SciELO - Scientific Electronic Library Online

 
vol.19 issue3Thrombocyte indices in dogs infected with Ehrlichia canis and Anaplasma phagocytophilumBlood biochemical parameters of broilers fed differently thermal processed soybean meal author indexsubject indexarticles search
Home Pagealphabetic serial listing  

Services on Demand

Journal

Article

Indicators

Related links

  • On index processCited by Google
  • Have no similar articlesSimilars in SciELO
  • On index processSimilars in Google

Share


Revista MVZ Córdoba

Print version ISSN 0122-0268

Rev.MVZ Cordoba vol.19 no.3 Córdoba Sept./Dec. 2014

 

ORIGINAL

Analgesic effect and side effects of celecoxib and meloxicam in canine hip osteoarthritis

Efectos analgésicos y secundarios de celecoxib y meloxicam en osteoartritis de cadera canina

Víctor Molina D,* M.Sc, David Álzate V, M.Sc, Jhon Ruíz B, Ph.D, Manuela Urrea A, MVZ, Juan Tobón J, MVZ.

1Universidad CES, Faculty of Veterinary Medicine and Zootechnics. INCA-CES Group, Medellin-Colombia, AA 054591.

*Correspondence: dooncanmc@hotmail.com

Received: March 2014; Accepted: September 2014.


ABSTRACT

Objective. To evaluate the pharmacological, clinical and toxicological effects of celecoxib and meloxicam for analgesia for 30 days in dogs with hip osteoarthritis. Materials and methods. Twenty-four patients were evaluated, 75% were females with an average age of 7.16 ± 2.06 years and twenty five percent were males with an average age of 7.83 ± 2.22 years. All patients had hip osteoarthritis and they were randomized into two groups; one group received oral celecoxib 5 mg/kg every 12 hours during one month and the second group received oral meloxicam 0.2 mg/kg every 24 hours during 1 month. The patients were evaluated for analgesia, and hematological, renal, liver, and coagulation tests on days 0, 10th and 30th after treatment initiation, and a gastric endoscopy on day 30. Statistical analysis was performed using a HSD Tukey test and c2 with a 5% level of statistical significance. Results. Both drugs reduced articular pain according to the Melbourne scale during the 30 days of treatment (p≤0.05). Hematological, renal, hepatic and coagulation tests were normal in both treatment groups. All patients presented chronic gastritis on endoscopy on day 30th. Conclusions. Both drugs decreased pain at day 30th without causing alterations in hematological, renal, hepatic or coagulation tests after 30 days of treatment. However, both drugs induced chronic gastritis.

Key words: Dog, NSAIDS, pain, pharmacology (Source: Mesh).


RESUMEN

Objetivos. Evaluar el efecto farmacológico, clínico y toxicológico de celecoxib y meloxicam utilizados como analgésicos durante 30 días en caninos con osteoartritis de cadera. Materiales y métodos. Fueron evaluados 24 pacientes, 75% hembras, con edad de 7.16 ± 2.06 años, y el 25% machos; con edad de 7.83 ± 2.22 años, todos tenían osteoartritis de cadera, se asignaron aleatoriamente a dos grupos; un grupo recibió celecoxib 5 mg/kg oral cada 12 horas durante 1 mes y el segundo grupo recibió 0.2 mg/kg de meloxicam, oral cada 24 horas durante 1 mes. Todos fueron evaluados por grado de analgesia y pruebas renales, hepáticas y de coagulación al día 0, 10 y 30. Se realizó una endoscopía gástrica al día 30. Para el análisis estadístico se utilizó el test HSD Tukey y c2, con nivel significancia del 5%. Resultados. Ambos tratamientos redujeron el dolor articular durante los 30 días, según la escala Melbourne (p≤0.05). Las variables hemáticas, renales, hepáticas y de coagulación estuvieron dentro de los valores normales sin diferencia. Todos presentaron gastritis crónica por endoscopia a los 30 días. Conclusiones. Ambos fármacos redujeron el dolor, ninguno tuvo efectos sobre la hematología, función renal, hepática y de coagulación a los 30 días; sin embargo, hubo gastritis crónica a los 30 días.

