Objective:To explore the application strategies and clinical effects of superior gluteal artery perforator tissue flaps in repairing stage Ⅳ pressure ulcers in the sacrococcygeal region.Methods:This study was a retrospective observational study. From July 2019 to April 2024, 89 patients with stage Ⅳ pressure ulcers in the sacrococcygeal region who met the inclusion criteria were admitted to the First Affiliated Hospital of Nanchang University, including 59 males and 30 females, aged 21 to 84 years. There were 89 sacrococcygeal pressure ulcers, with an area of 5.0 cm×4.0 cm-21.0 cm×21.0 cm after debridement. According to the shape, size, and depth of the wounds after debridement, combined with the elasticity and texture of the skin around the wounds, and the principle of minimizing damage to the donor area, the appropriate forms of superior gluteal artery perforator tissue flaps were cut for wound repair in the following three conditions. (1) For wounds with a round shape, an area of 5.0 cm×5.0 cm-21.0 cm×21.0 cm, and a depth of 1.0-3.5 cm, the superior gluteal artery perforator propeller flap or myocutaneous flap, bilobed superior gluteal artery perforator relay flap, and bilateral superior gluteal artery perforator rotational flap were used. (2) For wounds with an oval shape, an area of 5.0 cm×4.0 cm-18.5 cm×10.5 cm, and a depth of 1.0-3.0 cm, the superior gluteal artery perforator propeller flap or myocutaneous flap, unilateral superior gluteal artery perforator propeller flap combined with contralateral superior gluteal artery perforator V-Y advanced flap or keystone flap were used. (3) For wounds with a fusiformis shape, an area of 7.0 cm×4.0 cm-17.5 cm×6.0 cm, and a depth of 1.5-5.0 cm, the unilateral or bilateral superior gluteal artery perforator V-Y advanced flap, superior gluteal artery perforator keystone flap, or superior gluteal artery perforator keystone flap combined with gluteus maximus muscle flap were used. In this group of patients, a total of 40 superior gluteal artery perforator propeller flaps (with an resection area of 11.0 cm×6.0 cm-17.0 cm×11.0 cm), 22 superior gluteal artery perforator propeller myocutaneous flaps (with an resection area of 10.0 cm×5.0 cm-14.0 cm×8.0 cm), 7 bilobed superior gluteal artery perforator relay flaps (with a main flap resection area of 5.5 cm×5.5 cm-18.0 cm×11.5 cm and a side flap resection area of 4.5 cm×3.0 cm-11.0 cm×6.5 cm), 5 bilateral superior gluteal artery perforator rotational flaps (with a total resection area of 20.0 cm×16.0 cm-26.0 cm×21.0 cm on both sides), 14 superior gluteal artery perforator V-Y advanced flaps (with an resection area of 12.0 cm×10.0 cm-18.0 cm×18.0 cm), 13 superior gluteal artery perforator keystone flaps (with an resection area of 13.0 cm×6.5 cm-19.0 cm×18.0 cm), and 3 gluteus maximus muscle flaps (with an resection area of 8.0 cm×3.0 cm-15.0 cm×4.5 cm). The donor area wounds were all directly sutured. The survival of tissue flaps was observed and the incidence rate of delayed wound healing in the reception area was calculated, and wound healing in the donor area was observed. The appearance and texture of tissue flaps and recurrence of pressure ulcers were followed up.Results:After surgery, all bilateral superior gluteal artery perforator rotational flaps, superior gluteal artery perforator V-Y advanced flaps, superior gluteal artery perforator keystone flaps, and gluteus maximus muscle flaps survived well. There were 6 cases of delayed wound healing in the reception area after surgery, with an incidence rate of 6.7% (6/89). Two patients had incision dehiscence in the donor area wounds due to postoperative bleeding, the wounds healed after debridement, vacuum sealing drainage, and dressing change. The wounds in the donor area of the remaining patients healed well. Six patients were lost to follow-up. Eighty-three patients were followed up for 3-48 months, of whom 4 patients died. Among the remaining 79 patients, 3 cases had pressure ulcers recur due to improper nursing, while the rest of the patients had tissue flaps with good appearance and soft texture and no recurrence of pressure ulcers.Conclusions:Based on the characteristics of wound shape, size, and depth after debridement of stage Ⅳ pressure ulcers in the sacrococcygeal region, individualized selection of flap, myocutaneous flap, or a combination of flap and gluteus maximus muscle flap based on the perforating branch of the superior gluteal artery perforator can achieve good clinical repair results. The postoperative tissue flap survived well, with a good appearance, soft texture, and less recurrence of pressure ulcers.

