Optimizing Excitation Light for Accurate Rapid Bacterial Species Identification with Autofluorescence.

Rapid identification of bacterial species in patient samples is essential for the treatment of infectious diseases and the economics of health care. In this study, we investigated an algorithm to improve the accuracy of bacterial species identification with fluorescence spectroscopy based on autofluorescence from bacteria, and excitation wavelengths suitable for identification. The diagnostic accuracy of each algorithm for ten bacterial species was verified in a machine learning classifier algorithm. The three machine learning algorithms with the highest diagnostic accuracy, extra tree (ET), logistic regression (LR), and multilayer perceptron (MLP), were used to determine the number and wavelength of excitation wavelengths suitable for the diagnosis of bacterial species. The key excitation wavelengths for the diagnosis of bacterial species were 280 nm, 300 nm, 380 nm, and 480 nm, with 280 nm being the most important. The median diagnostic accuracy was equivalent to that of 200 excitation wavelengths when two excitation wavelengths were used for ET and LR, and three excitation wavelengths for MLP. These results demonstrate that there is an optimum wavelength range of excitation wavelengths required for spectroscopic measurement of bacterial autofluorescence for bacterial species identification, and that measurement of only a few wavelengths in this range is sufficient to achieve sufficient accuracy for diagnosis of bacterial species.

Use of Microscope-Integrated Near-Infrared Fluorescence for Enhancing Deep Lymphatic Vessel Detection during Supermicrosurgical Lymphaticovenous Anastomosis: A Longitudinal Cohort Study.

BACKGROUND: The default setting of microscope-integrated near-infrared fluorescence (MINIRF) using indocyanine green for locating superficial lymphatic vessels during lymphaticovenous anastomosis was limited to less than or equal to 70 percent intensity. The authors investigated whether maximizing the MINIRF intensity setting could increase the number of deep lymphatic vessels being found, thereby increasing the total number of lymphatic vessels for lymphaticovenous anastomosis. METHODS: This longitudinal cohort study enrolled 94 patients (86 female and eight male patients) with lower limb lymphedema. Superficial lymphatic vessels were identified with the MINIRF default setting, before maximal intensity was used for deep lymphatic vessel detection. Primary/secondary endpoints included the number of superficial and deep lymphatic vessels identified. No control was used. Demographic data, intraoperative findings [including superficial and deep (indocyanine green-enhanced and non-indocyanine green-enhanced) lymphatic vessels], and severity of lymphosclerosis were recorded. Data in three regions of the lower limb (i.e., foot/above ankle, below knee, and thigh) were compared. RESULTS: A total of 481 lymphatic vessels were identified, comprising 260 superficial and 221 deep lymphatic vessels. The median number of lymphatic vessels found per patient was five (interquartile range, four to six), and the median lymphatic vessel size was 0.63 mm (interquartile range, 0.5 to 0.8 mm). No difference was found in number (p = 0.360), size (p = 0.215), or severity of lymphosclerosis (p = 0.226) between the overall superficial and deep lymphatic vessels in the three lower limb regions. CONCLUSIONS: Deep lymphatic vessel detection can be aided by maximizing MINIRF intensity. These deep lymphatic vessels are comparable to superficial lymphatic vessels in number, size, and functionality, making them potentially valuable for lymphedema improvement. CLINICAL QUESTION/LEVEL OF EVIDENCE: Diagnostic, II.

Microsurgical Lymphovenous Anastomosis for Pelvic Lymphoceles after Gynecological Cancer Surgery.

BACKGROUND: Pelvic lymphoceles are the most common complications after pelvic lymphadenectomy. Microsurgical procedures have attracted attention as an alternative treatment for lymphoceles. Here, we report six cases of refractory lymphoceles that were successfully treated using lymphovenous anastomosis (LVA). METHODS: Six patients underwent surgery for gynecological cancers and developed pelvic lymphoceles, which did not respond to conventional treatment. We mainly performed LVA on the ipsilateral lower limbs, although some procedures were also performed on the contralateral limbs. The change in the lymphocele volume after LVA was examined using computed tomography and compared using the Wilcoxon test. RESULTS: Five of the six refractory lymphocele cases were successfully treated using LVA, and the remaining case exhibited an 87% reduction in lymphocele volume. The average numbers of anastomoses were 6.7 on the ipsilateral side and 2.8 on the contralateral side (the median numbers: 6 [range: 5-9] vs. 3 [range: 1-4], P = 0.034). The average lymphocele volume decreased significantly from 414.0 mL preoperatively to 8.0 mL postoperatively (the median lymphocele volume: 255.8 [range: 61.5-1,329.2] vs. 0 [range: 0-47.7], P = 0.0313). CONCLUSION: We found that microsurgical treatment was potentially effective for lymphoceles that did not respond to conventional treatment.

Secondary Vulvar Reconstruction Using Bilateral Gluteal Fold Flaps after Radical Vulvectomy with Direct Closure.

