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Homocysteine measurement by an enzymatic method and potential role of homocysteine as a biomarker in dogs

Correspondence: ¹Corresponding Author: Saverio Paltrinieri, Department of Veterinary Pathology, Hygiene and Public Health, University of Milan, Via Celoria 10, 20133 Milan, Italy. saverio.paltrinieri{at}unimi.it

	Abstract

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In humans, homocysteine (Hcy) is employed to monitor renal, cardiovascular, and other diseases and their complications. The aim of the current study was to define the analytical performances of an enzymatic method not yet validated in dogs for measuring homocysteine, and to assess the possible clinical usefulness of Hcy measurement. Using conventional approaches, the analytical performances were investigated by assessing, imprecision, inaccuracy, and interference of hemoglobin, triglycerides, and bilirubin. The possible clinical usefulness of Hcy determination was assessed by comparing the results of healthy dogs (n = 8) with those of dogs with heart disease (n = 10), inflammation (n = 6), gastrointestinal disorders (n = 7), neoplasia (n = 8), renal failure (n = 4), trauma (n = 7), and other miscellaneous diseases (n = 6). Preliminary evaluation of this enzymatic method showed it to be precise at Hcy levels close to or higher than the values in dogs with renal or cardiac disorders that had the highest Hcy levels. By contrast, at low Hcy levels, which were recorded basically in control dogs, the method suffers from high imprecision. The sample of choice is serum. The use of icteric samples should be avoided, while hemoglobin and lipids have only a minor effect on Hcy measurement. In conclusion, the enzymatic method employed in the current study provides useful information in dogs and could be used to monitor cardiac and renal disorders, in which Hcy concentrations are elevated.

Key Words: Biomarker • dogs • enzymatic method • heart disease • homocysteine • renal failure

Homocysteine (Hcy) is a sulfur-containing intermediate product of methionine metabolism and is further metabolized by vitamin B₁₂- or B₆-dependent pathways.17 In humans, hyperhomocysteinemia (HHcy) is a sensitive marker of folate and B-vitamin deficiency and is considered an independent risk factor for cardiovascular disease (CVD) and thrombotic-, neurodegenerative-, and -pregnancy-associated diseases.13,17 Specifically, HHcy is associated with an increased incidence of congestive heart failure (CHF), as well as with the severity of the disease. In high-risk populations, increased Hcy is a prognostic marker for an increased risk of new CVD events or mortality.7 High plasma concentrations of Hcy and low levels of B vitamins are risk factors for coronary and cerebral atherosclerosis and peripheral vascular disease.4 Moreover, HHcy has been shown to be an independent risk factor for cardiovascular disease in renal patients5,12,16; plasmatic levels of Hcy are inversely correlated with the glomerular filtration rate (GFR)5 and positively correlated with serum creatinine.16 Further, an increased risk of mortality was found in patients with HHcy and diabetes.18

In the veterinary literature, publications on the possible usefulness of Hcy as a risk factor or as a prognostic or diagnostic biomarker are rare. Studies in cats with heart diseases or arterial thromboembolism (ATE) provided controversial results (Hohenhaus AE, Simantov R, Fox PR, et al.: 1999, Evaluation of plasma homocysteine and B vitamin concentrations in cardiomyopathic cats with congestive heart failure and arterial thromboembolism. In: Proceedings of the Nestle Purina Nutrition Forum, p. 170. St. Louis, MO),11 and studies on the relationship between Hcy concentration in cats and hypocobalaminemia or cobalamin therapy suggested that serum Hcy concentration does not depend upon cobalamin availability.14,15 The only study for dogs2 demonstrated that Hcy levels were not affected by the short-term administration of a peripheral parenteral nutrition product. All the studies published in veterinary medicine employed high-performance liquid chromatography (HPLC), which is accurate but unpractical, expensive, and requires long run-times and specialized personnel. The aims of the current study were to investigate the analytical performances of an enzymatic colorimetric method for measurement of Hcy on canine samples that had previously been validated with human samples3 and to assess Hcy levels in healthy dogs and in dogs affected by different pathologic conditions to determine the possible clinical usefulness of this parameter.

Fifty-six canine blood samples were obtained, under informed consent, from client-owned dogs referred to the authors' respective institutions for various diagnostic or therapeutic measures. The samples were put in plastic tubes containing clot activator and separation gel.^a Sera were obtained by centrifugation (1500 x g for 7 min) within 30 min, and subsequently stored in plastic tubes at –20°C until analysis, for no longer than 1 month. To assess the possible influence of anticoagulants in 8 cases, aliquots of blood were also put into ethylenediamine tetra-acetic acid (EDTA) plastic tubes^b and lithium-heparin plastic tubes^b filled to their maximum capacity. Sera or plasma samples from the dogs were collected within 30 min by centrifugation at 1500 x g for 15 min and immediately analyzed.

Based on clinical examination, hematology, clinical biochemistry, and additional diagnostic tests, such as radiography and ultrasonography, dogs were classified in the following groups:

• Control: 8 dogs (3 males, 5 females; age range: 1–6 years; median age: 2.5 years) sampled during routine wellness visits or before spaying/neutering. When sampled, these dogs did not show any clinical or laboratory abnormalities, especially regarding heart and kidney functions.
  
