BACKGROUND AND PURPOSE: Interstitial laser coagulation (ILC) is a well-established treatment option for patients suffering from benign prostatic hyperplasia (BPH). The vulnerability of the current fibers adds to the high cost of the procedure. The objective was to study the impact of different time-power modes and novel probe designs on tissue effects and fiber durability. MATERIALS AND METHODS: Standardized interstitial laser (Nd:YAG) applications utilizing different fiber types and power settings were performed in vitro on fresh bovine liver in a fluid medium. The resulting effects on tissue coagulation were evaluated. Additionally, the durability of contemporary probes as well as novel designs was examined. RESULTS: High-intensity application protocols of 1750 J within 60 seconds were significantly (p < 0.001) more effective in coagulating tissue (4.22 cm3) than the 90 seconds (3.68 cm3) and 120 seconds (3.06 cm3) time-power modes but significantly (p < 0.001) decreased the durability of fibers. Prototype probes significantly improved durability (p < 0.001), whereas efficacy remained unchanged (p > 0.5). CONCLUSIONS: Using a laboratory model, we could demonstrate that high-intensity time-power settings are more effective in creating tissue coagulation in ILC. The resulting deterioration of the probes can be reduced by applying new fiber designs.
BACKGROUND AND PURPOSE: Interstitial laser coagulation (ILC) is a well-established treatment option for patients suffering from benign prostatic hyperplasia (BPH). The vulnerability of the current fibers adds to the high cost of the procedure. The objective was to study the impact of different time-power modes and novel probe designs on tissue effects and fiber durability. MATERIALS AND METHODS: Standardized interstitial laser (Nd:YAG) applications utilizing different fiber types and power settings were performed in vitro on fresh bovine liver in a fluid medium. The resulting effects on tissue coagulation were evaluated. Additionally, the durability of contemporary probes as well as novel designs was examined. RESULTS: High-intensity application protocols of 1750 J within 60 seconds were significantly (p < 0.001) more effective in coagulating tissue (4.22 cm3) than the 90 seconds (3.68 cm3) and 120 seconds (3.06 cm3) time-power modes but significantly (p < 0.001) decreased the durability of fibers. Prototype probes significantly improved durability (p < 0.001), whereas efficacy remained unchanged (p > 0.5). CONCLUSIONS: Using a laboratory model, we could demonstrate that high-intensity time-power settings are more effective in creating tissue coagulation in ILC. The resulting deterioration of the probes can be reduced by applying new fiber designs.