Blood lead concentrations in three groups of dogs from a suburban Illinois community.

Of 89 clinically normal dogs that were regular patients of a suburban Illinois veterinary hospital, all had blood-lead concentrations (BLC) within the range cited as normal in the literature. In contrast, 22% of 50 dogs from city pound and 15.3% of 98 dogs owned by low-income families of the community had BLC in excess of the normal limits. Additionally, 8% of dogs from the city pound and 4.1% of dogs from low-income families had BLC that are reported to the reliably associated with clinical lead poisoning. Socioeconomic characcteristics of the dog-owning family were more reliably associated with abnormally high BLC than were either history or clinical signs.     

Blood lead concentrations in rabbits

Blood lead concentrations in 68 healthy rabbits from laboratory (n = 15), meat production (n = 45), and home environments (n = 8) were determined. The median blood lead concentration of this heterogeneous population was 8 micrograms/dl (range = 2 to 27 micrograms/dl).     

Agglutinins to Brucella canis in stray dogs from certain counties in Illinois and Wisconsin.

In a serologic and blood culture survey for Brucella canis in 2,572 pound dogs from eight Illinois and Wisconsin counties, 173 (6.7%) were reactive in a presumptive slide test, 41 (1.5%) were reactive in a tube agglutination test, and 6 (0.2%) were positive in blood culture.     

Blood lead and urinary delta aminolevolonic acid (U-ALA) in the diagnosis of lead toxicosis of dogs

A comparative evaluation of the usefulness of blood lead and urinary delta aminolevolonic acid estimations in the diagnosis of canine lead poisoning was made in 2 dogs which were given increasing quantities of lead by mouth for extended periods. In both lead administered dogs the blood lead levels remained elevated throughout the experimental period of 18 weeks. This contrasted with the results of U-ALA determinations in which elevated levels were detected only infrequently and at erratic intervals lacking relationship to lead exposure.     

Blood vitamin and choline concentrations in healthy domestic cats, dogs, and horses

Blood concentrations of thiamin, biotin, nicotinates, pantothenates, folates, riboflavin, vitamins A, B6, B12, C, E, beta-carotene and choline were analyzed in healthy animals (23 horses, 25 dogs, and 29 cats). B-Complex vitamins and choline also were analyzed in the liver of the dogs and cats. Vitamin concentrations in the blood and livers of dogs were similar; however, blood vitamin A and beta-carotene concentrations were lower in the cat than in the dog. Horses had a higher B12 blood concentration than did the dogs and cats. These data can be useful for detecting overt and hidden vitamin deficits in these species due to various conditions.     

Blood vitamin concentrations in privately owned dogs fed non-standardized commercial diets and after intake of diets with specified vitamin concentrations

The objective was to investigate in a survey study the blood vitamin concentrations in healthy dogs fed non-specified commercial complete diets and in an intervention study to determine the effects of defined dietary vitamin intakes on blood vitamin levels and hair and skin condition. Sixty-four privately owned dogs, aged from 1 to 8 years, without history of skin or coat problems were included. All animals were fed commercial complete diets with uncertain vitamin concentrations before enrolment. The animals were assigned, according to weight and gender, to four groups with graded vitamin intakes. The blood vitamin levels and skin and coat quality of the dogs were investigated at days 0 and day 122. Coat and hair condition was not influenced by the experimental diets. The retinol concentrations were reduced at the end of the experiment compared with the baseline levels, retinyl esters were not influenced. 25-Hydroxycholecalciferol decreased in all groups, alpha-tocopherol was constant or tended to decrease. Ascorbic acid, thiamine pyrophosphate and riboflavin concentrations were not affected by treatment, flavin adenine dinucleotide and pyridoxal-5'-phosphate were partially reduced on day 122. Cobalamin, pantothenate and biotin concentrations increased with higher dietary intakes, folate levels in tendency. In conclusion, this study gives a survey of blood vitamin concentrations in healthy dogs and provides a data base for the evaluation of the vitamin status in health and disease.     

Blood glycated hemoglobin evaluation in sick dogs.

