Аннотация и ключевые слова
Аннотация (русский):
Дискоспондилит редко встречается у кошек. Мы описываем случай дискоспондилита у кошки на уровне L2-3. Представлены данные рентгенографии, компьютерной томографии, магнитно-резонансной томографии и гистологического исследования. Микробиологическое исследование крови и кости (из замыкательных пластин L2-3) не дали роста. Микробиологическое исследование мочи и спинномозговой жидкости не проводилось. Была выполнена корпэктомия, назначен амоксициллина клавуланат, в итоге пациент был успешно вылечен. Клинические признаки полностью исчезли, отдаленное наблюдение спустя год после хирургического лечения.

Ключевые слова:
дискоспондилит, рентгенография, компьютерная томография, магнитно-резонансная томография, кошка
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Abbreviation (Сокращения): CBC ― Complete Blood Count (общий анализ крови), CT ― computed tomography (компьютерная томография), MRI ― magnetic resonance imaging(магнитно-резонансная томография), STIR ― Short tau inversion recovery (последовательность инверсия-восстановление спинового эха)

 

Introduction

The case deals with inflammation of intervertebral discs associated with penetration of bacterial or fungal microflora. The condition affects intervertebral discs and vertebral endplates. The disease is well described in dogs [1], while there are just a few publications on discospondylitis in cats [2…6]. In dogs, the onset of the disease is associated with hematogenous spread of microbiota to intervertebral discs from various foci of bacterial inflammation, such as skin wounds or urinary tract infections [7], or migration of foreign bodies [8…10]. As well, brucellosis is believed to be an important driver of the development of disсospondylitis in dogs [11]. Cats get infected usually as a result of injuries, mainly bites, in most cases with concomitant meningomyelitis [2]. The case described deals with disсospondylitis in a cat associated with Streptococcus canis and Actinomyces viscosus [3]. In the work of Norsworthy GD 1979, bacterial growth was not obtained; two cats were diagnosed with E. coli [2]; also it describes a case of disсospondylitis presumably associated with Enterococcus sp. and Clostridium perfringens [5]. Clinical signs of disсospondylitis in cats do not differ from those described in dogs and include pain, restriction of movements, lameness, weight loss and anorexia, ataxia and paresis. In one case, a cat was diagnosed with concomitant pyelonephritis [6].

 

Signalment and History

The patient (a Maine Coon cat, male, aged 1 year 8 months, weight 8 kg) got to the veterinary hospital of the Innovation Veterinary Center of Moscow Veterinary Academy with manifestations of pain in the lumbar spine suffered for one month. The owners also mentioned an increased level of aggression, decreased appetite and activity. Bowel movement was absent for 2 days. The cat, vaccinated, fed with commercial cat foods, kept at home at all times and not let outside, did not have contacts with other pets, thus bites could be ruled out. A few days before admission to hospital, the cat was examined at a local clinic (the exact time of the visit not known) and prescribed prednisolone in the dose of 2 mg/kg. The treatment with prednisolone had no effect.

 

Physical Examination

While being examined, the cat showed pain in the lower back, responding aggressively to any sort of manipulations. The cat was able to move around without signs of ataxia or paresis. Palpation of the abdomen was difficult; no signs of pain in the abdominal organs were detected. Rectal temperature was within normal reference values (38.5 C/101.3 F); auscultation did not reveal any murmur in the lungs. Rotation of hip joints caused pronounced discomfort. Spinal reflexes: patellar reflex +1; cranial tibial reflex +1; flexor reflex (sciatic nerve) N; achilles tendon reflex +1; deep pain N. Postural reflexes: hopping N; proprioception N. The cat was sedated to perform diagnostic imaging, which was preceded by a repeated examination with a view to external wounds, abscesses, or inflammation of the oral cavity. No signs of external injuries were revealed.

 

Laboratory Findings

No deviations in CBC and biochemistry panel blood analyses were detected. Aerobic and anaerobic culture/sensitivity of fragments of an intervertebral disc and endplates was performed after diagnostic imaging.

 

Radiography

For radiography the cat was sedated. Radiography was performed in lateral and ventrodorsal projections (Fig. 1). Radiographically, irregular bone proliferation of endplates and spondylosis of L2-L3 was revealed. In the lateral projection, clear signs of lytic destruction were visible only in the ventral part of the L3 endplate. As well, in the lateral projection a clear evidence of spinal stenosis at the level of L2-L3. In the ventrodorsal projection, lytic destruction of endplates L2-L3 was visible (Fig. 1), the destruction being most pronounced on the left side. These radiographic findings were most consistent with spondylosis and discospondylitis. The decision to perform a surgery was made upon comparing the results of neurological examination and radiographic imaging. It was decided to perform a CT scan for more detailed visualization of the level of destruction, as well as to facilitate the planning of corpectomy.

