Injectable Anesthesia With Medetomidine, Ketamine, and Butorphanol in Captive Humboldt Penguins (Spheniscus humboldti).

The effects of an injectable anesthesia with 0.05 mg/kg medetomidine, 5 mg/kg ketamine, and 0.5 mg/kg butorphanol administered together intramuscularly were evaluated in 22 captive Humboldt penguins (Spheniscus humboldti, 10 male and 12 female), with a mean age of 8.5 ± 8.23 years. The birds fasted for18-24 hours prior to the procedure. Induction was followed by 4 distinct progressive responses of the birds to the anesthetic effect, including onset of initial effects at 2.0 ± 1.7 minutes (x̄ ± SD), sternal recumbency with the head still elevated at 2.2 ± 1.6 minutes, lowering and placing the beak tip to the ground at 3.6 ± 3.4 minutes, and lateral positioning of the neck and head at 4.2 ± 3.4 minutes. A general state of sedation, muscle relaxation, and analgesia were noted 10.0 ± 2.8 minutes postinjection. However, according to an established scoring system for the assessment of anesthetic depth in avian patients, a surgical plane of anesthesia was not achieved. Muscle relaxation determined by the same scoring system lasted for 31.4 ± 17.1 minutes. The penguins' mean respiratory rate did not demonstrate significant change and spontaneous ventilation was present throughout the procedure. Relative peripheral arterial oxygen saturation decreased significantly from 92.83 ± 5.77% at 10 minutes to 90.91 ± 5.77% at 40 minutes following induction. The birds' heart rate also decreased significantly from 112.55 ± 23.97 beats/min at 10 minutes to 101.65 ± 25.42 beats/min at 40 minutes. The measured cloacal temperatures were maintained within normal range despite ambient temperatures of up to 28.3°C (82.9°F). Reversal of medetomidine with 0.25 mg/kg atipamezole was conducted after 45.1 ± 7.3 minutes. Recovery was smooth but of variable duration with patients being able or willing to stand steadily in an upright position after 50.1 ± 34.6 minutes. One penguin died during recovery from a ruptured left ventricle and consecutive pericardial tamponade, but no predisposing factors were identified. The anesthetic protocol proved to be effective for noninvasive and minor painful procedures (eg, diagnostic imaging, blood collection). Disadvantages to the administration of the combined anesthetic agents in the penguins included a short period of muscle relaxation and smooth but potentially prolonged recovery. The safety of the anesthetic protocol described for Humboldt penguins in this report has to be evaluated critically against the the death of 1 penguin during recovery.

Tracheal Resection in a Secretary Bird ( Sagittarius serpentarius) with Granulomatous, Foreign-body Induced Tracheitis.

A 24-year-old female secretary bird ( Sagittarius serpentarius) was presented with acute, mild dyspnea occurring only during feeding times. Despite initial conservative therapy consisting of antibiotics and antifungal, antiparasitic, and anti-inflammatory drugs, the dyspnea worsened progressively, resulting in severe respiratory distress. Radiographs of the trachea suggested stenosis in the caudal one-third of the trachea. Tracheal endoscopy revealed an obstruction of approximately 90% of the tracheal lumen, in addition to mild suspected aspergillosis of the air sacs. Tracheal resection and anastomosis were performed, during which 1.5 cm of abnormal trachea was removed. Histopathologic examination showed severe granulomatous tracheitis, most likely induced by foreign body material. Respiratory signs resolved immediately postoperatively. Antibiotic and anti-inflammatory therapy continued for another 7 days and the bird was treated with antifungals for a total of 45 days. The bird recovered uneventfully. We encourage tracheal resection and anastomosis for severe tracheal stenosis even in aged, large birds of prey that are managed in large aviaries.

Pseudomonas aeruginosa Infection in a Group of Captive Humboldt Penguins ( Spheniscus humboldti ).

Nine Humboldt penguins ( Spheniscus humboldti ), between 1 and 1.5 years old and kept at Zoo Dresden, developed local and systemic infections with various opportunistic pathogens within a period of 4 months. Affected birds died peracutely without preceding symptoms or showed various clinical signs, including separation from conspecifics, reduced food intake, lethargy, dyspnea, swelling of the salt glands, and ocular discharge. One bird showed central nervous signs, including seizures. Pathologic examination of deceased birds revealed severe necrotizing inflammation of the mucous membranes and deep structures of the glottis, trachea, nasal sinus, and conchae and granulomatous inflammation of the salt glands. Further findings were airsacculitis, pneumonia, hepatitis, conjunctivitis, and myositis. Pseudomonas aeruginosa was the predominant pathogen in 7 cases. Six penguins died or were euthanatized, whereas 3 penguins that received systemic antibiotic treatment with tobramycin (10 mg/kg IM q24h for 10 days) showed rapid clinical improvement. Insufficient turnover rate of the filtration system, biofilm formation on pipe surfaces, and other factors are assumed to have promoted pathogen buildup in the pool water and subsequent infection.

Broad tissue and cell tropism of avian bornavirus in parrots with proventricular dilatation disease.

Avian bornaviruses (ABV), representing a new genus within the family Bornaviridae, were recently discovered in parrots from North America and Israel with proventricular dilatation disease (PDD). We show here that closely related viruses are also present in captive European parrots of various species with PDD. The six ABV strains that we identified in clinically diseased birds are new members of the previously defined ABV genotypes 2 and 4. Viruses of both genotypes readily established persistent, noncytolytic infections in quail and chicken cell lines but did not grow in cultured mammalian cells in which classical Borna disease virus strains replicate very efficiently. ABV antigens were present in both the cytoplasm and nucleus of infected cells, suggesting nuclear replication of ABV. The genome organization of avian and mammalian bornaviruses is highly conserved except that ABV lacks a distinct control element in the 5' noncoding region of the bicistronic mRNA encoding the viral proteins X and P. Reverse transcription-PCR analysis demonstrated the presence of virus in many, if not all, organs of birds with PDD. Viral nucleic acid was also found in feces of diseased birds, suggesting virus transmission by the fecal-oronasal route. Immunohistochemical analysis of organs from birds with PDD revealed that infection with ABV is not restricted to cells of the nervous system. Thus, ABV exhibits a broad tissue and cell tropism that is strikingly different from classical Borna disease virus.