A technique for detection of bovine viral diarrhea virus (BVDV) from circulating blood leukocytes, using the polymerase chain reaction, is described. The published nucleotide sequences of 2 strains of BVDV and that of hog cholera virus were aligned and the information was used to design oligonucleotides coding for 2 regions of amino acid homology. The oligonucleotides were a mixed population including all possible codons for the conserved amino acids. These degenerate oligonucleotides were used in the polymerase chain reaction to detect viral RNA in cells infected in vitro, or in circulating blood leukocytes from infected animals. Virus was detected in over 60 samples from diverse isolates. The detection of BVDV by the polymerase chain reaction is a rapid, sensitive, and specific technique, which represents an improvement over existing technology.

Ovulation has been likened to an inflammatory process. Inflammatory cells accumulate in the ovulating follicle, presumably because of chemotactic factors. Chemotactic activity was measured in fluid aspirated from follicles of estrous mares 0, 12, 24, and 36 hours after ultrasonographic detection of a 35-mm follicle and IV treatment with 2,500 IU of human chorionic gonadotropin. Chemotaxis was assessed by measuring directional migration of equine neutrophils under agarose. Follicular fluid acted as a chemoattractant for neutrophils, but there was no significant difference in chemotactic activity among different time intervals after administration of human chorionic gonadotropin. On the basis of results of various treatments, chemotactic properties of serum and follicular fluid were similar. Chemotactic activity was significantly reduced by heating (56 C for 30 minutes) and by trypsinization and was virtually removed by charcoal treatment. Dialyzing the follicular fluid (3,500 and 8,000 molecular weight cut-off) significantly reduced the chemotactic activity of follicular fluid and serum. The importance of chemotactic factors in the process of ovulation in the mare is yet to be established.

The DNA fragments representing the entire short unique region and part of the repeat sequences of the equine herpesvirus type-1 genome were cloned into plasmid vectors. The approximate positions of the junctions between the short unique region and the inverted repeats were then located by restriction endonuclease mapping. Two open reading frames coding for potential glycoproteins have been identified within the short unique region, using DNA sequence analysis. The predicted amino acid sequences of these open reading frames had extensive homology to the herpes simplex virus glycoproteins gE and gI and the related glycoproteins of pseudorabies virus and varicella-zoster virus.

Hip dysplasia is an affection of the coxofemoral joint that progresses until stabilization is caused by fibrosis and osteoarthritic changes. This stabilization process can be examined by clinical and radiographic methods. The capability of evaluating the procollagen concentrations in liquids, such as serum and synovial fluid, has further offered the basis for an objective biochemical evaluation of the stabilization process. Our study was performed to evaluate whether determination of procollagen concentrations was suitable for the use in practice. The procollagen type-III aminoterminal peptide (P-III-NP) concentration was measured in serum and in synovial fluid from coxofemoral joints in 20 dogs. Dogs were grouped on the basis of evidence of dysplasia and osteoarthritic changes of the hip: (1) a control group of 6 dogs without clinical or radiographic signs of hip dysplasia, and (2) dysplastic group of 14 dogs, which was further grouped with respect to the coxofemoral joint laxity, as determined by the Ortolani test. Synovial fluid concentration of P-III-NP was significantly (P < 0.05) higher in fluid from dysplastic joints than in fluid from normal joints. Serum concentrations of P-III-NP were significantly (P < 0.05) higher in dogs in which results of the Ortolani test were positive.

In a 4 x 4 crossover-design study, pharmacokinetic variables of 2 injectable formulations of netobimin (trisamine salt solution and zwitterion suspension) were compared after SC administration in calves at dosage of 12.5 mg/kg of body weight. Netobimin parent drug was rapidly absorbed, being detected between 0.25 and 12 hours after treatment, with maximal plasma drug concentration (Cmax) values of 2.20 +/- 1.03 micrograms/ml achieved at 0.75 +/- 0.19 hour (trisamine) and 1.37 +/- 0.59 micrograms/ml at 0.81 +/- 0. 18 hour (zwitterion). Netobimin area under the plasma concentration-time curve (AUC) was 7.59 +/- 3.11 micrograms.h/ml (trisamine) and 6.98 +/- 1.60 micrograms.h/ml (zwitterion). Elimination half-life (tl/2 beta) was 2.59 +/- 0.63 hours (trisamine) and 3.57 +/- 1.45 hours (zwitterion). Albendazole was not detected at any time. Albendazole sulfoxide was detected from 4 hours up to 20 hours (trisamine) and from 6 hours up to 24 hours (zwitterion) after administration of the drug. The Cmax values were 0.48 +/- 0.16 micrograms/ml and 0.46 +/- 0.26 micrograms/ml for trisamine and zwitterion formulations, respectively, achieved at time to peak drug concentration (Tmax) values of 9.50 +/- 1.41 hours (trisamine) and 11.30 +/- 1.04 hours (zwitterion). Albendazole sulfoxide AUC was 3.86 +/- 1.04 micrograms.h/ml (trisamine) and 4.40 +/- 3.24 micrograms.h/ml (zwitterion); tl/2 beta was 3.05 +/- 0.75 hours (trisamine) and 3.90 +/- 1.44 hours (zwitterion). Albendazole sulfone was detected from 4 (trisamine) or 6 hours (zwitterion) to 24 hours after treatment. The AUC was 6.98 +/- 1.60 micrograms.h/ml (trisamine) and 10.51 +/- 7.41 micrograms.h/ml (zwitterion); Cmax was 0.76 +/- 0.21 micrograms/ml at Tmax of 12.00 +/- 1.85 hours (trisamine) and 0.70 +/- 0.24 micrograms/ml at Tmax of 12.50 +/- 2.33 hours (zwitterion). Albendazole sulfone t1/2 beta was significantly (P < 0.05) longer for the zwitterion formulation (7.77 +/- 4.72 hours) than for the trisamine salt (2.87 +/- 0.61 hours). Albendazole sulfone AUC was higher than albendazole sulfoxide AUC, resulting in AUC ratio of 1.8 (trisamine) and 2.4 (zwitterion). The 2 formulations were not significantly different in terms of AUC or Tmax for netobimin and albendazole sulfone, AUC for albendazole sulfoxide, or tl/2 beta for netobimin and albendazole sulfoxide. It was concluded that the 2 netobimin injectable formulations were bioequivalent. Experimental phase had a significant effect on the AUC and Cmax for albendazole sulfoxide and on the Cmax for netobimin. One possible explanation for the differences between phases could be induction of liver microsomal enzymes by netobimin and its metabolites, resulting in increased rate of metabolism during phase 2 of the study.

