Small Animal Laparoscopy and Thoracoscopy. Группа авторов

Small Animal Laparoscopy and Thoracoscopy - Группа авторов


Скачать книгу
surgical complication rates for laparoscopy and laparotomy vary. Initial reports suggested that surgical complications occurred with a lower frequency for laparoscopy, but as the complexity of procedures performed using this approach has increased, the complication rate is now more comparable [32, 33]. Complication rates and surgical time, which can additionally contribute to morbidity, tend to decrease with surgeon experience [12].

      Surgical complications may be related specifically to the procedure, positioning for the procedure (discussed later), or be of a more general nature. Again, prior preparation will facilitate rapid treatment should this occur.

Photo depicts inadvertent splenic puncture.

      Source: Courtesy of Eric Monnet.

Photo depicts radiographic image showing inadvertent placement of insufflation gas into the bladder.

      Source: Courtesy of David Twedt.

      Other causes of surgical complications are related to the unique equipment used for intervention. Just as it is important for the surgeon to have basal knowledge of anesthesia, it is important for the anesthetist to have at least a similar level of understanding of the surgical equipment used to facilitate laparoscopy. Complications associated with puncture of organs/vessels with the Veress needle have already been discussed. Additional complications may arise from use (intentional or accidental) of high insufflation pressures, intra‐abdominal use of cautery (especially if a potentially flammable gas is used), heat from the light source and cable, etc.

      Hemodynamic Effects

      As insufflation pressures increase into the range of 10–15 mmHg, hepatic, renal, and mesenteric blood flows are decreased. In studies with pigs, intra‐abdominal pressures greater than 10 mmHg were associated with significant reductions in hepatic artery and splanchnic blood flow [53, 54]. In dogs intra‐abdominal pressures in the range of 16–20 mmHg decreased portal venous and mesenteric arterial flow [55, 56]. Impairment of blood flow in other vessels (e.g., celiac artery) and to the intestinal mucosa is also reported for both dogs and pigs in this similar pressure range [42, 54, 57]. Oliguria is reported with pressures in the 15–20 mmHg range and anuria may be seen when pressures exceed this ranges [42, 57, 58]. The decrease in renal blood flow leads to an increase in renin and aldosterone levels [59]. In dogs, renal blood flow and glomerular filtration were decreased by over 75% with intra‐abdominal pressures of 20 mmHg, and anuria was observed when abdominal pressures reached 40 mmHg [42, 58]. Similar findings were reported in pigs, where oliguria was observed with pressures over 15 mmHg [57]. Albeit uncommon, patients with chronic kidney disease may be at higher risk for acute kidney injury during laparoscopic surgery [60–62].

      Interestingly, in a single study in healthy cats, pneumoperitoneum up to an intra‐abdominal pressure of 16 mmHg with carbon dioxide as the insufflation gas did not significantly influence cardiovascular parameters, albeit ventilation seemed to be negatively impacted; regional blood flow was not evaluated [63]. While healthy cats did not show changes in measured parameters during peritoneal insufflation, it is important to remember that cardiovascular function may be further influenced by the patient's health status, positioning during anesthesia and surgery, duration of the procedure, and the type of insufflation gas.

Photo depicts dog prepared for laparoscopic intervention in Fowler position.
Скачать книгу