Serum Alkaline Phosphatase and Amylase Activities in Subacute Ruminal Acidosis in Dairy Cows
Ruminal fluid and blood samples were drawn from 159 dairy cattle (75 early lactation and 84 mid lactation cows from 10 dairy herds) to compare blood serum alkaline phosphatase and amylase activities in subacute ruminal acidosis. No significant differences were detected for blood alkaline phosphatase and amylase activities in subacute ruminal acidosis affected and the rest of the cows. The differences between animals with subacute ruminal acidosis and those with marginal pH values and healthy cows were not significant. The blood alkaline phosphatase and amylase activities had no significant correlations with ruminal pH.
Received: April 04, 2010;
Accepted: July 23, 2010;
Published: November 24, 2010
Subacute ruminal acidosis (SARA) is characterized by daily episodes of low
ruminal pH between 5.5 and 5.0 (Krause and Oetzel, 2006).
This digestive disorder is the consequence of feeding high grain diets to dairy
cows, which are adapted to forage diets (Oetzel, 2003;
Hajikolahi et al., 2006). In a dairy herd, two
groups of cows are most susceptible to SARA, early lactation and mid lactation
cows (Kleen et al., 2003). Field studies revealed
the presence of SARA in 11-29.3% early lactation cows and in 18-26.4% mid-lactation
cows (Garrett et al., 1997; Kleen,
2004; Tajik et al., 2009). Although, SARA
is suggested as the most important nutritional disorder of dairy cattle (Enemark,
2008), yet the mechanism of its pathogenesis is not completely known. Furthermore,
the signs of SARA are not completely known and the diagnosis is often difficult
in the field due to the variable and subtle signs.
The recommended protocol for the diagnosis of SARA is collection of ruminal
fluid by rumenocentesis (Nordlund et al., 1995;
Garrett et al., 1999). Although the complex etiology
and subclinical course of SARA complicate its diagnosis and necessitate its
routine monitoring, rumenocentesis complications (haematomas and abscess formation
at the puncture site and septic peritonitis) render routine monitoring of rumen
pH by rumenocentesis unpractical. Therefore, finding a non invasive and simple
method for detection of SARA in dairy herds will be most valuable.
The negative balance of calcium due to decreased feed intake and increased
urinary excretion seemed to be the cause of increased plasma alkaline phosphatase
(ALP) activity in rumen acidosis affected cows (Harmon and
Britton, 1983). On the other hand, decrease of dry matter intake is the
more consistent sign of SARA in affected cows (Kleen et
Plasma amylase activity was observed to increase in ruminal acidosis affected
goats and was believed to be due to pancreatic tissue damage (Lal
et al., 1992). However, Krehbiel et al.
(1995) did not report blood amylase increase in ruminal acidosis affected
lambs and suggested that the severity of the acidosis and rumen pH decrement
was the determinant factor of pancreatic tissue damage. SARA has to be defined
as an intermittent fall of the ruminal pH to non physiological levels and the
severity of rumen pH decrement is less than acute ruminal acidosis. Despite
this fact, Brown et al. (2000) observed increased
serum amylase activity in SARA-affected cows. It seems there is some controversy
concerning the change of amylase in SARA-affected cows.
This research was designed to study blood serum ALP and amylase activities in SARA-affected and compared to non- affected cows.
MATERIALS AND METHODS
From September 2007 to November 2007, 7 Holstein dairy herds in Khorasan Razavi province, northeast of Iran, were selected according to willing for participation in the study. All herds were fed Total Mixed Rations (TMR), which were formulated to meet all NRC nutrient recommendations. In all herds, the ration was consisted of alfalfa and corn silage as the forage and different ratios of barley and maize milled grains as the concentrate.
Two groups of 12 cows were selected randomly in each herd. One group consisted
of early lactation cows (3-20 days in milk) while the other consisted of mid-lactation
cows (60-150 days in milk). Four to six hours following morning TMR feeding,
ruminal fluid collection was carried out by means of rumenocentesis (Nordlund
et al., 1995) from selected cows. Ruminal fluid pH was determined
immediately with a portable pH-meter (Horiba, B-213, Kyoto, Japan). Also, jugular
vein blood samples were collected at the time of rumenocentesis from all cows.
The blood serum was separated after centrifugation at 1800 g for 10 min and
stored at -18°C until analysis.
Alkaline phosphatase (Bowers and McComb, 1975) and
amylase (Winn-Deen et al., 1988) activities were
measured in the stored serum samples by commercial kits (ZiestChem Diagnostics
Tehran, Iran) using an autoanalyser (Ependorf, EPOS analyzer 5060, Germany).
