Optimizing bipolar electrocoagulation for endoscopic hemostasis: assessment of factors influencing energy delivery and coagulation.

BACKGROUND Few data inform decisions on the optimal bipolar electrocoagulation (BPEC) technique. OBJECTIVES To assess how technical factors influence energy delivery and coagulation. DESIGN Prospective, randomized study in experimental models: meat, live pig mesenteric arteries. INTERVENTIONS Standard and prototype BPEC probes were applied at varying durations (2, 10, and 20 seconds), application forces (5, 75, and 150 g), and watt settings (10, 15, and 20 W). BPEC devices were applied to arteries with 40 g versus no additional force. MAIN OUTCOME MEASUREMENTS For the meat model: energy delivered, impedance, coagulation and cavitation depth, and coagulation surface area. For the mesenteric arteries: hemostasis. RESULTS The energy delivered increased with duration and force (P < .001) but not with the watt setting. Impedance rose rapidly at higher watt settings (>300 ohms within approximately 5 seconds at 20 W and approximately 10 seconds at 15 W), with a coincident drop in power. Coagulation depth and surface area correlated with energy delivered (r = 0.70-0.97). Only duration was associated with the coagulation depth (P < .001); cavitation (which occurred with a standard BPEC probe) plus coagulation depth was also associated with application force (P < .001). Hemostasis of the mesenteric arteries was achieved only with 40 g of force. LIMITATIONS The accuracy of these models in predicting clinical results is uncertain. CONCLUSIONS Increasing BPEC duration increased the energy delivered and the coagulation, whereas increasing the watt setting did not because of a rapid rise in impedance. Optimal BPEC technique included a lower watt setting (eg, 15 W), a longer duration (eg, approximately 10-12 seconds), and tamponade of the bleeding site.

[1]  W. Burnham,et al.  CONTROLLED TRIAL OF SMALL BIPOLAR PROBE IN BLEEDING PEPTIC ULCERS , 1986, The Lancet.

[2]  C. Tang,et al.  Randomized controlled trial comparing epinephrine injection plus heat probe coagulation versus epinephrine injection plus argon plasma coagulation for bleeding peptic ulcers. , 2003, Gastrointestinal endoscopy.

[3]  J. Gornbein,et al.  Clinical and economic outcomes of individuals with severe peptic ulcer hemorrhage and nonbleeding visible vessel: an analysis of two prospective clinical trials , 1998, American Journal of Gastroenterology.

[4]  D. Jensen,et al.  Experimental comparison of endoscopic yttrium-aluminum-garnet laser, electrosurgery, and heater probe for canine gut arterial coagulation. Importance of compression and avoidance of erosion. , 1987, Gastroenterology.

[5]  M. Skok,et al.  Argon plasma coagulation versus injection sclerotherapy in peptic ulcer hemorrhage--a prospective, controlled study. , 2004, Hepato-gastroenterology.

[6]  L. Laine Multipolar electrocoagulation in the treatment of active upper gastrointestinal tract hemorrhage. A prospective controlled trial. , 1987, The New England journal of medicine.

[7]  G. Guyatt,et al.  Endoscopic therapy for acute nonvariceal upper gastrointestinal hemorrhage: a meta-analysis. , 1992, Gastroenterology.

[8]  L. Laine,et al.  Determination of the optimal technique for bipolar electrocoagulation treatment. An experimental evaluation of the BICAP and Gold probes. , 1991, Gastroenterology.

[9]  B. Sigel,et al.  Physical factors in electrocoaptation of blood vessels. , 1967, Archives of surgery.

[10]  J. P. O'sullivan,et al.  Nature of the bleeding vessel in recurrently bleeding gastric ulcers. , 1986, Gastroenterology.

[11]  L. Laine Multipolar electrocoagulation in the treatment of peptic ulcers with nonbleeding visible vessels. A prospective, controlled trial. , 1989, Annals of internal medicine.

[12]  D L Morris,et al.  Does bipolar electrocoagulation time affect vessel weld strength? , 1991, Gut.