Although primary vulvovaginal reconstruction after vulvectomy has high potential to improve patients' outcomes, flap reconstruction is not an established part of the current standard treatment for vulvar cancer. We report a patient with successful secondary vulvar reconstruction 3 years after radical vulvectomy with direct wound closure. A 69-year-old woman presented with chronic, burning vulvar pain 3 years after radical vulvectomy without reconstruction for stage IB vulvar cancer. Her urethral orifice had everted because of the direct wound closure, which resulted in severe pain on contact. We performed secondary vulvar reconstruction using bilateral 14 × 5 cm2 gluteal fold flaps. Postoperative pain management and overall aesthetic outcomes were satisfactory. Secondary vulvar reconstruction with gluteal fold flaps can avoid the sequelae resulting from inadequate direct wound closure after radical vulvectomy. Thus, we strongly advocate immediate vulvar reconstruction to prevent such situations.

Establishing a Lymphatic Venous Anastomotic Training Model in Pig Trotters.

BACKGROUND: Lymphatic venous anastomosis (LVA) is a widely accepted surgical procedure for lymphedema. To obtain the best outcomes, surgeons should be well trained. A recent study introduced an LVA training model using pig trotters for their utility and structural similarity to human tissues. However, details regarding the utilization of anastomosis models, such as feasible points for training based on vessel anatomy, have not been clarified. Therefore, we assessed the anatomical details of lymphatic vessels and veins of trotters to establish a practical training model of LVA. METHODS: Ten frozen trotters were used. After thawing at room temperature, indocyanine green fluorescent lymphography was used to visualize the lymphatic course. To dissect the lymphatic vessels and veins from the distal to the proximal end, whole skins were detached thoroughly from the plantar side. Data from the lymphatic vessels and veins were collected based on their courses, diameters, and layouts to clarify adjacent points feasible for LVA training. RESULTS: Both lymphatic vessels and veins were classified into four major courses: dorsal, medial, lateral, and plantar. The majority were dorsal vessels, both lymphatic vessels and veins. The adjacent points were always found in the distal dorsum center and were especially concentrated between the metacarpophalangeal (MP) joint and central interphalangeal crease, followed by the medial and lateral sides. CONCLUSION: The most relevant point for LVA surgical training in the trotter was the dorsal center distal to the MP joint, where parallel vessels of similar sizes were found in all cases. This practical LVA surgical model would improve surgeon skills in not only anastomosis but also preoperative fluorescent lymphography.

Determining factors in relation to lymphovascular characteristics and anastomotic configuration in supermicrosurgical lymphaticovenous anastomosis - A retrospective cohort study.

INTRODUCTION: Supermicrosurgical lymphaticovenous anastomosis (LVA) can be performed in different configuration such as end-to-end (LVEEA), end-to-side (LVESA), and side-to-end (LVSEA). Each configuration has its own advantages and disadvantages. However, it has remained ambiguous as to which anastomotic o configuration to choose. The aim of this study is to analyze and compare the relative sizes of lymphatic vessel (LV) and recipient vein (RV), in attempts to provide the basis for proper selections of the anastomotic configuration. METHODS: From March 2016 to October 2018, 100 lymphedema patients with 103 lymphedematous lower limbs (stage I-III) were included. All patients underwent supermicrosurgical LVA. Demographic data and intraoperative findings, including the number and size of the LV/RV, the size discrepancies, and the numbers of LVA performed were recorded. The severity of LVs were classified based on the lymphosclerosis classification (s0, s1, s2, and s3). One-way ANOVA test and post hoc analysis with Bonferroni's correction were performed for size discrepancy analysis. RESULTS: A total 730 LVA were performed with 621 LVs and 468 RVs, averaging 7.1 LVA per limb. Of these, 367 (50.3%) were LVEEA, 333 (45.6%) were LVESA, and 30 (4.1%) were LVSEA. The average LV and RV size was 0.61 ± 0.35 mm and 0.87 ± 0.43 mm, respectively (p < 0.001). The average LV size in different configuration: LVEEA = LVESA < LVSEA (p < 0.001); The average RV size: LVEEA = LVSEA < LVESA (p < 0.001); The size discrepancy: LVESA > LVSEA > LVEEA (p < 0.001).The LVSEA group has more s1 lymphatic vessels as opposed to LVEEA and LVESA (p = 0.004). CONCLUSION: The size and the comparative discrepancy between the LVs and RVs are the determining factors for proper anastomotic configuration selection during LVA. LVESA was more frequently performed when vessel size discrepancy was larger. The efficacy of each anastomotic configuration has yet to be determined.

Accuracy analysis of computer-assisted surgery for femoral trochanteric fracture using a fluoroscopic navigation system: Stryker ADAPT® system.

