Colopexia laparoscópica com retalho de tela de polipropileno em cães Laparoscopic colopexy with polyprolyne mesh in dogs

Avaliou-se uma nova técnica de colopexia laparoscópica, sem necessidade de suturas intracorpóreas em cães, utilizando a implantação de segmento de tela de polipropileno em 11 animais. As superfícies serosas do cólon descendente e parede muscular foram mantidas em contato com o implante posicionado por meio de lesão produzida no mesocólon e sob o retalho bipediculado de músculo transverso abdominal. As extremidades da tela foram unidas com a aplicação de clipe de titânio. Os procedimentos duraram 36,00±13,15min, sem a ocorrência de complicações. No período pós-operatório, foi verificada a manutenção da colopexia em sete animais, a formação de fixação parcial entre o intestino e a parede em três cães, e a não formação de aderências do cólon em um paciente. Conclui-se que o procedimento proposto é viável para cães, porém necessita de ajustes técnicos.A new laparoscopic colopexy technique was tested in dogs without intracorporeal sutures. The use of polypropylene mesh in eleven mongrel dogs was evaluated. The serosal surface of the descendent colon and transverse abdominal muscle were put in contact with the mesh application, taking into consideration that the polypropylene implant was positioned through the mesocolon and under the muscle flap. Finally, the extremities of the mesh were clipped. The procedures lasted 36:00±13:15min, without any kind of complications. In the post-operative period, adequate colopexy in seven dogs was observed. In three dogs the colopexy was partial and in one the bowel did not adhere to the muscles or mesh. The proposed procedure is viable for dogs, however, it is necessary to make some adjustments

Intoxicação por enrofloxacina em um cão da raça Pinscher Miniatura: relato de caso Enrofloxacin poisoning in a Miniature Pinscher: a case report

Uma cadela da raça Pinscher Miniatura foi medicada pelo proprietário com enrofloxacina, na dose de 50mg/kg, uma vez ao dia, por dois dias (dose diária 10 vezes maior que a prescrita). Ao exame clínico o animal apresentou-se deprimido, em cifose lombar, hipotérmico, com mucosas pálidas, dispnéia, sialorréia, vômitos e anúria, evoluindo para parada respiratória, convulsões e coma. Foi realizado tratamento sintomático. O fluxo urinário retornou ao normal em 12 horas e as convulsões foram controladas, mas o animal permaneceu em coma, morrendo 72 horas após o início do tratamento. A necropsia e o histopatológico confirmaram insuficiência renal e hepática agudas, e choque hipovolêmico, compatível com intoxicação por enrofloxacina.A Miniature Pinscher bitch was treated by the owner with enrofloxacin at dose of 50 mg/kg, once a day, for two days (daily dose rate 10 times greater than prescribed). Physical examination showed depression, lumbar cifosis, hipotermia, pale mucosa, dispneia, drewling, vomiting and anuria, followed by respiratory failure, seizures, and coma. Symptomatic treatment was performed, and the urinary flow returned to normal in 12 hours, and seizures were controlled. However, the animal stayed in coma, and died 72 hours after the beginning of the treatment. Acute renal and hepatic failure, and hipovolemic shock, compatible with enrofloxacin intoxication, were observed through necropsia and histopatology

The role of auditory and vibration stimuli in zebrafish neurobehavioral models

Strongly affecting human and animal physiology, sounds and vibration are critical environmental factors whose complex role in behavioral and brain functions necessitates further clinical and experimental studies. Zebrafish are a promising model organism for neuroscience research, including probing the contribution of auditory and vibration stimuli to neurobehavioral processes. Here, we summarize mounting evidence on the role of sound and vibration in zebrafish behavior and brain function, and outline future directions of translational research in this field. With the growing environmental exposure to noise and vibration, we call for more active use of zebrafish models for probing neurobehavioral and bioenvironmental consequences of acute and long-term exposure to sounds and vibration in complex biological systems

The role of auditory and vibration stimuli in zebrafish neurobehavioral models

Strongly affecting human and animal physiology, sounds and vibration are critical environmental factors whose complex role in behavioral and brain functions necessitates further clinical and experimental studies. Zebrafish are a promising model organism for neuroscience research, including probing the contribution of auditory and vibration stimuli to neurobehavioral processes. Here, we summarize mounting evidence on the role of sound and vibration in zebrafish behavior and brain function, and outline future directions of translational research in this field. With the growing environmental exposure to noise and vibration, we call for more active use of zebrafish models for probing neurobehavioral and bioenvironmental consequences of acute and long-term exposure to sounds and vibration in complex biological systems