Palabras clave: Aines, dolor, farmacología, perro (Fuente: Mesh).


INTRODUCTION

The long-term use of non-steroidal anti-inflammatory drugs (NSAIDS) for the treatment of osteoarticular pain in canines is routine (1, 2), the most used therapeutic tool being selective NSAIDS (3, 4). Meloxicam, a selective NSAIDS, has been used as the standard treatment for osteoarticular pain canines (5) but it has been determined that continued use of this drug provokes digestive alterations and hepatic and renal insufficiencies (6-8) in canines. It has been detailed that other NSAIDS, specific as well as Coxibs, are less damaging in the long-term due to specificity because of cyclooxygenase 2 (COX2) (9). But few studies have been done for celecoxib in canines (10). Specifically in Colombia, where the availability of new COXIBs in veterinary medicine is non-existent, as well as the variety of breeds and crossbreeds, makes the use of these specific COX2 inhibitors a new therapeutic alternative for canines with articular pain.

Celecoxib is used on humans with arthrosis, rheumatoid arthritis and osteoarthritis, improving pain after 2-13 weeks of treatment (11). In canines Coxibs have been used more frequently for hip arthrosis treatment (2, 9, 12).

The renal effects of NSAIDS include: reduction of the glomerular filtration rate and suppression of prostaglandin E2, which leads to renal insufficiency with prolonged use (3). Selective and specific NSAIDS are supposed to be less damaging (13); however, this is not completely true, since renal function is not preserved, due to serious renal toxicity when used for long periods in people (8, 14). In dogs, meloxicam used for one month caused renal damage due to blockage of PGE2 (15). This differs from studies done by Doig et al (16) where it was found that canines tolerate meloxicam for four weeks. Theoretically celecoxib, on the other hand, should not alter renal function, due to its specificity, but it has been found to cause papillary necrosis in humans (17) due to COX2 inhibition, that it affects the glomerular filtration rate and therefore behaves like the majority of NSAIDS, in addition to modifying sodium elimination (13, 17). In canines, renal effects are arguable since long-term therapies with COXIBs have not demonstrated renal damage (18, 19).

The effects of NSAIDS on the liver are not conclusive in veterinary medicine (15) and it is presumed that hepatic reactions are idiosyncratic and not due to the drug. Hepatic lesions described are caused by meloxicam (7) and have not been described for celecoxib in canines (18, 19).

Hematologic alterations in canines due to meloxicam have not been described, but are presumed due to COX1 inhibition in lesser proportion that interferes with platelet aggregation (15, 20) and increases hemorrhagic risk, although with greater selectivity there is less inhibition of platelet aggregation.

An evaluation of the digestive tract has demonstrated that the use of any NSAIDS causes gastritis (6). In humans, the prolonged use of celecoxib did not produce gastrointestinal effects (14), while meloxicam did (21). Other authors affirm that celecoxib, like other NSAIDS, is harmful to gastric mucous due to acidic pKa (22).

The objective of this study was to evaluate and compare the pharmacologic, clinical and toxicological effects of celecoxib and meloxicam in dogs with hip osteoarthritis (OA) during a 30 day treatment period.

MATERIALS AND METHODS

Study site and methodology. A controlled, random, double blind clinical prospective experiment was performed. Neither the investigators nor the executers knew the treatment to be administered, and the heads of lab tests and histopathology did not know which therapy each patient received (double blind study). Groups were chosen randomly and assigned by numerical lottery. All the patients had been diagnosed with hip arthrosis, with a hip radiography showing a degree of dysplasia IV and visited the veterinary center of the Universidad CED in Envigado, Colombia.

Ethical aspects. This project was carried out under ethical act no. 69 of the Ethical Committee on Animal Experimentation of the Universidad de Antioquia.

Protocol evaluation. The evaluation of the evolution of both protocols was done by qualified medical personnel that did not know what treatment was given and was based on data collecting formats for each variable.