Objective-To compare serum concentrations of liposome-encapsulated butorphanol tartrate (LEBT) and standard butorphanol tartrate (STDBT) following SC and IM administration, respectively, and to evaluate analgesic effects of LEBT and STDBT after parenteral administration to Hispaniolan parrots. Animals-11 adult Hispaniolan parrots. Procedure-The ability of LEBT to prolong the duration of analgesia in an avian species was tested. Blood samples were collected at serial time points after SC administration of LEBT (10 mg/kg or 15 mg/kg) or IM administration of STDBT (5 mg/kg). Serum concentrations of butorphanol tartrate were determined by use of a commercial immunoassay that measured parent drug and metabolites. Analgesic efficacy was evaluated in parrots exposed to electrical and thermal stimuli. Foot withdrawal thresholds were recorded at baseline and at serial time points after LEBT (15 mg/kg), liposome vehicle, STDBT (2 mg/kg), or physiologic saline (0.9% NaCl) solution administration. Results-LEBT had a prolonged in vivo release for up to 5 days. Negligible serum butorphanol and butorphanol metabolite concentrations were obtained at 24 hours after IM administration of STDBT. Analgesic efficacy of LEBT as measured by foot withdrawal threshold to noxious thermal and electrical stimuli persisted for 3 to 5 days following SC administration of LEBT. Conclusions and Clinical Relevance-SC administration of LEBT provided analgesia and detectable serum butorphanol concentrations in Hispaniolan parrots for up to 5 days. The use of LEBT may allow for substantial improvement in long-term pain relief without subjecting birds to the stress of handling and multiple daily injections.

To examine the postnatal development of equine small intestine, biopsy specimens of jejunal mucosa from 8 ponies, between 6 and 28 weeks old, were subjected to analytical subcellular fractionation and assay of organelle marker enzymes. Fractionation revealed a reduction in the particulate brush border component of beta-galactosidase (lactase) activity between 6 and 28 weeks, and a corresponding increase in soluble activity, although the reduction in mean specific activity was not significant. There also was a decrease in the proportion of brush border to soluble aminopeptidase N activity, a relative loss of brush border gamma-glutamyltransferase activity, and a considerable decrease in the specific activity of alkaline phosphatase throughout the gradient fractions. In contrast, there were marked increases in activities of (alpha-glucosidase (maltase) and sucrase in the older ponies, accompanied by considerable changes in the intracellular distribution of particulate alpha-glucosidase activity, which was predominantly associated with endoplasmic reticulum at 6 weeks, whereas the large increase in activity observed by 28 weeks was clearly associated with the brush border. The modal density of brush borders also increased with age, suggestive of an increase in the glycoprotein-to-lipid ratio of the microvillar membrane. In contrast to these brush border changes, there was relatively little alteration in the activities or density distributions of marker enzymes for endoplasmic reticulum, basolateral membranes, mitochondria, or lysosomes. These findings indicate that maturation of equine intestinal epithelium during the first few months of life results in major changes in the properties and enzyme composition of enterocyte brush borders.