 

Computed tomography

The 16-slice spiral computed tomography protocol (Siemens Somatom Emotion 16, Siemens HealthineersErlangen GE) was implemented with the following characteristics: 110kv, 100mA, slice thickness 0.75 mm, pinch 0.8, rotation time 0,6 s, collimation 0.6 cm. Bone window reconstruction with convolution kernel B60s, soft tissue window reconstruction with convolution kernel B30s, FOV 6 x 6 cm. Level of research Th10-S1. The CT images revealed bone hypertrophy, spondylosis, and irregular bone proliferation of endplates of L2-L3, as did the x-ray images (Fig 2). The quality of CT imaging was not much better than that obtained with radiographic method, which can be explained by the severity of pathological changes. As well, the CT scan revealed that the main site of the spinal canal stenosis was located on the right side and represented by a fragment of bone tissue, 2 mm in height. Myelography was not performed, intravenous contrast agent was not administered.

 

Magnetic resonance imaging

In order to assess the degree of compression of the spinal cord, magnetic resonance imaging (Fig 3, 4) was performed with an open type scanner (Hitachi Airis Mate, Hitachi Healthcare, Ltd, Tokio JA) with the magnetic field intensity of 0.2 T. The protocol included T2-weighted (repetition time 2500 ms, echo time 100, 3.0 ms), T2-myelo (repetition time 3000 ms and echo time 580, 3.0 ms), T1-weighted (repetition time 320 ms and echo time 100, 3.0 ms) and STIR (repetition time 2560 ms and echo time 40, 3.0 ms). Contrast agent was not administered. In the T1 mode, the endplates and the vertebral bodies emitted a hyperintensive signal; in the T2 mode, the signal was isointensive with hyperintensive inclusions in the projection of the intervertebral disc. In the T2 myelo mode a significant decrease of signal from the dorsal and the ventral cerebrospinal fluid columns was visualized. Additionally, the STIR mode was performed. In the STIR mode, the endplates and the vertebral bodies emitted a hyperintensive signal.

 

Pathologic Findings

In the fields of cortical bone, zones of inflammatory infiltration were detected. Inflammation represented by lymphocytes and plasma cells was revealed. Trabeculae of bone of different degrees of mineralization and pronounced signs of resorption were observed. Haematopoiesis appeared to be presented poorly; bone marrow cells were found to be situated in the fine-fibered edematous connective tissue. The hyaline cartilage was observed as present in a small amount manifesting no morphological changes. Sites with the bone tissue replaced by fibrous tissue of coarse fibrous structure, were detected. Based on these data, the pathologist diagnosed the patient with disсospondylitis (Fig. 5).

Culturing was performed only with respect to the material taken from the lesion in the spine; no bacterial growth was observed.

 

Treatment

The cat was subjected to corpectomy in order to provide decompression of the spinal cord as well as for the purposes of biopsy sampling (histological and bacteriological research). Despite the fact that no bacterial growth was observed, amoxicillin clavulanate was prescribed (Sinulox®; Pfizer Animal Health, Exton, PA) 20 mg/kg PO BID for six weeks pursuant to the recommendations of Sykes JE, Kapatkin AS 2014 [14], as well as on the basis of the statistical occurrence of bacteria in discospondylitis in dogs [1]. After the surgical operation, the patient was discharged from the hospital. No recommendations as to restriction of movement of the animal were given to the owners. The subsequent examination 4 days later revealed positive dynamics, no neurological deficit and a significantly lower level of aggression. The latest telephone conversation with the owners took place 8 months after the surgery. The owners reported high quality of life, high activity, and absence of pain.

 

Discussion

In this clinical case, we were not able to detect the exact causative agent; at the same time, treatment based on decompression of the spinal cord and empirical antibiotic therapy produced good results. In our opinion, one of the weak sides of the chosen treatment was the lack of use of fluoroquinolones because disсospondylitis in the cat could have been caused by E. coli. X-ray and CT findings were not different from those observed in dogs. In this case, CT scan was performed in order to facilitate surgical navigation, as well as for training purposes. The authors did not find any works with descriptions of MRI findings concerning disсospondylitis in cats. Another shortcoming of this work is the use of low-field MRI 0.2T.

Comparing the visual image of disсospondylitis in this cat (radiography, CT, MRI) with that described in dogs [12, 13], the authors did not detect any difference. The fact that the specimen contained lymphocytes and plasmocytes, as well as the absence of histologic signs of bacterial and fungal growth in the tissues of the intervertebral disc, endplates and blood, suggest that this case of disсospondylitis was caused by sterile lymphocytic/plasmocytic inflammation. We believe that the outlook in cats suffering from disсospondylitis is significantly better than in dogs; however, in order to state it as a fact we need to perform more observations. Since cases of disсospondylitis are rare in cats, the authors believe that each case of the disease should be described.

 

List of author contributions

Category 1

(a)               Conception and Design: Kemelman Evgeniy, Koreshkov Artem

(b)               Acquisition of Data: Kemelman Evgeniy, Koreshkov Artem

(c)               Analysis and Interpretation of Data: Kemelman Evgeniy, Koreshkov Artem

 

Category 2

(a)               Drafting the Article: Kemelman Evgeniy, Koreshkov Artem

(b)               Revising Article for Intellectual Content: Kemelman Evgeniy, Maxim Lapshin, Koreshkov Artem

 

Category 3

(a)               Final Approval of the Completed Article: Kemelman Evgeniy, Koreshkov Artem, Yuliya Uvarova

 

Credits

The authors would like to thank Lapshin Maxim (IVC MVA), Natalia Mitrokhina (Veterinary center of pathomorphology and laboratory diagnostics Dr. N.V. Mitrokhinoi, 3, Natashi Kovshovoi str., Moscow, RF, 119361) for the description of the histological study that she performed.

