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Dioctophymatosis as cause of dyspnea in a dog/Dioctofimatose como causa de dispneia em cao.

Dioctophyme renale is a parasite of the nematode class with hematophagous habits (MONTEIRO et al., 2002) that can infect various species, for example dogs, cats, and humans (VENKATRAJAIAH et al., 2014). Dogs are considered abnormal definitive hosts and become infected after ingestion of infected paratenic hosts (KOMMERS et al., 1999). The parasite usually affects the right kidney. However, aberrant migrations in dogs have been reported to the abdominal cavity (VEROCAI et al., 2009), scrotum (REGALIN et al., 2016) and urethra (STAINKI et al., 2011), among others. Most often, the discovery of the parasite is incidental, as it rarely causes clinical signs (BUTTI et al., 2016). The aim of this paper is to report the aberrant migration of Dioctophyme renale (D. renale) within the thorax of a dog, causing intense dyspnea.

An approximately one-year-old male dog of no defined breed, weighing 22kg, was presented at the Veterinary Hospital with acute apathy, anorexia, and dyspnea. During pulmonary auscultation, the presence of discrete crackling was observed. Since the general physical examination did not present any major alterations, the animal was referred to the diagnostic imaging section for radiographic chest examination. Right lateral and ventrodorsal radiographs revealed presence of multiple circular structures with a cavity, with a radiopaque thick contour (nine millimeters). The latter measured approximately four centimeters in diameter (Figure 1A), on the caudal portion of the left cranial lobe on laterolateral projection and left caudal lobe, on ventrodorsal projection. A discrete bronchial pattern was reported in the caudal lobes. There was radiographic suspicion of pulmonary bullae.

Oxygen supportive therapy was instituted, and thoracic ultrasonography was performed with the intention of confirming the radiographic suspicion. Ultrasonography examination revealed the presence of tubular structures measuring approximately one centimeter in diameter (Figure 1B), with a hyperechoic interface and mild pleural effusion. Movement was observed in the right and left hemi thorax and in different intercostal spaces in the pleural cavity. Abdominal ultrasound evidenced reduced size of the right kidney in comparison to the left.

The right kidney also presented irregular contours and increased echogenicity in the cortical region. There were also multiple tubular structures of hyperechoic interface in the medulla and renal pelvis, suggesting the presence of nematode parasites. Ultrasound examination of the scrotum showed the presence of mobile circular structures; these images were compatible with the presence of nematode parasites. Thus, a diagnosis of multiple infestation of parasite in the right kidney, scrotum, and thoracic cavity was made. Urinalysis demonstrated the presence of microscopic hematuria with 40-50 red blood cells per high power field, without major alterations.

The animal was referred for the surgical procedures of orchiectomy and trans-sternal thoracotomy to remove the parasite(s). Prior to surgery, the patient received acepram (0.03mg x [kg.sup.-1] IM) and morphine (0.5mg x [kg.sup.-1] IM). General anesthesia was induced with propofol (2mg x [kg.sup.-1] IV) and maintained with isoflurane. Before the surgery, a thoracic drain was positioned and fixed by finger-trap suture in the eighth left intercostal space. Subsequently, a scalpel incision was made in the skin and musculature of the third sternebra till the xiphoid process. The thoracic cavity was evaluated and a free D. renale was reported, which was later identified as female with a size of 48 centimeters. Upon removal of the parasite and inspection of the cavity, the presence of moderate pleuritis was observed in the left ventral portion of the thoracic cavity. However, no pulmonary parenchymal lesion was observed, and no pulmonary bullae reported. Thoracic synthesis was then performed by means 0.8mm cerclage wire around each sternebra, 3-0 poly glycolic thread in sultan pattern on musculature, a zig-zag pattern with 3-0 poly glycolic thread in the subcutaneous tissue, and nylon 2-0 on the skin with a simple, interrupted pattern. Subsequently, due to the presence of the parasite in the scrotum, orchiectomy was performed through pre-scrotal median access. However, the parasite was not reported at the site and its migration to the abdominal cavity was suspected and synthesis performed. The removal of the abdominal parasites and kidney; however, was left to a future procedure.