Patient inclusion criteria. Males and females from 2 to 10 years of age and a variety of breeds were included, all having gone to the veterinary center, weighing 10 kg or more, without individual history of renal, hepatic or digestive insufficiency or clotting diseases, with a normal endoscopic evaluation and stomach mucous biopsy.

All the patients presented hip osteoarthritis, with hip dysplasia symptoms diagnosed by radiography, presenting changes to the femur head, acetabulum, Nolberg Angle and Rhodes Distance at grade IV for all the patients.

Patient selection criteria. Twenty four patients were included, 18 females and 6 males; 12 were crossbreeds, 9 Labradors, 1 French bulldog, 1 Dalmatian, 1 Boxer. They were randomized into two groups by number selection. Sample calculations had a standard error of 2.05.

Treatments. Celecoxib Group, twelve dogs received celecoxib 5 mg/kg orally every 12 hours for 30 days. 66.6% were females and 33.3% males; 58.3% Labradors, 25% crossbreed, 8.3% and 8.3% Dalmatians and Boxers respectively, with an average age of 7±2.4 years. The average weight was 30.5±13.9 kg.

Meloxicam Group, twelve dogs received meloxicam 0.2 mg/kg orally every 24 hours for 30 days. The meloxicam group was made up of 12 dogs, 83.3% females, 16.6% males, 75% crossbreeds, 16.6% Labradors and 8.3% French bulldog, with an average age of 7.7±1.7 years old, and a weight of 26.1 ± 11.4 kg.

Pain evaluation. Each patient received a complete general evaluation before beginning medication; the evaluator did not take part in the investigation project and did not know about the therapy, and each patient was evaluated for: age, sex, weight, breed, reproductive state, cardiac frequency and respiratory frequency. All the patients were evaluated with the Ortolanni orthopedic test. The presence or absence of pain was evaluated according to the Melbourne scale (UMPS) 0-27 (23). Corresponding: 0, absence of pain, 1-8 light pain, 9-15 moderate and more than 15, severe pain (Table 1).

Hematologic evaluation. Samples were obtained from the external jugular vein after skin disinfection and were collected in an EDTA tube (Vacutainer®, Becton, Dickinson) and refrigerated at 2°C and were sent to the Instituto Colombiano de Medicina Tropical (ICMT), where they were processed in the Abacus Junior Vet® device (Diatron Ltda, Austria). The hematologic tests performed were: hematocrit (Hto), hemoglobin (Hg), mean cell volume (MCV), mean cell hemoglobin (MCH), mean concentration of cell hemoglobin (MCHC), erythrocyte and plasma protein count. The tests were done on days 0, 10 and 30. The laboratory supplied the reference values.

Renal evaluation. All the patients were tested for renal function. Samples obtained in sample tubes were refrigerated and sent to ICMT. They measured levels of: creatinine, urea and phosphorus. Additionally, medial cystocentesis was performed to evaluate urine, which was evaluated with strips and an optic microscope for sediment. Results were evaluated according to the reference values provided by the laboratory and samples were collected on days 0, 10 and 30.

Hepatic function evaluation. Samples obtained in the external jugular vein in a red tube. Levels of alanine aminotransferase (ALT), alkaline phosphatase (AP), direct and indirect bilirubin and albumin were measured on days 0, 10 and 30 of the treatment. The device used was Biosystems® A15 (Biosystem SA, Barcelona, Spain). The reference values were supplied by ICMT.

Clotting evaluation. Samples were obtained in a tube with a blue cap, with potassium citrate, and the tests performed were: prothrombin time and partial thromboplastin time, on days 0, 10 and 30 after beginning medication. Data was obtained through manual coagulometry.