 

Conflict of interest

The team of authors did not receive any sponsor aid from manufacturers or suppliers of equipment and consumables used in this work.

 

Ethical issues and plagiarism

This study was conducted in accordance with the legislation of the Russian Federation and the internal Charter of the Academy and the Clinic. The owner was warned that the data obtained in the process of diagnosing and treatment of the animal would be used for publication in a scientific journal. The owner did not sign any document concerning processing of personal data, therefore we do not specify the name and the address of the owner, as well as the name of the animal. The owner was repeatedly informed about the aforementioned conditions before the article was sent to the editor of the journal. The owner further sent an e-mail, in which he once again confirmed his consent to the publication of the clinical case. Having studied the norms of international law, the author sees no violations thereof.

In its structure, the article appears to resemble other similar articles indicated in the list of references, however, we provide a description of a separate clinical case.

 

Fig. 1. Lateral and ventrodorsal radiography of the spinal column at the level of L2-L3. Note the irregular margins and lytic appearance of the caudal endplate of L2 and cranial endplate of L3, characteristic of disсospondylitis

 

Fig. 2. CT scan of the lumbar spine at the level of L2-3. Bone window. The most pronounced area of lytic destruction of endplates is visible on the left side (arrowhead). A slight narrowing of the spinal canal is visible on right side (arrow)

 

Fig. 3. Sagittal projections in T1, T2 and T2-myelo modes. In the T1 mode, a hyperintensive area in the endplate and the L3 vertebral body can be seen very well

 

Fig. 4. Sagittal projections in the T2-myelo mode: a hypointensive contour of the spinal cord at the level of L2-3 can be visualized, which is an evidence of its compression

 

Fig. 5. Photo of the specimen taken from the disсospondylitis-affected area. Hematoxylin and eosin stainx 400

 

Список литературы

1. Burkert B.A., Kerwin S.C., Hosgood G.L., Pechman R.D., Fontenelle J.P. Signalment and clinical features of discospondylitis in dogs: 513 cases (1980‒2001), J Am Vet Med Assoc, 2005, No. 227, pp. 268‒275.

2. Aroch I., Shamir M., Harmelin A., Lumbar discospondylitis and meningomyelitis caused by E. coli in a cat, Feline Pract., 1999, No. 27, pp. 20‒22

3. Malik R.M., Latler M., Love D.N., Bacterial discospondylitis in a cat, J. Small Anim. Pract., 1990, No. 31: pp. 404‒406.

4. Norsworthy G.D., Discospondylitis as a cause of posterior paresis, Feline Pract., 1979, No. 9, pp. 39‒40.

5. Packer R.A., Coates J.R., Cook C.R., Lattimer J.C., O'Brien D.P., Sublumbar abscess and discospondylitis in a cat, Vet Radiol and Ultrasound, 2005, No. 46, pp. 396‒399.

6. Watson E., Roberts R.E., Discospondylitis in a cat, Vet Radiol., 1993, No. 34, pp. 397‒398.

7. Thomas V.B., Diskospondylitis and other vertebral infections, Vet Clinics of N Am: Small Animal Practice, 2000, No. 30(1), pp. 169‒181.

8. Brennan K.E., Ihrke P.J., Grass awn migration in dogs and cats: a retrospective study of 182 cases, J Am Vet Med Assoc, 1983, No. 182, pp. 1201‒1204.

9. Johnston D.E., Summers B.A., Osteomyelitis of the lumbar vertebrae in dogs caused by grass seed foreign bodies, Australian Veterinary Journal, 1971, No. 47, pp. 289‒294.

10. LeCouter R.A., Child G., Diseases of the spinal cord, In: Ettinger, ed. Textbook of veterinary internal medicine, Philadelphia: WB Saunders, 1989; pp. 650‒654.

11. Kerwin S.C., Lewis D.D., Hribernik T.N., Partington B, Hosgood G, Eilts BE. Diskospondylitis associated with Brucella canis infection in dogs: 14 cases (1989–1991), J Am Vet Med Assoc, 1992, No. 201, pp. 1253–1257.

12. Gendron K., Doherr M.G., Gavin P., Lang J. MRI characterization of vertebral endplate changes in a dog, Vet Radiol and Ultrasound, 2012, No. 53, pp. 50‒56.

13. Harris J.M., Chen A.V., Tucker R.L., Mattoon J. S. Clinical features and MRI characteristics of diskospondylitis in dogs: 23 cases (1997‒2010), J Am Vet Med Assoc, 2013, No. 242, pp. 359‒365.

14. Sykes J.E., Kapatkin A.S., Osteomyelitis, Discospondylitis, and Infectious Arthritis, In: Sykes J,E. Canine and feline infectious diseases, St. Louis, Missouri, 2014, pp. 814‒829.

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