The dog was hospitalized for three days to control post-surgical pain (morphine 0.5mg x [kg.sup.-1]SC, q12h; tramadol 2mg x [kg.sup.-1] and dipyrone 25mg x [kg.sup.-1] both SC, q8h; meloxicam 0.1mg x [kg.sup.-1]SC, q24h), antibiotic therapy (cefalotin 30mg x [kg.sup.-1]SC, q8h) and for thoracic drainage. No pneumothorax or postoperative pleural effusion were reported, so the chest drainage was removed two days postoperatively. The animal recovered well clinically, showing no evidence of dyspnea. After two weeks of the first surgical procedure, exploratory celiotomy and right nephrectomy were performed, without major complications. The anesthesia protocol was the same as used in the first surgery. In the same procedure, another free parasite was removed from the abdominal cavity, originated from the migration of D. renale previously located in the scrotum. The postoperative protocol was the same as the first surgery, except for morphine, which was not prescribed. After ten days, the dog was discharged from the hospital.

Although, dioctophymosis is generally an accidental diagnosis or necropsy finding (MEYER et al., 2013), some animals may show clinical signs of infestation. Signs of hematuria, anorexia, gait disturbance, emaciation, and apathy have been described previously (BUTTI et al., 2016); however, respiratory distress as a consequence of the presence of D. renale, has not been reported. In this case, the animal presented with the clinical manifestation of intense dyspnea secondary to the presence of a free parasite in the thoracic cavity and the consequent inflammation. According to FANTONI & MASTROCINQUE (2010), respiratory changes, included hypoventilation and hypoxia, and occurred in painful situations. The presence of a free parasite in the thoracic cavity could cause pain, explaining the dyspnea. Another hypothesis is that the clinical signs were secondary to the pleuritis, even though it was not marked on a naked-eye examination. Aberrant migration of D. renale into the thoracic cavity is particularly uncommon. Only one report was found in the extant literature describing a necropsy finding, but data on the clinical manifestations of the case were not detailed (MEYER et al., 2013).

Dioctophymatosis can be diagnosed through urinalysis. Although, urinalysis was performed, no significant changes were seen in the exam. The diagnosis can also be reached with the support of imaging tests, such as radiography, ultrasonography and, when available, computed tomography (RAHAL et al., 2014). SILVEIRA et al. (2015) emphasize that imaging studies are paramount for the early and definitive diagnosis of parasitism, especially in cases of erratic migration (RAHAL et al., 2014). In this case radiography raised suspicion of pulmonary bullae, a condition caused by alveolar rupture due to small airway obstruction (HAWKINS et al., 2008), characterized radiographically as a large cystic space with thin wall (up to two millimeters) in the lung parenchyma (TAVAKOLI & MEHRJERDI, 2010). In the present case, the radiographic findings included cystic areas, though the walls were thickened, to approximately nine millimeters. Furthermore, the condition is considered rare in dogs (TAVAKOLI & MEHRJERDI, 2010) and due to the unusual thickening of the wall of the structure, it was decided that a thoracic ultrasonography should be performed to confirm the suspicion as computed tomography was unavailable. The ultrasonographic examination provided diagnostic confirmation. The technique of thoracic ultrasonography has been explored in recent years to aid in the diagnosis of lung diseases (BABICSAK et al., 2011). Despite its limitations in evaluating lesions below gaseous collections, the technique allowed differentiation between pulmonary and pleural lesions, as well as peripheral pulmonary lesions (SARRAFF-LOPES & LARSSON, 2011).

In the present case, ultrasonography was able to differentiate the radiographic suspicion of bullae from infestation of the thoracic cavity by D. renale. Thus, it was possible to establish a specific and successful therapy for the case.