The effects of 3 days of glucocorticoid administration on bovine blood neutrophil expression of L-selectin and CD18, and on the health status of mammary glands subclinically infected with Staphylococcus aureus were measured in 9 lactating Holsteins. The experiment was a 3 x 3 Latin square cross-over design, with 3 glucocorticoid treatments switched among groups of 3 cows/treatment during 3 periods. Treatments consisted of a vehicle (control, 10 ml of excipient/cow/d), cortisol (7.5, 15, and 7.5 mg/cow on days 1, 2, and 3, respectively), and dexamethasone (0.04 mg/kg of body weight/cow/d for total daily dosages that ranged from 21.6 to 33.2 mg). Blood samples for immunostaining and flow cytometric analysis of L-selectin and CD18 and leukograms, as well as foremilk samples for determination of S aureus shedding somatic cell counts, protein and fat percentages, and daily milk yields were collected repeatedly before, during and after treatment days. Dexamethasone caused a profound, acute, short-lived down-regulation of L-selectin on neutrophils, which correlated in time to leukocytosis, mature and immature neutrophilias, increased shedding of S aureus in infected glands, and onset of high percentages of fat and protein and decreased milk yields. Dexamethasone also caused profound but delayed down-regulation of neutrophil CD18, which reached nadir simultaneously with reappearance of L-selectin-bearing neutrophils, normalized blood neutrophil counts, markedly high foremilk somatic cell counts and protein percentage, decreased S aureus shedding in milk, and finally, expression of clinical mastitis in some infected quarters. Each of these variables had returned to control (vehicle) values by the ninth (and last) sample collection day. Although cortisol treatment also decreased expression of L-selectin and CD18 on neutrophils, dosages used in this study were not sufficient to alter the number of circulating cells or to convert subclinical mammary gland infections to clinical mastitis. These results suggest that mammary gland health status can be altered by sudden exposure of blood neutrophils to glucocorticoids, because these steroid hormones caused profound down-regulation of the adhesion molecules that direct neutrophil margination and migration through the vascular endothelium. The results also reinforce the potential disease risk of treating infected animals with potent synthetic glucocorticoids, such as dexamethasone.

Bovine immunodeficiency virus (BIV), a lentivirus, is prevalent in dairy and beef cattle in southeastern United States and may be associated with a lymphoproliferative disease. The mode(s) of BIV transmission are undefined. Because artificial insemination is a common practice in dairy production, contaminated stud semen could serve as an important source of infection if the virus is harbored in seminal fluids. To evaluate this possibility, we procured 11 cryopreserved semen specimens from a stud semen repository. Leukocytes were purified from the specimens, and the leukocyte DNA was used as template in a polymerase chain reaction procedure that targeted a 235-base pair, highly conserved domain of the BIV pol gene. The target sequence was amplified from the seminal leukocyte DNA of 9 of the specimens (82%), and nucleotide sequencing confirmed the BIV specificity of the fragment. This finding provides evidence that stud bull semen may serve as an important reservoir of BIV, suggesting the possibility that artificial insemination of dairy cows may have a major role in transmission and wide-spread dissemination of this bovine lentivirus.

Milk antimicrobial residues are a serious concern for the dairy industry. Residues of the tetracycline family of antimicrobials have been reported in market milk by investigators, using radioimmunoassay and microbial receptor technology (hereafter referred to as the Charm II test). In response to these reports, an investigation was conducted to determine the potential of 3 extra-label routes of oxytetracycline (OTC) administration to cause milk residues above the Food and Drug Administration safe value of 30 parts per billion (ppb). Lactating Holstein cows were administered OTC once by use of 1 of 3 routes: IV at 16.5 mg/kg of body weight (n = 6); IM at 11 mg/kg (n = 6); and intrauterine (IU) at 2 g in 500 ml of saline solution/cow (n = 6). Duplicate milk samples were collected at the milking prior to drug administration and for the next 13 milkings at 12-hour intervals. Concentrations of OTC in milk samples were analyzed by use of the Charm II test for tetracyclines (limit of OTC detection, approx 5 ppb) and were compared with concentrations determined by use of a high-performance liquid chromatography (HPLC) method (lower limit of OTC quantitation, approx 2 ppb). The potential for milk OTC residues above the Food and Drug Administration safe value of 30 ppb after treatment was considerably greater for the IV and IM routes, compared with the IU route. Mean peak OTC concentrations in milk at the first milking after treatment for the HPLC and Charm II tests were approximately 3,700 to 4,200 ppb for the IV route, 2,200 to 2,600 ppb for the IM route, and 186 to 192 ppb for the IU route, respectively. Pharmacokinetic analysis, based on milk OTC concentrations, indicated that the area under the curve (AUC) and milk maximal concentration (Cmax) differed significantly (P < 0.001) among routes of administration. The AUC was similar for IV and IM administrations; values for both were greater than the AUC for IU administration. The Cmax was greatest for IV, intermediate for IM, and least for IU administration. There were significant (P less than or equal to 0.01) differences in AUC between assay methods (Charm II vs HPLC) for the IV route. Concentrations of OTC in milk determined by the Charm II test were often greater than those determined by HPLC. Administration of OTC to lactating cows via these routes is extra-label drug use. Failure to withhold the product from early milkings of cows administered OTC by the IV or IM route should be considered a potential cause of OTC residues in market milk. Milk from nearly all cows contained OTC (< 30 ppb), the Food and Drug Administration safe level, by 120 hours after OTC administration. Use of appropriate withholding times and antibiotic residue testing is indicated to avoid OTC residues.