to 15% of 1.0 mA treatments and to
90% of 5.0 mA treatments. In contrast, Cornell workers claimed no
significant differences in milk yield or composition, health and reproduction,
or water consumption (1, 9) of cows exposed to 0, 1, 2, or 4 volts
at their waterers. In the Journal of Dairy Science articles, authors
claim that results were based on 40 cows (10 cows per treatment group)
for complete lactations. However, five months were required to complete
filling the treatment groups with 10 fresh cows as designed, and apparently,
according to research notes of the trial furnished by the authors
under Court Subpoena, 141 cows were actually in the pens during the
trial, and cows were put in the wrong pens 16 times during the trial.
Water consumption was measured for the whole pen, not for individual
cows; and cows were observed drinking from the waterers over the fence
from outside the electrocution stall. Therefore, water consumption
reported has no direct relationship to milk production of experimental
cows because nonexperimental cows occupied spaces to keep the pens
full.Gorewit et al. (9) stated that average current (and ranges) for
2 d (randomly selected) were 3.1 mA (4.5 to 1.5), 6.5 mA (8.6 to 4.6),
and 11.2 mA (14.1 to 7.5) for the 1, 2, and 4 V pens, respectively
in the Cornell experiment. Evidently current was not monitored regularly.
In view of results by others, design of the Cornell trials must have
permitted meager exposure of cattle to electricity for outcomes to
have differed so from reports of decreased water, feed consumption,
and milk yield. Researchers claim that amperage (flow of electrical
current) rather than voltage per se is the culprit affecting cattle.
The relationship between voltage and current is expressed by Ohm’s
Law: E=IR, where E is volts, I is current flow (amperes), and R is
resistance of the circuit (Ohms). Then, volts divided by resistance
equals amperage. A table of resistances to current flow through various
pathways of the body is in the publication by Appleman and Gustafson
(3). Resistances ranged from 244 to 1960 Ohms depending on the animal
contact point and the pathway through the animal. For example: if
the particular animal’s path resistance is 250 Ohms, then .5 volts
yield 2 milliamps as: .5 volts/250 Ohms = .002 amps x 1000 = 2 milliamps
current. Because individual animals respond differently, arbitrarily
selecting a predetermined voltage or amperage as safe for all animals
seems foolish and irresponsible. Economic consequences occur when
as little as 2 of 37 or 2 of 7 of the cows in a herd are afflicted
by stray voltage. The Attorney General of Michigan concluded (Re:
Michigan Electric and Gas Association, Case No. U11368, October 15,
1997) that the Michigan Public Service Commission does not have the
statutory authority to approve rules to regulate the levels of extraneous
electrical current, which attempt to authorize utilities to spread
unwanted and detrimental electrical power (voltage and/or current)
outside of contractual easements onto private property to the detriment
of the health, safety and welfare of both people and animals, and
to the detriment of the use and enjoyment of property. The Attorney
General’s opinion was in response to a request by Consumers Energy
Company for the PSC to rule that 2 mA electrical current or less was
not harmful to livestock, and, therefore, plaintiffs claims could
not be brought to litigation. Conclusions Scrutiny of the published
articles cited in A Review of Stray Voltage Research, Effects on Livestock,
by Robert J. Fick and Truman C. Surbrook, does not support their conclusion
that 2.0 or less milliamps current from extraneous voltage is harmless
to dairy cows and of no economic consequence to dairy farmers. Much
of the data are unreliable and irrelevant to voltages found on farms
and are misleading to an unsuspecting public. Acknowledgements Appreciation
is expressed to Dr. Lon D. McGilliard, Professor Emeritus, MSU, and
former Editor, Journal of Dairy Science, for editing the manuscript,
and to Oleg Makhnin, Consultant, Department of Statistics and Probability,
MSU, for assistance in evaluating published data.
References 1.Aneshansley, D. J., R. C. Gorewit, D. C. Ludington,
and Z. Xin. 1987. Effects of neutral-to-earth voltage on behavior,
production and water intake in dairy cattle. Paper No. 87-3034. American
Society of Agricultural Engineers. Baltimore, MD. 1987. 2.Aneshansley,
D. J., R. C. Gorewit, and L. R. Price. 1992. Cow sensitivity to electricity
during milking. J. Dairy Sci., 75:2733-2741. 3.Appleman, R. D., and
R. J. Gustafson. 1985. Source of stray voltage and effect on cow health
and performance. J. Dairy Sci., 68:1554-1567. 4.Behr, Michael. Forensic
Economist. 1997. Stray voltage research fraud. Proprietary publication
by the author. Northfield, Minnesota. 5.Bodman, Gerald R., P.E. 1992.
Comments on Stray Voltage Technical Issues. Presented before the Minnesota
Department of Public Service in its Stray Voltage Rulemaking Docket
No. E-999/R92-245. 6.Craine, L. B., M. H. Ehlers, and D. K. Nelson.
1970. Electric potentials and domestic water supplies. Agricultural
Engineering, 51(7):415-417. 7.Drenkard, D. V. H., R. C. Gorewit, N.
