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ssss1 Alternating current flows from the generator to the handpiece. Electrical current then flows from the electrode (handpiece) to the patient and then to the return electrode.

Source: From Taheri et al. [5].

ssss1 Electrode extensions are available in various tip configurations.

Source: From Huhn [3].

ssss1 Both J‐ and L‐shaped extensions are available for use with monopolar electrosurgery. Their extended lengths make them ideal for use in minimally invasive surgery. Also pictured is Valley Lab's TriVerse handpiece, which has a sliding switch to allow for adjustment of power delivery at the handpiece in addition to the generator.

Source: From Huhn [3].

Approximately 40 000 human patients sustain electrosurgical‐related injuries each year. Up to 70% of electrosurgical burns go undetected at the time of laparoscopic surgery, often because the active electrode is outside of the surgeons' field of view [8]. Three different types of coupling injuries can occur: direct coupling, indirect coupling, and capacitive coupling [4,9–11]. Direct coupling is the result of an electrically conductive object in close proximity to the target tissue. It occurs when the active electrode is activated before contact with the tissues resulting in energy transmission to the unwanted electrically conductive object, which can manifest as a burn (ssss1). Indirect coupling results from a discontinuity in the insulating coating of the active electrode. If this occurs, the current is drawn toward a neighboring electrically conductive object. Because of the lack of output on the target tissue, power settings are often increased, intensifying the misdirected current (ssss1). These insulation breaks are often small and not visible to the naked eye. These small breaks in insulation are dangerous because large current densities are concentrated at these small discontinuities in insulation. Capacitive coupling results from a build‐up of current between two conducting substances that are separated by an insulating substance. When the charge exceeds the insulating capacity, it can spark across the insulator to the other conducting substance, resulting in thermal injury. Capacitive coupling injuries occur most often with the use of “hybrid” cannula systems, or those that use both conductive (metal) and insulating (plastic) materials. All metal cannulas are less likely to result in this type of coupling injury because stray current is dispersed over a larger surface area. The extent of coupling injuries depends on the magnitude of the current applied.