Objective:To explore the application strategies and clinical effects of superior gluteal artery perforator tissue flaps in repairing stage Ⅳ pressure ulcers in the sacrococcygeal region.Methods:This study was a retrospective observational study. From July 2019 to April 2024, 89 patients with stage Ⅳ pressure ulcers in the sacrococcygeal region who met the inclusion criteria were admitted to the First Affiliated Hospital of Nanchang University, including 59 males and 30 females, aged 21 to 84 years. There were 89 sacrococcygeal pressure ulcers, with an area of 5.0 cm×4.0 cm-21.0 cm×21.0 cm after debridement. According to the shape, size, and depth of the wounds after debridement, combined with the elasticity and texture of the skin around the wounds, and the principle of minimizing damage to the donor area, the appropriate forms of superior gluteal artery perforator tissue flaps were cut for wound repair in the following three conditions. (1) For wounds with a round shape, an area of 5.0 cm×5.0 cm-21.0 cm×21.0 cm, and a depth of 1.0-3.5 cm, the superior gluteal artery perforator propeller flap or myocutaneous flap, bilobed superior gluteal artery perforator relay flap, and bilateral superior gluteal artery perforator rotational flap were used. (2) For wounds with an oval shape, an area of 5.0 cm×4.0 cm-18.5 cm×10.5 cm, and a depth of 1.0-3.0 cm, the superior gluteal artery perforator propeller flap or myocutaneous flap, unilateral superior gluteal artery perforator propeller flap combined with contralateral superior gluteal artery perforator V-Y advanced flap or keystone flap were used. (3) For wounds with a fusiformis shape, an area of 7.0 cm×4.0 cm-17.5 cm×6.0 cm, and a depth of 1.5-5.0 cm, the unilateral or bilateral superior gluteal artery perforator V-Y advanced flap, superior gluteal artery perforator keystone flap, or superior gluteal artery perforator keystone flap combined with gluteus maximus muscle flap were used. In this group of patients, a total of 40 superior gluteal artery perforator propeller flaps (with an resection area of 11.0 cm×6.0 cm-17.0 cm×11.0 cm), 22 superior gluteal artery perforator propeller myocutaneous flaps (with an resection area of 10.0 cm×5.0 cm-14.0 cm×8.0 cm), 7 bilobed superior gluteal artery perforator relay flaps (with a main flap resection area of 5.5 cm×5.5 cm-18.0 cm×11.5 cm and a side flap resection area of 4.5 cm×3.0 cm-11.0 cm×6.5 cm), 5 bilateral superior gluteal artery perforator rotational flaps (with a total resection area of 20.0 cm×16.0 cm-26.0 cm×21.0 cm on both sides), 14 superior gluteal artery perforator V-Y advanced flaps (with an resection area of 12.0 cm×10.0 cm-18.0 cm×18.0 cm), 13 superior gluteal artery perforator keystone flaps (with an resection area of 13.0 cm×6.5 cm-19.0 cm×18.0 cm), and 3 gluteus maximus muscle flaps (with an resection area of 8.0 cm×3.0 cm-15.0 cm×4.5 cm). The donor area wounds were all directly sutured. The survival of tissue flaps was observed and the incidence rate of delayed wound healing in the reception area was calculated, and wound healing in the donor area was observed. The appearance and texture of tissue flaps and recurrence of pressure ulcers were followed up.Results:After surgery, all bilateral superior gluteal artery perforator rotational flaps, superior gluteal artery perforator V-Y advanced flaps, superior gluteal artery perforator keystone flaps, and gluteus maximus muscle flaps survived well. There were 6 cases of delayed wound healing in the reception area after surgery, with an incidence rate of 6.7% (6/89). Two patients had incision dehiscence in the donor area wounds due to postoperative bleeding, the wounds healed after debridement, vacuum sealing drainage, and dressing change. The wounds in the donor area of the remaining patients healed well. Six patients were lost to follow-up. Eighty-three patients were followed up for 3-48 months, of whom 4 patients died. Among the remaining 79 patients, 3 cases had pressure ulcers recur due to improper nursing, while the rest of the patients had tissue flaps with good appearance and soft texture and no recurrence of pressure ulcers.Conclusions:Based on the characteristics of wound shape, size, and depth after debridement of stage Ⅳ pressure ulcers in the sacrococcygeal region, individualized selection of flap, myocutaneous flap, or a combination of flap and gluteus maximus muscle flap based on the perforating branch of the superior gluteal artery perforator can achieve good clinical repair results. The postoperative tissue flap survived well, with a good appearance, soft texture, and less recurrence of pressure ulcers.

Objective To evaluate the diagnostic value of cardiac magnetic resonance(CMR)in patients with severe connective tissue disease-associated pulmonary hypertension(CTD-PAH).Methods A total of 48 patients diagnosed with CTD-PAH by right heart catheterization(RHC)in Tianjin Medical University General Hospital from June 2018 to July 2021 were retrospectively included.The parameters of right ventricular(RV)morphology,function and ventricular septum(IVS)were obtained by manual delineation on CMR images and corrected by body surface area.The late gadolinium enhancement(LGE)myocardial mass(MM)and its percentage in left ventricular(LV)MM were manually sketched and calculated on LGE images.The patients were divided into the mild-moderate group and the severe group according to mean pulmonary arterial pressure(mPAP).CMR parameters were compared between the two groups.The diagnostic value of CMR for severe CTD-PAH was analyzed by receiver operating characteristic(ROC)curve.Results A total of 48 patients with CTD-PAH were included in this study.The curvature of interventricular septum(CIVS)and RV ejection fraction(EF)were lower in the severe group than those in the mild-moderate group,and the time proportion of IVS deformation,RV end-diastolic volume index(EDVI),RV end-systolic volume index(ESVI)and RV MM were higher than those in the mild-moderate group(P＜0.05).ROC curve analysis showed that RV MM,time proportion of IVS deformation and RV ESVI had better diagnostic efficacy in severe CTD-PAH patients(AUC was 0.792,0.766 and 0.731,respectively).The combined AUC of the three parameters was 0.840,specificity was 85.7%and sensitivity was 79.4%.Conclusion The parameters of RV and IVS measured by CMR can effectively evaluate patients with severe CTD-PAH and directly reflect serverity of cardiac impairment in patients with severe CTD-PAH from the morphological and functional perspective.