Digestive evaluation. All the dogs went through a digestive evaluation, a daily qualitative evaluation. Digestive symptoms presented during the treatment were: hyporexia 1, anorexia 2, nausea 3, vomiting 4 and diarrhea 5. Hyporexia was considered to be a decrease in appetite and anorexia was the complete absence of appetite during 24 hours; this data was evaluated according to the subjective scale given by the investigator. Each patient was given a superior digestive endoscopy, under general anesthesia, using the following protocol: Propofol 3 mg/kg intravenous (IV) and isoflurane 1 minimum alveolar concentration (MAC) for 100% of the patients (24). The endoscopic evaluation was done in a descriptive manner, according to the presence or absence of visual alterations in the gastric mucous such as edema, erythema, inflammation and hemorrhaging, assigning numeric values in case of presence or absence of symptoms, without knowledge of each patient's treatment. Five biopsies were performed on gastric mucous kept in formaldehyde at 10% (v/v) for histopathologic evaluation. The biopsies were evaluated in the pathologic laboratory in the Clinica Medellin (Poblado headquarters), Medellin, Colombia, where the presence or absence of alterations and the state of gastric mucous was described (polymorphonuclear presence, edema, erythrocytes and inflammatory changes). The evaluations were done on days 0 and 30.

Statistical analysis. Data was collected using Microsoft© Excel and analyzed using Statgraphics Centurion XV®, with a signification level of 5%. Multiple range tests was done, Tukey HSD and c2 for all the qualitative data. All data was subjected to ANOVA; additionally, significant statistical differences were determined between groups and protocols for each variable.

RESULTS

There were no differences between the two protocols with relation to age, sex or weight and there was no relation between these variables and osteoarticular pain.

Pain evaluation. Both treatment groups began medication on day 0 with moderate pain according to the University of Melbourne pain scale (UMPS). Ten days later, pain was reduced in both groups for slight pain and there between both groups (p≥0.05). By day 30, pain in both groups had diminished and all presented slight pain, with a significant difference between celecoxib and meloxicam (p≤0.05). Both drugs were effective to diminish pain (Figure 1). Evaluation of the analgesic showed that celecoxib presented a statistical difference between days 0 and 30 (p≤0.05) with a lessening of pain, from moderate to slight (Figure 1).

On the other hand, meloxicam did not show differences between treatment periods (p≥0.05). All patients had slight pain during the experiment.

Hematologic evaluation. The hemogram showed no difference between protocols and treatment days (p≥0.05). Mean cell hemoglobin (MCH) was different between protocols and treatment days, but the values were within normal range and distribution area for canines.

The leukogram showed no differences between celecoxib and meloxicam or between treatment days (p≥0.05).

Renal evaluation. No difference was found (p≥0.05) between treatments there were no adverse effects relating to renal function (Table 2).

Hepatic function evaluation. No alterations between protocols and treatment days were found. Only ALT and ALP showed differences (p≤0.05) between treatment days, but they are not indicative of damage, since they are considered normal for canines (Table 3).

Clotting evaluation. There was no difference in prothrombin time between protocols or treatment days (p≥0.05). Partial thromboplastin times showed a significant difference (p≤0.05) between patients treated with celecoxib and meloxicam between days 0 and 10. However, the results were within the normal range for canines (Table 4).

Digestive evaluation. Although the majority of clinical digestive symptoms occurred in similar proportions in both groups, in the celecoxib group diarrhea was the most common symptom (60%) while in the meloxicam group it was found in 33.33% (Table 5).

Clinical symptoms associated with digestive disorders were found in both treatment groups.

Macroscopic evaluation in digestive endoscopy and microscopic evaluation found compatible lesions with gastric irritation (inflammation, edema, congestion and/or erythema) in both groups at the end of the evaluation period, with a significant difference (p≤0.05) compared with day 0 (Table 6).

DISCUSSION

Thirty percent of patients were Labradors and this is related to the predisposition of the breed towards hip displacement and rear osteoarthritis (25). The authors feel that the frequency of the Labrador breed can be associated to its being one of the most common breeds in Medellin, making it seem that the disease is more common in them, and although literature describes this breed as one of the most predisposed, the present study does not determine the frequency of this problem in the zone of influence, and therefore it is only a possible hypothesis. The presence of the disease and clinical symptoms correspond to those found by other authors (12, 25, 26).