• Heart disease: 10 dogs (6 males, 4 females; age range: 1–14 years; median age: 8 years). This group included dogs with dilated cardiomyopathy, mitral insufficiency, pulmonic stenosis, congenital arrhythmia, and patent ductus arteriosus.
  
• Inflammation: 6 dogs (1 male, 5 females; age range: 3–11 years; median age: 5.5 years) with pyometra (n = 2), eosinophilic pneumonia, ehrlichiosis, leishmaniasis, or pyoderma.
  
• Gastrointestinal disorders: 7 dogs (3 males, 4 females; age range: 3–12 years; median age: 8 years) with pyloric stenosis (n = 3), intestinal obstruction (n = 3), or gastric ulceration (n = 1).
  
• Neoplasia: 8 dogs (4 males, 4 females; age range: 7–12 years; median age: 10 years). Neoplasms diagnosed in these dogs included histiocytoma, pulmonary carcinoma, lipoma, mammary carcinoma, ovarian carcinoma, and synoviosarcoma. Insulinoma was suspected in 1 case. In another case, a splenic mass was identified but not further investigated by cytology or histology.
  
• Kidney disease: 4 dogs (1 male, 3 females; age range: 10–17 years; median age: 11 years). All dogs in this group had increased creatinine and urea with additional biochemical changes consistent with renal azotemia caused by chronic renal failure (n = 3) or acute renal failure (n = 1).
  
• Trauma: 7 dogs (1 male, 6 female; age range: 1–10 years; median age: 3 years) that experienced traumatic events, including fractures or joint injuries.
  
• Miscellaneous diseases: 6 dogs (3 males, 3 females; age range: 1–11 years; median age: 6.8 years). This group included dogs with gastric torsion, postsurgical hemorrhage, chronic diaphragmatic hernia, and neurological signs of undetermined origin (n = 2).
  

Homocysteine was measured with an automated spectrophotometer^c using a commercially available kit based on an enzymatic cycling reaction that detects Hcy in human serum or plasma.^d,3 At the beginning of each batch of tests, the instrument was calibrated using the human-based calibrator provided by the manufacturer of the kit,^d and human-based control solutions^d (low control = 7.0 ± 1.1 µmol/l; high control = 29.0 ± 4.4 µmol/l) were employed to assess the efficiency of the calibration.

After thawing, Hcy concentration was determined for all serum samples by measuring each sample in triplicate. The mean value, the standard deviation (SD), and the coefficient of variation (CV = SD/mean x 100) were calculated using an Excel^e spreadsheet with Analyse-it software.^f The same software was used to perform all the statistical analyses.

Samples were then used to prepare the reference material listed in Table 1. Except for the "high Hcy level" sample (sample A), which was prepared by aliquoting the sample with the highest Hcy concentration, all the reference samples were obtained by pooling sera with medium-to-high (pools B and D) or medium-to-low (pools C, E, and F) concentrations of Hcy. Aliquots of each pool were assayed immediately or, as regards interassay variability, stored frozen at –20°C. The analytical characteristics of the tests on canine samples were assessed by a basic panel of validation procedures suggested in the published literature19 and previously employed in similar studies.8 Although less complete than other validation approaches (based on additional tests and on higher numbers of replicates), this basic panel was considered adequate to provide preliminary information on analytical aspects and on the possible clinical usefulness of Hcy concentration in the blood.9,19

Although the lower limit of quantification (the lowest amount of the analyte that can be determined with suitable precision and accuracy) has not been statistically assessed in the current study, the poor precision at low Hcy levels was confirmed by the results of the linearity under dilution (LUD) test and the recovery tests. Although these 2 tests cannot replace conventional approaches to evaluate the inaccuracy of tests (e.g., method comparison and proficiency testing, which are not available for the Hcy method employed in this study),9 in many papers,8,10 LUD and recovery tests are used as indirect methods to "estimate" inaccuracy and to provide information about reportable ranges and proportional systematic errors, respectively.9,19 The LUD test was performed by diluting pool D with saline solution to obtain samples containing 80%, 60%, 40%, and 20% of the analyte. The recovery test was performed by adding 3 aliquots (100 µl each) of pool E to 3 different volumes (25, 50, and 75 µl) of pool D. All the samples, including undiluted pools D and E, were analyzed in triplicate. The percentage of recovery compared with expected values (Table 2) was close to 100% for both the tests except for the sample corresponding to 20% dilution. Least square linear regression (Fig. 1) demonstrated an excellent degree of correlation for both LUD (R² = 0.99; P = 0.000) and recovery (R² = 0.98; P = 0.011) tests. In both cases, data fit the linear model. The results demonstrate that the analytical method was linear in the range of values examined and that no proportional systematic errors were present.