PURPOSE: ADAPT is a fluoroscopic computer-assisted surgery system which intraoperatively shows the distance from the tip of the screw to the surface of the femoral head, tip-to-head-surface distance (TSD), and the tip-apex distance (TAD) advocated by Baumgaertner et al. The study evaluated the accuracy of ADAPT. PATIENTS AND METHODS: A total of 55 patients operated with ADAPT between August 2016 and March 2017 were included as subjects. TSD and TAD were measured postoperatively using computed tomography (CT) and X-rays. The intraclass correlation coefficient (ICC) was checked in advance. The error was defined as the difference between postoperative and intraoperative measurement values of ADAPT. Summary statistics, root mean square errors (RMSEs), and correlations were evaluated. RESULTS: ICC was 0.94 [95% CI: 0.90-0.96] in TSD and 0.99 [95% CI: 0.98-0.99] in TAD. The error was -0.35 mm (-1.83 mm to 1.12 mm) in TSD and +0.63 mm (-5.65 mm to 4.59 mm) in TAD. RMSE was 0.63 mm in TSD and 1.53 mm in TAD. Pearson's correlation coefficient was 0.79 [95% CI: 0.66-0.87] in TSD and 0.83 [95% CI: 0.72-0.89] in TAD. There were no adverse events with ADAPT use. CONCLUSION: ADAPT is highly accurate and useful in guiding surgeons in properly positioning the screws.

Comparison of Lymphovenous Shunt Methods in a Rat Model: Supermicrosurgical Lymphaticovenular Anastomosis versus Microsurgical Lymphaticovenous Implantation.

BACKGROUND: Lymphaticovenular anastomosis and lymphaticovenous implantation are the most popular lymphovenous shunt operations for the treatment of obstructive lymphedema. However, no study has been reported regarding direct comparison between lymphaticovenular anastomosis and lymphaticovenous implantation. This study aimed to compare postoperative patency of lymphaticovenular anastomosis and lymphaticovenous implantation using a rat model. METHODS: Twelve Wistar rats were used for the study. The rats were randomized into the lymphaticovenular anastomosis group (n = 6) or the lymphaticovenous implantation group (n = 6). In the lymphaticovenular anastomosis group, the largest femoral lymphatic vessel was anastomosed to a similar-size vein in an end-to-end intima-to-intima coaptation manner, and the other lymphatics were ligated. In the lymphaticovenous implantation group, the femoral lymphatic vessel and surrounding tissue were inserted into the short saphenous vein with a telescopic anastomosis technique. Patency was evaluated intraoperatively and 1 week postoperatively with patent blue dye and indocyanine green lymphography. RESULTS: The mean diameters of the lymphatic vessels and the veins were 0.242 mm (range, 0.20 to 0.35 mm) and 0.471 mm (range, 0.30 to 0.75 mm), respectively. Intraoperative patency was 100 percent (six of six) in both groups (p = 1.000). Postoperative patency was significantly higher in the lymphaticovenular anastomosis group compared with the lymphaticovenous implantation group [100 percent (six of six) versus 33.3 percent (two of six); p = 0.014] CONCLUSION:: Postoperative patency of the lymphaticovenular anastomosis group was higher than that of the lymphaticovenous implantation group, although intraoperative patency rates of the lymphaticovenular anastomosis and lymphaticovenous implantation groups were comparable.

Indocyanine Green Lymphographic Signs of Lymphatic Collateral Formation in Lower Extremity Lymphedema After Cancer Resection.

Indocyanine green lymphography has recently been used to assess lymphatic vessel function in lymphedema patients. Postoperative collateral lymphatic vessels toward ipsilateral axillary lymph nodes are rarely seen above the umbilical level in lower lymphedema patients. Between January 2012 and December 2014, we performed indocyanine green lymphography of 192 limbs in 96 lower extremity lymphedema cases. As a result, dermal back flow appeared in 95 cases, with 38 in the lower abdominal area and 31 in the genital area. We confirmed 3 cases of superficial lymphatic collateral ways extending above the umbilical level to the axillary lymph nodes. All 3 cases had similarity in lower abdominal edema, so excessive lymphatic fluid in the lower abdomen was assumed to be the cause. Lymphatic collateral ways from abdomen to axillary lymph nodes in this study was likely to be designed to prevent the progress of lymphedema.

Preoperative color Doppler ultrasound assessment of the lateral thoracic artery perforator flap and its branching pattern.

The anatomy of the lateral thoracic artery perforator flap remains controversial, but this region is extremely useful as a reconstructive donor site. In this report, we describe the usefulness of the preoperative color Doppler ultrasound evaluation for the harvesting of the lateral thoracic artery perforator flap, and we clarify its branching pattern. Twenty-seven patients underwent the preoperative color Doppler ultrasound assessment before perforator flaps were harvested. We evaluated the branching pattern and the diameter of the flaps by direct observation. All flaps were successfully transferred, and it was found that the branching pattern of the lateral thoracic perforator is divided into three groups: the superficial branch, the medial branch, and the deep branch. Their appearance ratios were 48.1% (13/27), 14.8% (4/27), and 81.5% (22/27), respectively. The lateral thoracic artery perforator flap has a great deal of anatomical variation, and vessels with relatively small diameters compared to those of other flaps. This is why flaps from this region are not currently popular. This study revealed the superiority of the color Doppler ultrasound for preoperative planning of the lateral thoracic artery perforator flap elevation. Furthermore, the branching pattern and the diameters of the different branches were specified.