R. Scott, and R. Sagi. 1985.
Milk Production, health and endocrine responses of cows exposed to
electrical currents during milking. J. Dairy Sci., 68:2694-2702. 8.Gorewit,
R. C., D. J. Aneshansley, D. C. Ludington, R. A. Pellerin, and Xin
Zhao. 1989. AC Voltages on water bowls: effects on lactating holsteins.
J. Dairy Sci., 72:2184-2192. 9.Gorewit, R. C., D. J. Aneshansley,
and L. R. Price. 1992. Effects of voltages on cows over a complete
lactation. 1. Milk yield and composition. J. Dairy Sci., 75:2719-2725.
10.Gorewit, R. C., D. J. Aneshansley, and L. R. Price. 1992. Effects
of voltages on cows over a complete lactation. 2. Health and reproduction.
J. Dairy Sci., 75:2726-2732. 11.Gwazdauskas, F. C., M. J. Paape, D.
A. Perry, and M. L. McGilliard. 1980. Plasma glucocorticoid and circulating
blood leukocyte responses to cattle after sequential intramuscular
injection of ACTH. Am. J. Vet. Research, 41:1052. 12.Lefcourt, Alan
M. 1982. Behavioral responses of dairy cows subjected to controlled
voltage. J. Dairy Sci., 65:672. 13.Lefcourt, Alan M., and R. Michael
Akers. 1982. Endocrine responses of cows to controlled voltages during
milking. J. Dairy Sci., 65:2125. 14.Lefcourt, Alan M., Stanislaw Kahl,
and R. Michael Akers. 1986. Correlation of indices of stress with
intensity of electrical shock for cows exposed to electrical current
milking. J. Dairy Sci., 69:833-842. 15.McDowell, R. E., E. G. Moody,
P. J. Van Soest, R. P. Lehmann, and G. L. Ford. 1969. Effect of heat
stress on energy and water utilization of lactating cows. J. Dairy
Sci., 52:188. 16.Norell, R. J., R. J. Gustafson, R. D. Appleman, and
J. B. Overmier. 1982. Behavioral studies of dairy cattle sensitivity
to electric current. Transactions of the ASAE, 16(5) 1506-1511. 17.Paape,
M. J., D. W. Carroll, A. J. Karl, R. H. Miller, and Claude Desjardins.
1974. Corticosteroids, circulating blood leukocytes, and erythrocytes
in cattle: diurnal changes and effects of bacteriologic status, stage
of lactation and milk yield responses to adrenocorticotropin. Am.
J. Vet. Research, 35:355, vol 3. 18.Paape, M. J., F. C. Gwazdauskas,
A. J. Guidry, and B. T. Weinland. 1981. Concentrations of corticosteroids,
leukocytes, and immunoglobulins in blood and milk after administration
of ACTH to lactating dairy cattle; Effects on phagocytosis of staphylococcus
aureus by polymorphonuclear leukocytes. Amer. Journal of Veterinary
Research, 42:20081. 19.Phillips, D. S. M. 1962. Production of cows
may be affected by small electrical shocks from milking plants. New
Zealand Journal of Agriculture, 105:221. 20.Plaizier, J. C. B., E.
J. King, J. C. M. Dekkers, and K. Lissemore. 1997. Estimation of economic
values of indices for reproductive performance in dairy herds using
computer simulation. J. Dairy Sci., 80:2775-2783. 21.Scott, R. N.,
R. C. Gorewit, and D.V. Drenkard. 1984. Effects of electrical current
on milking and behavior. Proceeding of the National Stray Voltage
Symposium (page 33), October 10-12, 1984. Syracuse, NY, American Society
of Agricultural Engineers. 22. Statistics and Probability Department,
Consulting Service, Michigan State University, East Lansing. 23.Stoebel,
David P., and Gary P. Moberg. 1982. Repeated acute stress during the
follicular phase and luteinizing hormone surge of dairy heifers. J.
Dairy Sci., 65:92-96. 24.Wegner, T. N., J. D. Schuh, E. F. Nelson,
and G. H. Stott. Effect of stress on blood leucocytes and milk somatic
cell counts in dairy cows. J. Dairy Sci., 59:949. 25.Whittlestone,
W. G. 1951. Studies on milk ejection in dairy cows. The effect of
stimulus on the release of “milk ejection” hormone. New Zealand Journal
of Science and Technology. 32A(5):1. 26.Whittlestone, W. G., M. M.
Mullard, R. Kiljour, and L. R. Cate. 1975. Electrical shock during
machine milking. New Zeakand Veterinary Journal, 26(6):105. 27.Wilson,
S. J., R. S. Marion, J. N. Spain, D. E. Spiers, D. H. Keisler, and
M. C. Lucy. 1998. Effects of controlled heat stress on ovarian function
of dairy cattle: 1. Lactating cows. J. D. Sci., 81:2124-2131. 28.Wilson,
S. J., C. J. Kirby, A. T. Koenigsfeld, D. H. Keisler, and M. C. Lucy.
1998. Effects of controlled heat stress on ovarian function of dairy
cattle. 2. Heifers. J. Dairy Sci., 81:2132-2138.
Link to original abstract http://www.msu.edu/user/hillman/ABSTRACT.htm
http://www.wisinfo.com/newsherald/mnhlocal/283647576532628.shtml