Currently, there is no option for nonsurgical, drug-based treatment for D. renale. Even if the parasite were to lose its viability, it would not be easily eliminated from the body, making surgery the only effective therapy (PEDRASSANI et al., 2009). To date, there is no other report of trans-sternal thoracotomy for removal of the parasite from the thoracic cavity. When available, thoracoscopy is a less invasive option and allows for more detailed exploration (LAKSITO et al., 2010). Although, thoracoscopy was not an option at the hospital where the procedure was performed, the exploratory thoracotomy allowed the appropriate treatment and inspection of the cavity. As described previously in the necropsy findings of MEYER et al (2013), intraoperative evidence of pleuritis was observed. However, no perforations were seen in the pleura, nor was there histopathological confirmation of such alteration.

With the present case report, the aberrant migration of the parasite Dioctophyme renale should be added to the list of differential diagnoses for patients with breathing difficulties in endemic areas. It should also be included as a differential diagnosis in cases suspected of pulmonary bullae. Finally, the thoracic cavity should be considered as a potential locale for the presence of this worm.


We authors of the article entitled "Dioctophymatosis as cause of dyspnea in a dog" declared, for all due purposes, the project that gave rise to the present data of the same has not been submitted for evaluation to the Ethics Committee of the Universidade Federal do Pampa (UNIPAMPA)", but we are aware of the content of the Brazilian resolutions of the National Council for Control of Animal Experimentation (CONCEA) <> if it involves animals.

Thus, the authors assume full responsibility for the presented data and are available for possible questions, should they be required by the competent authorities. 10.1590/0103-8478cr20180490

Received 06.19.18

Approved 11.20.18

Returned by the author 12.14.18



Authors wish to thank Ministerio da Educacao (MEC) for the scholarship provided to some of the authors.


The authors declare no conflict of interest. The founding sponsors had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, and in the decision to publish the results.


MLAM performed the surgical procedure and postoperative care. TS was responsible for the anesthetics procedures. CR and JPEP were responsible for the medical conduct in the first care. SWD and IRLM were responsible for imaging diagnosis. EMG and MLAM were responsible to writing the manuscript. All authors critically revised the manuscript and approved the final version.


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Maria Ligia de Arruda Mistieri (1) Susane Werle Dill (2) Carine Rampelotto (3) Etiele Maldonado Gomes (1) * (iD) Joao Paulo da Exaltacao Pascon (4) Thaline Segatto (5) Ingrid Rios Lima Machado (2)

(1) Departamento de Clinica Cirurgica de Pequenos Animais, Universidade Federal do Pampa (UNIPAMPA), CP 118, 97500-970, Uruguaiana, RS, Brasil. E-mail: * Corresponding author.

(2) Departamento de Diagnostico por Imagem, Universidade Federal do Pampa (UNIPAMPA), Uruguaiana, RS, Brasil.

(3) Departamento de Clinica Medica de Pequenos Animais, Universidade Federal de Santa Maria (UFSM), Santa Maria, RS, Brasil.

(4) Departamento de Clinica Medica de Pequenos Animais, Universidade Federal do Pampa (UNIPAMPA), Uruguaiana, RS, Brasil.

(5) Departamento de Anestesiologia Veterinaria, Universidade Federal do Pampa (UNIPAMPA), Uruguaiana, RS, Brasil.

Caption: Figure 1--A-Radiographic image of the thorax in a right lateral projection where it is possible to visualize the presence of multiple circular structures with thick edges and increased opacity (arrow) between intercostal spaces in the ventral thoracic region. B-Ultrasonography image using 7,5MHz linear transducer, on longitudinal plane, in the thoracic region identifying circular (yellow) formation in the 4th intercostal space. Source: HUVET-UNIPAMPA.
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Author:Mistieri, Maria Ligia de Arruda; Dill, Susane Werle; Rampelotto, Carine; Gomes, Etiele Maldonado; Pa
Publication:Ciencia Rural
Date:Jan 1, 2019
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