View larger version (13K): [in this window] [in a new window]   Figure 1 Linearity under dilution (LUD) of serum pool D and recovery tests obtained by mixing different amount of pool E with a fixed amount of pool D. Observed values (in µmol/l) were statistically correlated to the expected value according to a linear model, as demonstrated by the "lack of fit" test. LUD test—intercept: –0.90 (95% confidence interval [CI]: –3.37 to 1.57); slope: 1.05 (95% CI: 0.90–1.21); recovery test—intercept: –2.31 (95% CI: –10.27 to 5.64); slope: 1.17 (95% CI: 0.63–1.71).

View larger version (12K): [in this window] [in a new window]   Figure 2 Interferogram for hemoglobin, triglycerides, and bilirubin. Results are expressed as percentage of the original value. Each data point represents the mean ± standard deviation of triplicate measurement, expressed as percentage variation compared with the basal value. * = significantly higher (P < 0.001) than the baseline value.

Although the definition of the precise diagnostic or prognostic role of Hcy measurement in different pathologic conditions, establishment of reference intervals and discrimination values, and the possible influence of variables such as sex and age on Hcy concentration were out of the scope of the current study, the potential role of Hcy as a biomarker in dogs was investigated by comparing particular categories of diseases. Data from the different groups of dogs were compared by the Kruskal-Wallis test, followed by the Dunn's multiple comparison test, to investigate possible group differences. Control dogs had a mean Hcy value of 5.72 ± 3.26 µmol/l (median = 5.82 µmol/l, min.–max. range: 1.43–11.23 µmol/l). This value demonstrated that test results >5.0 µmol/l are likely to be clinically relevant. It is thus unlikely that the imprecision of the method at low Hcy levels would affect clinical decisions. The other groups had Hcy values that were not significantly different from those of the control group, with the exception of dogs with renal diseases (18.86 ± 10.15 µmol/l; median: 16.99 µmol/l, min.–max. range: 9.38–32.07 µmol/liter) or with heart disease (10.21 ± 6.09 µmol/l; median: quals; 7.64 µmol/l, min.–max. range: 4.47–24.50 µmol/l), which were significantly different (P < 0.001 and P < 0.05, respectively) from those of the control group (Fig. 3). The groups included in the present study were heterogeneous in terms of age, sex, type of pathophysiology, and severity of diseases. In addition, there was no information about the presence of complications that were potentially responsible for hypertension such as arterial stenosis or endothelial damage. Although statistically significant sex- or age-related differences were not detected, it is possible that the other factors mentioned above could influence the distribution of Hcy values in healthy and diseased dogs. Nevertheless, the results suggest that, as in humans, renal and cardiac diseases in dogs are characterized by increased Hcy levels. To assess the possible clinical usefulness of Hcy measurement, for each point value, the diagnostic specificity and sensitivity of high Hcy concentrations were calculated using standard formulae to identify a "positive" group composed of dogs with renal or cardiac diseases.19 The discriminating power of Hcy for these conditions was assessed by designing a receiver operating characteristic (ROC) curve and by calculating the positive likelihood ratio.6 The area under the ROC curve (Fig. 4) was 77%, and the likelihood ratio to distinguish these conditions from other diseases was >3 at Hcy values >9.1 µmol/l (data not shown). This information, coupled with the pretest probability of disease raised by other clinical, clinicopathological, or instrumental data, could improve diagnosticians' ability to detect and monitor renal and cardiac diseases.

View larger version (10K): [in this window] [in a new window]   Figure 3 Concentration of homocysteine (Hcy) recorded in the following groups of dogs: C = controls; H = heart diseases; I = inflammation; GI = gastrointestinal diseases; N = neoplasia; K = kidney disease; T = trauma; and O = others (miscellaneous). Boxes = I–III inter-quartile range; horizontal lines = median value; vertical lines = min.–max. range; * = P < 0.05 vs. control group; *** = P < 0.001 vs. control group.

View larger version (16K): [in this window] [in a new window]   Figure 4 Receiver operating characteristic curve showing the discriminating power of homocysteine for cardiac or renal diseases.

	Acknowledgments

 
The authors thank Dr. Wolfgang Ziemann and Kerstin Sommer (Demeditec Diagnostics GmbH), and the staff of the Veterinary Clinic Malpensa.

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From the Veterinary Clinic Malpensa–Samarate, Varese, Italy (S Rossi), and the Department of Veterinary Pathology, Hygiene and Public Health, University of Milan, Milan, Italy (G Rossi, Giordano, Paltrinieri).

^a. Nuova Aptaca Srl, Asti, Italy.

^b. Venoject®, Terumo Corp., Rome, Italy.

^c. Cobas Mira®, F. Hoffmann-La Roche Ltd, Basel, Switzerland.

^d. Demeditec Diagnostics GmbH, Kiel, Germany.

^e. Microsoft Corp., Redmond, WA.

^f. Analyse-it Software Ltd., Leeds, UK.

^g. Merck KGaA, Darmstadt, Germany.

^h. Lipofundin® S 20%, B. Braun Milano SpA, Milano Italy.

^i. Fluka, Sigma-Aldrich, Milano, Italy.

^j. Hemat 8, SEAC, Firenze, Italy.

^k. Real Time Diagnostic System, Viterbo, Italy.

^l. Instrumentation Laboratory SpA, Milano Italy.

	References

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