Control serum (ZiestChem Diagnostics Tehran, Iran) was used for controlling
Statistical analysis was preformed using SPSS12 (Illinois, Chicago). Two sample t-tests were used to compare the serum ALP and amylase activities between SARA- affected cows and the rest of the cows and to detect differences between early lactation and mid-lactation groups. Correlations of ALP and amylase with the ruminal pH were analyzed by Pearsons correlation tests. Analysis of variance (ANOVA) test was used for comparison of ALP activity between animals with SARA, animals with a marginal pH and the rest of the cows. Because of unequal variances, Kruskal-Wallis test were used to compare amylase between SARA- affected, marginally affected and healthy cows. With the same reason, Kruskal -Wallis tests were used to compare amylase when early and mid lactation cows were evaluated separately. Differences were considered significant at p<0.05.
It was possible to draw a ruminal fluid from 159 out of 168 initially selected
animals (75 early lactation and 84 mid lactation cows). Cows with a rumen pH
of 5.5 or less at the time of rumenocentesis, considered to be experiencing
SARA and a ruminal pH≥5.8 considered as a non affected cow. Animals with
rumen pH values between 5.6 and 5.8 were considered to be marginally acidotic.
If three or more cows in a rational group have rumen pH of 5.5 or less, the
group was considered to be experiencing SARA (Nordlund et
al., 1995; Garrett et al., 1999).
The concentrations of serum ALP and amylase in SARA- affected and the rest
of the cows are shown in Table 1. There were no significant
difference between SARA- affected and the rest of the cows in blood ALP and
amylase. Also, the differences were not significant when early lactation and
mid lactation cows were evaluated separately.
||The concentrations of serum ALP and amylase (mean±
SEM) in SARA- affected and the rest of the cows (consisted of marginally
affected and healthy cows)
||The concentrations of serum ALP and amylase (mean±SEM)
in SARA- affected, marginally affected and healthy cows
No significant difference was found between early and mid lactation cows in
the blood ALP and amylase activities. At the time of rumenocentesis, early lactation
cows in 4 farms and mid-lactation cows in 5 farms were found to be experiencing
SARA. The comparison of mean ALP and amylase between SARA affected and non affected
rational groups using student's t- tests showed no significant difference.
The blood ALP and amylase activities had no significant correlations with the rumen pH (r = -0.057 and r = -0.04, respectively), But there was a significant correlation between blood ALP and amylase activities (r = 0.239, p = 0.006). When early and mid lactation cows were evaluated separately, the correlations of the blood ALP and amylase activities with rumen pH were not significant. But, the correlation between the blood ALP and amylase activities was significant in early lactation cows (r = 0.331, p = 0.009). The concentrations of serum ALP and amylase in SARA-affected, marginally affected and healthy cows are shown in Table 2, no significant difference was detected between animals with SARA and those with marginal pH values and healthy cows for blood ALP and amylase activities. The differences were not significant when early and mid lactation cows were evaluated separately.
The normal range of serum ALP activity in cattle is wide, 0-488 IU mL-1
(Kaneko et al., 1997). So, in this study, serum
ALP activities of all sampled cows were normal. Harmon and
Britton (1983) believed that the increase in the serum ALP activity of rumen
acidosis affected cows was due to feed intake decrement and urinary excretion
of calcium. Despite the decrease of dry matter intake in SARA-affected cows
(Kleen et al., 2003), no serum ALP change was
detected. On the other hand, Brown et al. (2000)
reported that the change in blood pH of SARA affected cows was small, hence,
urinary excretion of calcium like that observed by Harmon
and Britton (1983) in acute acidosis, did not happen during SARA. In Harmon
and Britton (1983) experiment, the ruminal pH of wethers, 6 hours after
feeding a high concentrate diet, was between 5.2 and 5.5. According to definition
of SARA by Krause and Oetzel (2006), it seems that the
wethers involved in this study were suffered from SARA. In Harmon
and Britton (1983) study, blood ALP increased significantly after feeding
90% concentrate diets for 10 days. In Brown et al.
(2000) study, steers received a SARA inducing meal and blood ALP was measured
for 14 days. Brown et al. (2000) did not observe
any change in the serum ALP activity during the experimentally induced SARA
in beef steers which is same to our results.
Blood activity of amylase is routinely used as a clinical laboratory test for
diagnosis of acute pancreatitis (Krehbiel et al.,
1995). Krehbiel et al. (1995) believe that
the severity of rumen pH drop in rumen acidosis is the determinant factor of
pancreatic tissue damage. Although decrease of rumen pH in SARA is intermittent,
Brown et al. (2000) reported increased serum
amylase activity in SARA- affected cows. But, according to our results, there
was no significant difference between SARA- affected and non affected cows and
rational groups in the blood serum amylase activity and no significant correlation
was found between the rumen pH and the serum amylase activity. Mohamed
et al. (2003) found that the serum amylase values in cows with chronic
pancreatitis remain normal. Therefore pancreatic damages in SARA affected cows
can not be rejected.
Brown et al. (2000) suggested that the serum
amylase and ALP activities might be useful in distinguishing between SARA- affected
and non affected steers. But, present results did not confirm this. It seems
that there are some differences between experimentally controlled studies of
SARA and farm condition and the results of the experimental studies may be different
from what is happening in dairy farms. Also, pathologic study and comparison
of pancreatic lesions between SARA- affected and non affected cows in dairy
farms is recommendable.
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