Objective    To introduce a new method for identifying intersegmental planes during thoracoscopic segmentectomy using pulmonary circulation single-blocking in the target segment. Methods    To retrospectively analyze the clinical data of 83 patients who underwent thoracoscopic pulmonary segmentectomy from January 2019 to March 2020 using the pulmonary circulation single-blocking method. There were 33 males and 50 females, with a median age of 54 (46-65) years, and they were divided into a single vein group (SVG, n=31) and a single artery group (SAG, n=52), and the clinical data of two groups were compared. Results    The intersegmental planes were identified successfully in both groups and there were no statistically significant differences between the two groups in terms of intersegmental plane management (P=0.823), operating time (P=0.786), intraoperative blood loss (P=0.775), chest drainage time (P=0.659), postoperative hospital stay (P=0.824) or the incidence of postoperative complications (P=1.000). Conclusion    The use of pulmonary circulation single-blocking for intersegmental plane identification during thoracoscopic segmentectomy is safe and feasible, and the intersegmental plane can be satisfactorily identified by the single-blocking of arteries or veins.

Objective To explore the application value of chest dual-energy subtraction (DES) technology in the diagnosis of occupational pneumoconiosis. Methods A total of 86 patients with suspected pneumoconiosis and 21 dust-exposure workers were selected as the research subjects using random sampling method. The posterior and anterior chest radiographs were taken by digital radiography (DR) and DES technology, and the difference of chest radiographs of DR, DES and combined groups were compared. Results The positive rate of superior chest radiographs in DR group was higher than that in DES group (72.9% vs 56.1%, P<0.05). The determination of shadow shape and size, total density and stage of pneumoconiosis on chest radiographs in DES group and combined group were consistent with those in DR group (all Kappa values >0.75, all P<0.01). However, the judgment of small shadow intensity, small shadow aggregation and large shadow distribution in the two groups were not superior to those in the DR group (Kappa value was 0.67, 0.74, both P<0.01). There was no significant difference between DES group and DR group in the determination of small shadow intensity, small shadow aggregation and large shadow distribution (P>0.05). However, there were statistically significant difference in this index between the combined group and DES group and DR group (all P<0.01). There was no statistically significant difference in shadow shape and size, total density and stage of pneumoconiosis in chest radiographs among these three groups (all P>0.05). Conclusion There was no difference between DES alone and DES combined with DR for the diagnosis of pneumoconiosis in terms of shadow shape and size, total density and stage of pneumoconiosis when compared with the gold standard DR. The value of DES in the diagnosis of pneumoconiosis needs further study.

Accurate identification of intersegmental plane is one of the key steps of segmentectomy. Identification of intersegmental plane is usually based on differences in ventilation or circulation between the targeted segment and the reserved segment. In recent years, many methods of showing the intersegmental plane after blocking pulmonary circulation have emerged, and these methods have simplified segmentectomy and shortened the operation time. In this paper, we reviewed the related methods of blocking pulmonary circulation to identify the intersegmental plane.

Objective To investigate the metabolomics characteristic of neuromyelities optica spectrum disorder (NMOSD) in plasma and cerebrospinal fluid.Methods Ultra high performance liquid chromatography-mass spectrometry (UHPLC-MS) was used to identify plasma metabolites in 16 patients with NMOSD and 8 healthy controls.At the same time,the identification of metabolites in cerebrospinal fluid of 8 NMOSD patients and 5 healthy controls was completed.Differential metabolites screening and metabolomic pathway analysis were performed by diversified data analysis methods.Results Compared with healthy control group,the content of 8 substances such as Cis.8.11.14.Eicosatrienoic acid in the plasma of NMOSD patients was increased.The content of 8 substances such as L-glutamine acid were decreased.There was no significant difference in the metabolites between Aquaporin 4 (AQP-4) antibody positive and negative NMOSD plasma.The content of 6 substances such as 3-hydroxybutyric acid in cerebrospinal fluid of patients with NMOSD was reduced.Conclusions The distribution of metabolites in plasma between NMOSD patients and healthy controls was significantly different.There was no significant difference in metabolites between AQP-4 antibody positive and negative NMOSD plasma.There are some differences in metabolites between cerebrospinal fluid of NMOSD patients and healthy controls.A variety of amino acid abnormalities,sphingomyelin dysfunction,energy metabolism and mitochondrial dysfunction were involved in the pathogenesis of NMOSD.