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The aim of this study was to introduce and report on a 3D-printed perforator navigator and its clinical application. Integrated imaging and 3D printing techniques were employed for the design and manufacture of a perforator navigator. Key techniques included establishing a digital image coordinate system, localizing perforator fascia piercing points, creating a reference plane for the perforator course, and projecting the perforator course onto the body surface. All cases of maxillofacial defect repaired with free fibular myocutaneous flaps, from January 2019 to January 2022, were reinvestigated. Patients treated using traditional perforator localization methods were assigned into group Ⅰ, while those who had a navigator used during treatment were allocated to group Ⅱ. Outcome measurements included perforator positioning accuracy, perforator preparation time (PT), and flap growth score. Capillary refilling time and degree of flap swelling were recorded on the 1st, 3rd, and 7th days after surgery. On the 10th day after surgery, the flap survival situation was graded. In total, 25 patients were included in the study. Perforator preparation time for group Ⅱ was significantly less (p ＝ 0.04) than for group Ⅰ (1038.6 ± 195.4 s versus 1271.4 ± 295.1 s. In group Ⅱ, the mean positioning deviation for the perforator navigator was 2.12 cm less than that for the high-frequency color Doppler (p ＝ 0.001). Group Ⅱ also had a higher score than group Ⅰ for overall flap growth evaluation (nonparametric rank sum test, p ＝ 0.04). Within the scale of the study, it seems that perforator localization and navigation using a 3D-printed navigator is technically feasible, and helps to improve the clinical outcome of free fibular flaps. The perforator navigator will play a useful role in displaying the perforator course, improving the accuracy of perforator localization, reducing surgical injury, and ultimately enhancing flap success rate.

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The brachial artery perforator propeller (BAPP) flap has the advantages of both local and perforator propeller flaps, and it remains relatively underused partly because of the anatomical variations of perforators in the medial arm. We aimed to review our preliminary experience using two different methods for perforator localization of a BAPP flap, including the application of a refined coordinate system (the ABC system) in the medial arm and indocyanine green angiography (ICGA). We evaluated the advantages and disadvantages of these methods and selected the optimal examination mode depending on detailed clinical settings. The perforator was identified for each patient using the ABC system and/or ICGA, depending on the clinical setting. Twenty-two patients underwent soft-tissue reconstructions with 22 BAPP flaps, and perforator localization for all the flaps was performed before surgery using the ABC system. Thirty-one perforators were localized before surgery and marked accordingly, all of which were visualized during surgery, except two, which were not found during the surgery. ICGA was used in six pre-expanded flaps at both stages of surgeries. Twenty-seven perforators were detected before surgery, and all of them were identified during surgery; the previously localized perforators found using the ABC system in the six patients were all reidentified using ICGA. Both the ABC system and ICGA were found to be useful for preoperative perforator localization in BAPP flap transfers. Each method has its unique downsides; however, they can supplement each other to facilitate safe and effective flap elevation. Therefore, selection of the optimal method based on the clinical settings is recommended.

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Objective:To compare the clinical value of CTA and CDU in perforator flap of peroneal artery.Methods:From February 2013 to October 2016, 47 patients who suffered with soft tissue defects and were hospitalised in the Department of Orthopaedics, the 920th Hospital of Joint Logistic Support Force of Chinese PLA were retrospectively reviewed and evaluated. All the defects were reconstructed by the perforator flap of peroneal artery. All patients received preoperative CTA and CDU scans before surgery. Appropriate perforator vessels were selected and the locating points in body surface and external diameters of the perforator vessels were recorded and compared with intraoperative findings. SPSS 22.0 statistical software was used for data analysis. P<0.05 was considered statistically significant. Results:The intraoperative coincidence rate of the proposed perforator vessels was 97.87% for CDU and 95.74% for CTA, with no significant difference between the 2 groups( P>0.05). It was found that the preoperative CTA and CDU measurements were consistent with the actual intraoperative measurements, and there was no significant difference between the 2 groups( P>0.05). For CTA combined with CDU, an intraoperative coincidence rate was 100% in the location of peroneal perforating vessels. All flaps were followed-up for 1 to 18(mean 13.5) months. All the flaps survived well with good texture and appearance without complication. Conclusion:CDU and CTA are reliable and useful in preoperative vascular evaluation of peroneal perforator flap, and both can be used in a complementary or combined manner.