Figure 6.9 Coaxial instruments used through single‐port devices can obviate some of the disadvantages encountered when the ability to triangulate is compromised.
Source: Courtesy of J. Brad Case.
Figure 6.10 A right‐angle adaptor placed onto the connection between the light cable and telescope can reduce interference between the light cable and instruments during single‐port surgery.
Optics
With the close proximity of the telescopes and instruments in single‐port surgery, adjustments are required to create space both internally and externally to avoid instrument and optic interference. The easiest way to avoid optics and instrument clashing during the procedure is the use of an angled telescope. The most common telescope used for single‐port laparoscopy in veterinary medicine is a telescope with a 30° angle. To further reduce the external clashing of instruments with the light cable, a right‐angle adaptor for the light cable can be used (Figure 6.10). Recently, the development of advanced laparoscopes geared specifically for single‐port surgery has emerged. A variety of deflectable telescopes with different mechanical design properties have recently been shown to be effective. One design involves a traditional fixed‐rod design that contains a rotating lens at the distal end (EndoCAMeleon, Karl Storz Endoscopy), or alternatively a design that uses the “chip on the tip” concept by placing an image processor at the distal tip of an articulating laparoscope (EndoEye, Olympus; Idealeye Stryker, Kalamazoo, MI) [72]. During veterinary single‐port surgery, it has been shown that using either a 30° telescope or an advanced deflecting optic enables the telescope's camera head and tip to be directed away from the other instruments during the procedure, improving working space while simultaneously maintaining excellent visualization.
Conclusion
The single‐port platform is a recent innovation in minimally invasive surgery. This platform may represent the next step forward in minimally invasive techniques. Early reports in the veterinary literature have shown this access method as a feasible and potentially more attractive approach for many common veterinary procedures. The focus of all new surgical techniques should be feasibility, safety, and efficacy, and they should provide a clinical advantage over other existing methods. Further studies are needed to determine if this platform for surgery can be considered a comparable alternative to multiport laparoscopy. Continually pursuing these types of research initiatives will help to drive emerging minimally invasive techniques and technology that ultimately benefits both human and veterinary patients alike.
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