Understanding the Mechanical Forces on the Sacrum Can Help Optimize Flap-based Pilonidal Sinus Reconstruction.

Background: Pilonidal sinus can be treated with excision and flap reconstruction, but treatment is often complicated by wound dehiscence, infection, and recurrence. Understanding the mechanical forces on the sacrococcygeal area during posture change could help guide optimal flap choice. Methods: Sixteen volunteers underwent measurements of skin-stretching, pressure, and shear stress on the sacrum when sitting relative to standing. Skin-stretching was measured by drawing a 4 × 4 cm square on the sacrum and measuring the vertical, horizontal, and diagonal axes. Pressure and shear stress was measured at six sacral points with a device. The data analysis highlighted the potential of the superior gluteal artery perforator (SGAP) flap for dissipating mechanical forces. Ten pilonidal sinus cases treated with SGAP flaps were retrospectively reviewed for 6-month outcomes. Results: Sitting is associated with high stretching tension in the horizontal direction [estimated marginal mean (95% confidence intervals) = 17.3% (15.4%-22.6%)]. The lower sacrum experienced the highest pressure [106.6 (96.6-116.5) mm Hg] and shear stress [11.6 (9.7-13.5) N] during sitting. The transposed SGAP flap was deemed to be optimal for releasing the horizontal tension and providing sufficient subcutaneous tissue for ameliorating pressure/shear stress during sitting. It also has high blood flow and can therefore be used with large lesions. Moreover, its donor site is above the high-pressure/stress lower sacrum. Retrospective analysis showed that no patients experienced complications. Conclusions: Sitting is associated with high mechanical forces on the sacrococcygeal skin. The transposed SGAP flap may ameliorate these forces and thereby reduce the risk of complications of pilonidal sinus reconstruction for large defects.

Diagnostic performance of real-time tissue elastography in chronic hepatitis C patients with sustained virological response.

BACKGROUND AND AIMS: Real-time tissue elastography is a non-invasive method for measuring liver elasticity. However, there are no reports evaluating the value of real-time tissue elastography for liver fibrosis in hepatitis C virus-infected patients with sustained virological response. The aim of this study is to clarify the diagnostic performance of real-time tissue elastography in patients with sustained virological response. METHODS: In this prospective study, we enrolled 425 chronic hepatitis C patients who underwent liver biopsy: 118 patients with sustained virological response (45.8% women) and 307 patients with hepatitis C virus (51.1% women). The post-sustained virological response biopsy was performed 5.9 ± 1.8 years after the therapy. Liver fibrosis index measurements as assessed using real-time tissue elastography were performed on the same day of biopsy. RESULTS: The respective mean liver fibrosis index values for fibrosis stages F0, F1, F2, F3, and F4 were 2.82 ± 0.33, 2.90 ± 0.51, 3.06 ± 0.58, 3.65 ± 0.24, and 3.83 ± 0.65, respectively, in patients with sustained virological response. The diagnostic accuracies expressed as areas under the receiver operating characteristic curves in patients with sustained virological response were 0.776 for the diagnosis of significant fibrosis (≥F2), 0.885 for severe fibrosis (≥F3), and 0.860 for cirrhosis (F4), respectively. The optimum cut-off values liver fibrosis index were 3.14 for ≥F2, 3.24 for ≥F3, and 3.30 for F4 in patients with sustained virological response. CONCLUSION: Real-time tissue elastography is an acceptable method for predicting the severity of fibrosis in hepatitis C virus patients with sustained virological response.

Optic Canal Decompression with a Lateral Approach for Optic Nerve Injury Associated with Traumatic Optic Canal Fracture.

Optic canal fracture (OCF) is a traumatic injury that requires urgent intervention because it can induce optic nerve damage and visual impairment. Despite the severity of OCF, a standard treatment method has not been established. In this article, we report a case of OCF and traumatic optic nerve injury in which visual acuity was recovered by releasing the optic canal using an unconventional lateral approach. A 43-year-old man presented with right lateral ethmoid fracture, right orbit blowout fracture, and OCF. The visual acuity was "hand motion" before surgery. Decompression was performed 10 hours after injury by approaching the right optic canal laterally from a coronal incision in front of the right ear, cutting along the border of the sphenoid bone, and scraping away some of the sphenoid wing and zygomatic bone. Steroid pulse therapy was added. Eventually, the visual acuity improved to 0.2 and the intraocular pressure decreased to 16.0 mm Hg. Compared with conventional methods, this method associates with better safety because (1) it causes relatively little bleeding and cerebrospinal fluid leak; (2) once the sphenozygomatic suture is identified, the distance to the optic canal is relatively short; and (3) if the fracture point is on the outer optic canal, the fracture line can be observed directly. Steroid pulse therapy may also have contributed to the good visual outcome. This is the first report of a novel lateral approach to OCF that is safe, effective, and only requires plastic surgery skills.