Hip arthrosis is more frequent in dogs over 5 years (1, 5, 12), coinciding with what was found in this study (7.33 years). There was no relation between sex, reproductive state, weight, and the clinical symptoms or the presence of disease, which has been related to physical condition. There was no relationship in this study that weight (28.8 kg) is related to incidence of the disease, as has been described by other authors (12), since there was no difference found between weight and the presence of the disease in this study; a possible explanation is family inheritance, which is hypothetical.

All the patients had a positive Ortolanni at the inclusion and had a level of 9.10 on day 0 on the UMPS scale, which indicates moderate pain, very common in OA. Pain diminished with both NSAIDS by the end of the treatment with the last UMPS level at 6 to 7 for celecoxib and 8 to 9 for meloxicam; these levels corresponded to slight pain. Both groups had decreased pain, which corresponds to the descriptions made by other authors for meloxicam and coxibs, and was expected (1, 2, 15). Celecoxib and meloxicam lessened pain according to UMPS values (4). Therefore, it was determined that both are good analgesics for the treatment of pain related to hip arthrosis in canines and coincides with that described for humans (27).

Evaluation of red blood cells in this study determined that none of the drugs caused any damage. Blood cell values were not altered, contrary to what has been previously described (20, 28). Continued use for 30 days did not affect this variable.

The white cell line variable was not modified in this study and differences found did not have clinical relevance to the health of the patients, since it was within the normal range for canines (29).

Measuring plasmatic levels of creatinine, urea, phosphorus, urinary density, aspect, color, sediment, cellularity, crystals, and proteins in urine showed no alteration; it is presumed that renal functionality was conserved, which is similar to data for other coxib, such as firocoxib, used for 90 days (18).

This study did not find a relationship between the use of these medicines for 30 days and an increase in creatinine, urea and changes in urinary density related to acute renal failure. This is similar to what has been found with other coxibs and meloxicam in dogs with arthrosis (18, 19, 30).

With meloxicam and celecoxib patients did not show modifications in the evaluation of hepatic variables, which was similar to results found by Luna and Steagall (15), but they do not coincide with reports of hepatotoxicity in dogs and human beings (7) or other hepatic-renal lesions described after their continued use (17) due to the 2C9/3A4 metabolism by cytochrome P450 that avoids bioaccumulation and toxicity. The results of levels of alkaline phosphatase and alanine aminotransferase were similar to other reports (30). Hepatic lesions reported in dogs are idiosyncratic and not toxic (3).

Prothrombin time and partial thromboplastin time were not different in this study due, perhaps, to the specificity and selectivity of the drugs for COX2 (3). Neither meloxicam nor celecoxib affected clotting times in canines compared with reports from other authors that found a COX1 inhibitor as an inhibiting factor of platelet aggregation or thrombotic action of celecoxib. The anticlotting effect of meloxicam was not found in this study, compared with reports from other authors.

Digestive evaluation in this study found that celecoxib and meloxicam produce lesions in the gastric structure from day 10, which is similar to the results found in other studies with humans and animals (6, 15). COX2 inhibition does not impede the drugs from causing chronic gastritis due to their pharmacologic characteristics, since they are acidic. Therefore it is necessary to use gastric protectors or chlorhidric acid antisecretory agents when they are used for extended periods (6).

The presence of diarrhea as a predominant clinical symptom in dogs using celecoxib is due to the damaging effects of NSAIDS on the digestive enzymes of intestinal mucous, described by some authors in rodents and canines. The decrease in the absorption capacity of the intestines (31) would produce osmotic type diarrhea symptoms due to decreasing the absorption capacity of water and salts.

In conclusion, celecoxib and meloxicam diminished osteoarticular pain in the short and long term, from day 10 to day 30 of the treatment. Analgesia was found from the first days of treatment and pain was reduced from moderate to slight, according to the UMPA. Greater decrease was found in the celecoxib group in comparison to meloxicam. None of the drugs evaluated during 30 days showed adverse effects in renal, hepatic, coagulation or hematologic function. Meloxicam and celecoxib cause acute gastritis.