Blood glycated hemoglobin concentration reflects long-term serum glucose levels in dogs. In this study, the effects of several diseases on blood glycated hemoglobin levels have been evaluated. For this study, blood samples were drawn from 93 unhealthy dogs. The animals were distributed into 10 groups according to pathological process (group 1, digestive problems; group 2, leishmaniasis; group 3, anemia; group 4, dermatological disorders; group 5, urinary problems; group 6, cardiorespiratory problems; group 7, diabetes mellitus; group 8, insulinoma; group 9, general diseases; group 10, control group). Blood glucose and glycated hemoglobin concentrations and hemoglobin and hematocrit values were analyzed in all the animals. In diabetic dogs, a strong increase in blood glycated hemoglobin was observed when compared with the other groups (P < 0.01). In contrast, dogs with insulinoma showed a decrease in blood glycated hemoglobin, though significant differences were not reported in all cases. No change in blood glycated hemoglobin concentrations were reported in dogs affected by other diseases. So, we can suppose that only the chronic alterations in glucose metabolism (chronic hyper- or hypoglycemia) can induce significant changes on the blood glycated hemoglobin concentrations in dogs.     

Industrial lead contamination of an Illinois wildlife refuge and indigenous small mammals

Deer mice (Peromyscus maniculatus) were trapped from a sand prairie at various distances from an adjacent battery lead reclamation plant. Analysis of liver, kidney, and bone for lead concentrations showed an increase of tissue lead concentrations over controls to a distance of approximately 400 m. Soil and plant lead concentrations roughly correlated with the findings in deer mouse tissues. At higher tissue lead concentrations, acid-fast staining intranuclear inclusions within renal tubular epithelial cells were an occasional finding.     

Endostatin concentrations in healthy dogs and dogs with selected neoplasms

Endostatin prevents angiogenesis and tumor growth by inhibiting endothelial cell proliferation and migration. The purpose of this study was to determine serum endostatin concentrations in 53 healthy dogs and in 38 dogs with confirmed malignant neoplasms. Endostatin concentration was determined with a competitive enzymatic immunoassay (EIA) with rabbit polyclonal antibody generated against a recombinant canine endostatin protein. Both the presence of cancer and increasing age were associated with increased serum concentration of endostatin. Endostatin concentration in healthy dogs was 87.7 +/- 3.5 ng/mL. Upper and lower limits of the reference range for serum endostatin concentration in healthy dogs were 60 and 113 ng/mL. Dogs with lymphoma (LSA) and hemangiosarcoma (HSA) had endostatin concentrations of 107 +/- 9.3 ng/mL. In conclusion, this study demonstrates that endostatin can be quantified in dogs and that endostatin concentrations are high in dogs with HSA and LSA.     

Plasma free cortisol concentrations in dogs with hyperadrenocorticism.

Unbound or free cortisol constitutes a small fraction of total plasma cortisol, but is believed to represent the biologically active portion of this circulating glucocorticoid. We tested the hypothesis that the percentage free cortisol was altered in plasma from dogs with hyperadrenocorticism, which could account for a greater target tissue response to this circulating hormone. The percentage free cortisol in plasma samples from human beings, healthy dogs, and dogs with hyperadrenocorticism was estimated, using centrifugal ultrafiltration-dialysis. Total cortisol concentrations were determined by use of radioimmunoassay. Total cortisol concentrations appeared greater in plasma from human beings than in plasma from either group of dogs. However, the percentage free cortisol was lower in plasma from human beings, resulting in a calculated concentration of free cortisol that was quite similar between plasma from human beings and healthy dogs. Total plasma cortisol concentrations were greater (P less than 0.01) in samples from dogs with hyperadrenocorticism (190 +/- 113 nmol/L; mean +/- SD) than in healthy dogs (102 +/- 85 nmol/L), but the percentage free cortisol was not different between these 2 groups (dogs with hyperadrenocorticism, 16 +/- 9%; healthy dogs, 13 +/- 6%). However, plasma free cortisol concentrations (product of total and the percentage of free cortisol) were greater (P less than 0.01) in samples from dogs with hyperadrenocorticism (36 +/- 41 nmol/L) than in those from healthy dogs (16 +/- 9 nmol/L). Significant (P less than 0.001) positive linear relationships were found between total cortisol concentrations and percentage free cortisol in plasma samples from healthy dogs and dogs with hyperadrenocorticism.(ABSTRACT TRUNCATED AT 250 WORDS)     

Serum free and total iodothyronine concentrations in dogs with hyperadrenocorticism.

