Novel Hemostatic Technique During Laparoscopic Liver Parenchymal Transection: Saline-Linked Electrocautery Combined With Wet Oxidized Cellulose (SLiC-WOC) Method.

INTRODUCTION: Although laparoscopic hepatectomy has the potential advantage of reducing intraoperative blood loss, it is more difficult to control bleeding laparoscopically compared to an open approach. We introduced a novel hemostatic technique, the saline-linked electrocautery combined with wet oxidized cellulose (SLiC-WOC) method, during laparoscopic hepatectomy where a combination of saline-linked electrocautery (SLiC) and wet oxidized cellulose (WOC) is used. This study aimed to investigate the feasibility of employing the SLiC-WOC method for laparoscopic hepatectomy. METHODS: Thirteen patients who underwent laparoscopic liver resection with the SLiC-WOC method between 2019 and 2020 were included in this study. The number of bleeding episodes in which the SLiC-WOC method was applied was counted, and the time required to achieve complete hemostasis was measured. RESULTS: Among the bleeding events that were difficult to achieve hemostasis by SLiC alone, 94% were safely and efficiently controlled. Additionally, 69% of hemostasis was achieved within 60 seconds and 91% within 120 seconds. Postoperatively, most patients experienced no complications and no operative mortality was observed. CONCLUSIONS: The SLiC-WOC method can provide safe and time-efficient hemostasis during laparoscopic hepatectomy. This is especially crucial for bleeding, which is difficult to control using electrocautery alone.

Modified Two-Surgeon Technique for Laparoscopic Liver Resection.

While minimizing intraoperative blood loss during liver resection is one of the most important tasks, it is more difficult to control the refractory bleeding during laparoscopic liver resection than with an open approach. We herein provide a modification of the two-surgeon technique that enables laparoscopic liver parenchymal transection to be performed as quickly and securely as open liver resection. To achieve proper "role sharing," the "transection mode" and the "hemostatic mode" are independent sets in place in this procedure, and these modes are switched rigidly according to the surgical field condition. By thoroughly sharing the roles, rapid laparoscopic liver parenchymal transection comparable to open liver resection can be accomplished. The present modified approach achieves satisfactory transection and hemostasis of the liver parenchyma and is also advantageous for teaching young surgeons and the entire surgical team.

Irrigation-coupled bipolar cautery unit: A practical, economical, and simple version.

Hemostasis is a fundamental principle of surgery for which electrocoagulation is universally used. Bipolar electrocautery has an advantage over monopolar electrocautery in terms of the precision of the extent of tissue coagulation and the lateral extent of thermal tissue injury. However, secondary to the thermal changes induced in the tissue due to electric current passage, there is charring of tissue, which adheres to the cautery tip. This, not only decreases its effectiveness, but also, by getting avulsed while removing the cautery tip from the surgical field, causes rebleeding and more trauma to the tissue. Irrigation of the surgical field during application of cautery reduces the charring effect, thereby improving the efficiency and efficacy. Irrigation-coupled electrocautery devices are available but are costly to acquire and maintain. We describe a simple and reliable version of an irrigation-coupled cautery device, which is of immense functional utility in our experience. It decreases the amount of charring of the tissue and its adherence to the bipolar forceps tips, thereby decreasing the frustrating loss of effectiveness and also increases the life of the bipolar forceps as cleaning needs to be less frequent. By virtue of its simplicity and cost-effectiveness, it can be used in almost all hospitals and situations.