Acknowledgements

To the School of Veterinary Medicine and Zootechnics at the Universidad CES for their sponsorship of this project, and to Caninos y Felinos© Clínica Veterinaria in Medellin, Colombia, for their logistic support.

Conflict of interest

The authors declare that no sponsorship from commercial laboratories was received. The idea came from personal interest in drug development and the search for new alternatives.


REFERENCES

1. Sanderson RO, Beata C, Flipo R-M, Genevois J-P, Macias C, Tacke S, et al. Systematic review of the management of canine osteoarthritis. Vet Rec. 2009;164:418-24.         [ Links ]

2. Innes FJ, Cayton J, Lascelles BDX. Review of the safety and efficacy of long-term NSAID use in the treatment of canine osteoarthritis. Vet Rec. 2010 Feb 20;166(1):226-30.         [ Links ]

3. Lizarraga Madrigal I, Sumano Lopez H, Castillo Alcala F. Cyclooxygenase-2 selective inhibitors: Potential usage in dogs. Vet Mex. 2002;33(3):2-24.         [ Links ]

4. Johnston S, M.McLaughlin R, Budsberg SC. Nonsurgical Management of Osteoar thritis in Dogs. Vet Clin Small Anim. 2008;38:1449-70.         [ Links ]

5. Aragon CL, Hofmeister EH, Budsberg S. Systematic review of clinical trials of treatments for osteoarthritis in dogs. JAVMA. 2007;230(4):514-21.         [ Links ]

6. Henderson AK, Webster CLR. Disruption of the Gastric Mucosal Barrier in Dogs [Internet]. CompendiumVet.com. 2006. Available from: http://cp.vetlearn.com/Media/PublicationsArticle/PV_28_05_340.pdf.         [ Links ]

7. Nakagawa K, Yamagami T, Takemura N. Hepatocellular toxicosis associated white the alternate administration of carprofen and meloxicam in a siberian husky. j.vet.med.sci. 2005;67(10):1051-3.         [ Links ]

8. Batlouni M. Antiinflamatorios No Esteroides: Efectos Cardiovasculares, Cerebrovasculares y Renales. Arq Bras Cardiol. 2010; 94(4):538-46.         [ Links ]

9. Autefage A, Palissier FM, Asimus E, Pepin-Richard C. Long-term efficacy and safety of firocoxib in the treatment of dogs with osteoarthritis. Vet Rec. 2011;168:617-23.         [ Links ]

10. Bergh MS, Budsberg S. The coxib NSAIDs: potential clinical and phamacologic importance in veterinary medicine. J Vet Intern Med. 2005;19(1):633-43.         [ Links ]

11. Choitsu SC, Soen S. Efficacy and Safety of the Selective Cyclooxygenase-2 Inhibitor Celecoxib in the Treatment of Rheumatoid Arthritis and Osteoarthritis in Japan. Digestion. 2011;83(1):108-23.         [ Links ]

12. Anderson A. Treatment of hip dysplasia. J Small Anim Pract. 2011;52:182-9.         [ Links ]

13. Michelin A de F, Ferreira Peres AA, Bitar Galvini B, Lopez Cruz L. Toxicidade renal de inhibidores selectivos da cicloxigenasa 2: celecoxib e rofecoxib. Rev Ciênc Méd Campinas. 2006;4(15):322-32.         [ Links ]

14. Vásquez-Cotés S, Vásquez-Fuertes L, Rodríguez-Alvárez M, Reig-Rincón de Arellano I, Martínez-Cócera C. Tolerancia a celecoxib y meloxicam en pacientes con intolerancia a analgésicos no esteroides. Med Interna. 2008;25(4):163-7.         [ Links ]

15. Luna S, Bastilio A, Steagall P. Evaluation of adverse effects of long-term oral administration of carprofen, etodolac, flunixin meglumine, ketoprofen and meloxicam in dogs. Am J Vet Res. 2007;68:258-64.         [ Links ]

16. Doig PA, Purbrick KA, Hare JE, McKeown DB. Clinical efficacy and tolerance of meloxicam in dogs with chronic osteoarthritis. Can Vet J. 2000;41(1):296-300.         [ Links ]