Serum concentrations of total and free thyroxine (T4 and FT4, respectively), 3,5,3'-triiodothyronine (T3), 3,3',5'-triiodothyronine (reverse T3) were measured in 42 dogs with hyperadrenocorticism, and were compared with values determined in clinically normal dogs. Mean total T4 concentration in dogs with hyperadrenocorticism (14.3 nmol/L) was significantly (P less than 0.001) lower than the normal value (25.7 nmol/L), with 38% of the dogs having low serum T4 concentration. Although 16 (38%) of the 42 dogs with hyperadrenocorticism had a high FT4 fraction, indicative of diminished serum T4 binding, normal FT4 concentration was found in only 6 of the 16 dogs (38%) with low total T4 values. Mean serum T3 concentration in dogs with hyperadrenocorticism (0.79 nmol/L) was also significantly (P less than 0.001) lower than the normal value (1.16 nmol/L), with 39% of the dogs having T3 values below the normal range. Individual T3-to-T4 and T3-to-FT4 ratios, indices of T3 production and/or clearance, were above the normal range in 29 and 24% of dogs with hyperadrenocorticism, respectively. Mean reverse T3 concentration in dogs with hyperadrenocorticism (0.17 nmol/L) was also significantly (P less than 0.001) lower than the normal mean value (0.39 nmol/L), with 48% of the dogs having reverse T3 values below the normal range. Of the 21 dogs in which all iodothyronines were measured, 6 (29%) had undetectable values for all hormones.(ABSTRACT TRUNCATED AT 250 WORDS)     

Blood selenium concentrations of sheep and goats from selected areas of Kenya

A systematic mapping technique based on blood, forage and soil selenium levels was employed to locate areas of selenium deficiency, adequacy or excess in areas of Kenya where grazing of small ruminants predominates. A total of 1,478 blood samples from both sheep and goats, 180 forage samples and 90 soil samples were analysed for selenium levels. During the wet seasons 28% of the sheep and 15% of the goats had marginal to deficient blood selenium concentrations while during the dry season 20% of the sheep and 12% of the goats had marginal to deficient blood selenium concentrations. Forage samples had a range of 0.03 to 0.66 ppm selenium while soil samples had a range of 0.06 to 0.98 ppm selenium. Although many animals had blood selenium levels of less than 0.05 ppm, below which selenium deficiency signs might occur, none of the animals manifested these signs.     

Expanding families: preparing for and introducing dogs and cats to infants, children, and new pets

Once clients make a decision to expand their family with children or pets, veterinarians can be instrumental in providing education and support to make the additions successful. Veterinarians should remind clients to make changes in the household well in advance of the new addition's arrival, to be patient, to make all introductions safe and controlled, and to reward good behavior. If problems arise, owners should be advised to separate those involved and get behavioral treatment as soon as possible. Through these simple steps, veterinarians can increase the likelihood that clients will be able to integrate new family members successfully.     

Serial thyroid hormone concentrations in healthy euthyroid dogs, dogs with hypothyroidism, and euthyroid dogs with atopic dermatitis.

Serum thyroxine (T4) and 3,5,3'-triiodothyronine (T3) concentrations were determined every 3 h for 12 h beginning at 8 a.m. in 20 healthy euthyroid dogs, 19 dogs with hypothyroidism, and 18 euthyroid dogs with atopic dermatitis. Status of thyroid function was based on history, physical findings, results of thyrotropin response testing, and requirement for thyroid hormone replacement therapy. Mean serum T4 and T3 concentrations did not vary significantly between blood samplings within each of the three groups of dogs. Between groups of dogs, mean serum T4 concentration was significantly (P less than 0.05) higher at each blood sampling time in healthy euthyroid dogs and euthyroid dogs with atopic dermatitis when compared to dogs with hypothyroidism. There was no significant difference in mean serum T4 concentration at any blood sampling time between healthy euthyroid dogs and euthyroid dogs with atopic dermatitis or in mean serum T3 concentrations at any blood sampling time between any of the three groups of dogs. Random fluctuation in serum T4 and T3 concentrations was found in dogs in all three groups. Random fluctuations were more common with serum T3 versus T4 concentrations. Consequently, sensitivity (0.88 versus 0.52), specificity (0.73 versus 0.45), predictive value for a positive test (0.75 versus 0.32), predictive value for a negative test (0.87 versus 0.65), and accuracy (0.80 versus 0.47) were better for serum T4 concentration than serum T3 concentration, respectively, when all blood samples were analysed. Measurement of serum T4 concentration was more accurate than serum T3 concentration in assessing the status of thyroid gland function.