Intraocular pressure change during laparoscopic sacral colpopexy in patients with normal tension glaucoma.

INTRODUCTION AND HYPOTHESIS: The steep Trendelenburg position, high pneumoperitoneum pressure, and longer surgical time may lead to significantly increased intraocular pressure (IOP), which could result in unexpected eye disease complications, including perioperative visual loss (POVL). We monitored IOP to induce early laparoscopic sacral colpopexy (LSC) safely. METHODS: This prospective study enrolled 39 patients with pelvic organ prolapse (POP), including 10 with eye diseases (6 with normal tension glaucoma and 4 with a narrow anterior chamber and normal range IOP). Enrolled patients underwent LSC under the same surgical settings involving a pneumoperitoneum of 10 mmHg and a Trendelenburg position of 15°. We measured IOP at seven time points during surgery and estimated IOP changes with time in patients with or without eye diseases. RESULTS: All patients, with or without eye diseases, experienced significantly elevated IOP during LSC. There were no significant differences between these groups. The average maximal IOP reached 20 mmHg at the end of surgery, and recovered to baseline values with the patient in the supine position at the end of anesthesia. No patient had an IOP of >40 mmHg as a critical threshold during surgery, and no substantial clinical eye symptoms were seen after LSC. CONCLUSIONS: Laparoscopic sacral colpopexy using an pneumoperitoneum of 10 mmHg and a Trendelenburg position of 15° during a 3-h surgical period could be performed within a safe range of IOP.

Effect of Intraocular Lens Power Calculation Formula Optimization in the Sum-of-Segments Optical Biometer.

Purpose: We evaluated the effect of optimization of the intraocular lens (IOL) power calculation formula SRK/T and Barrett Universal II (BU II) in long eyes (≥26 mm: group L) and short eyes (≤22 mm: group S) using axial length calculated from segmented refractive indices (SRI). Setting: Multicenter study at five sites in Japan. Design: Retrospective observational study. Methods: This study included 461 eyes of 461 patients (mean age 73.8 ± 8.4 years) who underwent cataract surgery. The predicted refractive error (PRE) was compared between the SRI (ARGOS) and the equivalent refractive index (ERI) biometers (IOLMasterTM700). The patients were randomly divided into two groups, a learning group and a validation group. The optimization constants were determined in the learning group, and the optimization constants were subsequently applied to the validation group and compared with the ERI biometer results. Results: Using both SRK/T and BU II, the validation group's PRE using optimization constants for the SRI biometer in group L was significantly smaller than that using the ERI biometer (p<0.001, p<0.01). In group L, the arithmetic PRE of Barrett UII formula with SRI showed a significant improvement after optimization compared to before optimization (p<0.0001). In group S, the arithmetic PRE of SRK/T and Barrett UII formula with SRI showed a significant improvement (p<0.0001, p<0.0001). Conclusion: In long and short eyes, the current study revealed that optimization of the SRK/T and Barrett formula constants for the SRI biometer was beneficial to achieve accurate refractive outcomes after cataract surgery.