17. Tabibian J, Tabibian N, Kaufman D. Late-onset celecoxib induced combined hepato nephrotoxicity. Br J Clin Pharmacol. 2008;66(1):150-2.         [ Links ]

18. Joubert KE. The effects of firocoxib (previcox) in geriatric dogs over a period of 90 days. JSAfr.vetASS. 2009;60(3):179-84.         [ Links ]

19. Roberts ES, Van Lare KA, Marable BR, Salminen WF. Safety and tolerability of 3 week and 6 moths dosing of Deracoxib (Deramaxx) chewable tablets in dogs. Jvet Paharmacol Ther. 2008;32(329):337.         [ Links ]

20. Agustí A, Danés I. Modificación del efecto antiagregante de ácido acetil salicílico por los fármacos antiinflamatorios no esteroideos. Med Clin Barc. 2004;123(11):433-4.         [ Links ]

21. Goodman L, Gilman A, Hardman J, Limbird LE. Goodman & Gilman´s The Pharmacological basis of therapeutics. 12th ed. New York: McGraw Hill; 2006.         [ Links ]

22. Lanas Arbeloa Á. Avances en patología gastrointestinal relacionada con el tratamiento con antiinflamatorios no esteroideos y antiagregantes plaquetarios. Gastroenterol Hepatol. 2011;34(1):35-42.         [ Links ]

23. Firth AM, Haldane SL. Development of a scale to evaluate postoperative pain in dogs. JAVMA. 1999;214(5):651-9.         [ Links ]

24. Gómez LF, Hernánndez CA, Restrepo-Betancurt LF, Orozco S. Comparación de etomidato, ketamina y propofol como inductores para gastroduodenoscopia en perros. Rev Colomb Cienc Pecu. 2007;20(1):59-66.         [ Links ]

25. Oddone AJ, Rodríguez-Jurado PM. Enfermedades Congénictas y Hereditarias de las Razas Caninas y Felinas. Primera. Buenos Aires: Intermedica; 2010. 147 p.         [ Links ]

26. Hou Y, Wang Y, Lust G, Zhu L, Zhang Z, Todhunter RJ. Retrospective Analysis for Genetic Improvement of Hip Joints of Cohort Labrador Retrievers in the United States: 1970-2007. PLoS ONE. 2010;5(2):9410.         [ Links ]

27. Che Y-F, Jobanputra P, Barton P, Bryan, S, Harris, G, Taylor, RS, et al. Cyclooxygenase-2 selective non-steroidal anti-inflammatory drugs (etodolac, meloxicam, celecoxib, rofecoxib, etoricoxib, valdecoxib and lumiracoxib) for osteoarthritis and rheumatoid arthritis: a systematic review and economic evaluation. Health Technol Assess. 2008;12(1):25-32.         [ Links ]

28. Llau JV, De Andrés, J J, Gomar C, Gómez-Luque A, Hidalgo F, Sahagún J, et al. Fármacos que alteran la hemostasia y técnicas regionales anestésicas y analgésicas: recomendaciones de seguridad (foro de consenso). R E V Soc Esp Dolor. 2001;8(1):337-48.         [ Links ]

29. Campora C, Freeman KP, Lewis FI, Gibson G, Sacchini F, Sanchez-Vazquez MJ. Determination of haematological reference intervals in healthy adult greyhounds. JSAP. 2011 Jun;52(1):301-9.         [ Links ]

30. Steagall, P, Mantovani FB, Ferreira TH, Salcedo E, Mouthiño FQ, Luna LS. Evaluation of the adverse effects of oral firocoxib in healthy dogs. J Vet Pharmacol Ther. 2007; 30:2218-23.         [ Links ]

31. Chopra S, Kishore-Saini R, Nath-Sanyal S. Intestinal toxicity of non-steroideal anti-inflammatory drugs with differential cyclooxigenase inhibition selectivity. Nutr Hosp. 2007;22(5):528-37.         [ Links ]