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Small Animal Laparoscopy and Thoracoscopy


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of Medtronic, Minneapolis, MN.

      Microwave ablation (MWA) uses electromagnetic methods to induce the destruction of tumors via thermal energy at frequencies ≥ 900 MHz [33]. A generator emits an electromagnetic wave through an antenna resulting in the application of heat to tissues. It has several advantages over radiofrequency ablation, including consistently higher intratumoral temperatures leading to larger ablation zones and shorter treatment times; it has an active heating mechanism that allows for more uniform tumor necrosis even in close proximity to large blood vessels; it can be effective in tissues with high impedance such as lung or charred, desiccated tissue; and multiple tumors can be treated simultaneously with an additional antenna [34, 35].

      The most common generators include EmprintTM (Medtronic, Boulder, CO) and NeuwaveTM (NeuWave Medical, Madison, WI). The Medtronic antennas come in three different shaft lengths, 15, 20, and 30 cm, but the radiating (green) section of the probe that becomes hot with use is 2.8 cm on all probes. The NeuWave probes vary in size from 13to17 gauge and lengths of 15, 20, and 25 cm. Power and time settings are recommended by the manufacturer depending on the tissue type, size of the lesion, and number of probes used.

      In people, MWA has been described via an open approach, percutaneously via image guidance and with laparoscopy and thoracoscopy. There is limited published information on MWA in veterinary medicine and even more limited information on its use with laparoscopy and thoracoscopy. Yang et al. [36] described the use of MWA with an open approach for the treatment of hepatic neoplasia in five dogs. More recently, Oramas et al. [37] described the feasibility of laparoscopic access to the liver lobes in cadaveric dogs and then detailed the use of MWA with laparoscopy in two clinical cases of hepatic neoplasia. Video‐assisted MWA of pulmonary metastasis has also been reported in a dog [38].

Photo depicts endoclips come in different shaft diameters and clip sizes. They apply C-shaped clips that close from the tip first. (a) Endoclip applicator. (b) The instrument provides instruments on number of clips left. (c) Tip of clip applier.

      Source: From Huhn [3].

Photo depicts endoscopic gastrointestinal anastomosis staplers have a 10-mm-diameter shaft that has three different length staplers with four different staple sizes. The largest staple leg length (5 mm, black) requires a 15-mm port because of the larger diameter of the stapler.

      Source: Image courtesy of Medtronic (Minneapolis, MN).

      A study comparing two Endo GIA 30 vascular staple cartridges in a porcine model found both the 2.0 and the 2.5mm staple height to be equivalent for hemostasis of large blood vessels (renal artery and vein, caudal vena cava, and aorta). Both achieved vessel sealing greater than 310 mmHg and were able to seal arteries up to 17 mm and veins up to 22 mm [39]. Lansdowne et al. [40] reported thoracoscopic lung lobectomy in nine dogs. They recommended using the 3.5mm staple height and longer staple cartridges because the 30mm length alone often was not long enough to span the hilus of the lung lobe. Imhoff and Monnet evaluated the Tri‐stapleTM technology in an ex vivo model for lung biopsy and found leakage at lower pressures when compared to standard staples with a nongraduated compression [41]. Despite these ex vivo results, the Tri‐stapleTM technology is commonly used during thoracoscopic lung lobectomy.

      Source: Adapted from Medtronic (Minneapolis, MN).

Tri‐StapleTM technology for ENDO GIA – laparoscopic and open procedures
Cartridge color Open staple height Closed staple height Tissue type
Grey 2, 2, 2 mm 0.75, 0.75, 0.75 mm Vascular
Tan 2, 2.5, 3 mm 0.75, 1, 1.25 mm Vascular/medium
Purple 3, 3.5, 4 mm 1.25, 1.5, 1.75 mm Medium/thick
Black (15 mm Port) 4, 4.5, 5 mm 1.75, 2, 2.25 mm Extra‐thick

      1 1 Dubiel, B., Shires, P.K., Korvick, D., and Chekan, E.G. (2010). Electromagnetic energy sources in surgery. Vet. Surg. 39 (8): 913.

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