Traditional urostomy management methods primarily rely on clinical experience, lacking precise prediction and personalized intervention approaches. In recent years, the rapid advancement of artificial intelligence technology in the medical field has provided new solutions for intelligent monitoring, risk assessment, and nursing optimization of urostomy leakage. This paper reviews the research on the application of artificial intelligence in urostomy leakage, introduces the overview of artificial intelligence, the application and effectiveness of artificial intelligence in urostomy leakage, analyzes the shortcomings of this research field, and explores future development trend, in order to provide a reference for formulating clinical nursing programs and prognosis rehabilitation suitable for the leakage of bladder cancer patients with urostomy, and reduce the incidence of leakage and maintain the health of peristomal skin.

Objective:To evaluate the accuracy of a self-developed extraoral scanning system based on photogrammetry technology, and to provide evidence for advancing the development and clinical application evaluation of domestically produced scanning devices.Methods:This research group developed a photogrammetry-based implant extraoral scanning system with customized scan bodies. Two distinct edentulous implant resin models were designed and three-dimensional (3D)-printed by Center of Digital Dentistry, Peking University School and Hospital of Stomatology, containing 6 (Model 1) and 8 (Model 2) abutment analogs respectively. Reference data acquisition was performed using a high-precision denture 3D scanner with scan caps mounted on the analogs. Specialized scan bodies were then mounted on the analogs for 3D positional data acquisition using both the self-developed system (experimental group) and the clinically established system (control group). Each system conducted 10 repeated scans per model. Trueness was assessed through root mean square error (RMSE), linear deviation (LD), and angular deviation (AD) relative to reference data, while precision was determined through intra-group RMSE analysis. Systematic comparisons included inter-group performance on identical models and intra-group variability across different models.Results:For Model 1, the experimental group showed statistically significant advantages over controls in intra-group RMSE [(3.10±0.71) μm vs (4.61±1.51) μm, P<0.001], reference-data RMSE [(21.48±0.60) μm vs (32.50±0.63) μm, P<0.001], linear deviation [23.64 (32.35) μm vs 44.86 (55.73) μm, P<0.001], and angular deviation [0.29° (0.29°) vs 0.23° (0.33°), P<0.001]. In Model 2, significant improvements were observed in intra-group RMSE [(4.47±1.58) μm vs (6.21±2.07) μm, P<0.001], reference-data RMSE [(38.84±0.86) μm vs (43.69±1.34) μm, P<0.001], and linear deviation [37.95 (50.68) μm vs 49.71 (58.89) μm, P<0.001]. Both groups exhibited model-dependent variability, with RMSE of precision and trueness of both groups, linear deviation of experimental group, angular deviation of control group showing statistically significant increases (all P<0.001) corresponding to abutment analog quantity. Conclusions:The self-developed scanning system demonstrates superior accuracy in 3D positional acquisition of abutment analogs compared to the contral group system, with implant number identified as a critical determinant of extraoral scanning accuracy.

OBJECTIVES: This study aimed to investigate the influence of the dimensional stability of 3D printed resin master model on the replication accuracy of implant replicas. METHODS: Ten digital impressions of patients undergoing continuous crowns or fixed bridge restoration supported by two implants were obtained, and resin models with implant replicas were 3D printed. Scanning rods were fixed on the replicas 3, 7, and 14 days after printing. The 3D, linear, and angular deviations of the scanning rods at different times were analyzed through Geomagic Wrap 2021 software. RESULTS: The position of the replicas shifted mesiolingually, in the same direction as the shrinkage of the model. From day 7 onward, the 3D, distance linear, and angular deviations of the replicas (scanning rod) significantly increased compared with those on the 3rd day (P<0.05). On the 14th day, the changes were even more pronounced, with the above deviations showing statistical significance (P<0.05) compared with those for the 3-day and 7-day groups. No statistical difference in height linear deviation was observed among the groups. CONCLUSIONS The insufficient dimensional stability of 3D printed resin models can lead to changes in the relative position and angle of the replicas, thereby affecting the accuracy of the replicas in recreating the implant's position. Complete manufacturing of prosthesis is recommended within 7 days after the model is printed.
Printing, Three-Dimensional ; Humans ; Dental Implants ; Models, Dental ; Dental Impression Technique ; Crowns

OBJECTIVES: To evaluate the accuracy of a self-developed extraoral scanning system based on four-camera stereophotogrammetric technology in the acquisition of three-dimensional positional information on dental implants and conduct a comparative study involving an intraoral scanning system. METHODS: With the use of an in vitro edentulous jaw model with implants, extraoral (experimental group) and intraoral (control group) scanning systems were employed to obtain STL (Standard Tessellation Language) datasets containing three-dimensional morphological and positional information on scan bodies. In addition, a dental model scanner was used to obtain reference data. The three-dimensional morphological, linear, and angular deviations between groups and reference data were analyzed using Geomagic Wrap 2021 software to compare trueness and precision. RESULTS: The extraoral scanning system demonstrated superior trueness in three-dimensional morphological, linear, and angular deviations compared with the intraoral scanning system, with statistically significant differences (P<0.001). The extraoral scanning system also showed a higher precision in three-dimensional morphological deviation (P<0.001). As the number of implants increased, the extraoral scanning system exhibited increased three-dimensional morphological and linear deviations (P<0.001) but maintained a stable angular deviation. The intraoral scanning system displayed significant increases in three-dimensional morphological, linear, and angular deviations with the increase in the number of implants (P<0.05). CONCLUSIONS The stereophotogrammetry-based extraoral scanning system outperforms intraoral scanning system in terms of the accuracy for multi-unit implant positioning and provides a novel approach for attaining a fully digital workflow for implant rehabilitation in edentulous jaws.
Jaw, Edentulous ; Humans ; Dental Impression Technique ; Dental Implants ; Imaging, Three-Dimensional/methods* ; Photogrammetry/methods* ; Models, Dental

AIM:To investigate the protective mechanism of calycosin(CA)on renal structure and antioxi-dant capacity in acute kidney injury(AKI)mice.METHODS:Thirty male C57BL/6J mice were allocated into control group,model group,and treatment group.The treatment group was further subdivided into low-dose CA,middle-dose CA,and high-dose CA groups,receiving 5 mg/kg,10 mg/kg,and 20 mg/kg CA solution by gavage for 6 days.After the pre-treatment phase,both the model and treatment groups were administered an intraperitoneal injection of 20 mg/kg of cis-platin(CDDP)to induce AKI modeling.Specimens from the mice were collected 72 hours post-modeling for further analy-sis.The body weight and the mean mass of both kidneys were assessed.Serum creatinine(SCr)and blood urea nitrogen(BUN)levels were assessed to evaluate kidney function.Kidney pathology was assessed with periodic acid-Schiff(PAS)staining,while protein levels of superoxide dismutase 1(SOD1),SOD2,glutathione peroxidase 1(GPX1),and catalase were evaluated using Western blot and immunohistochemistry assay.RESULTS:Compared with the control group,the model group exhibited a substantial reduction in body mass,a significant increase in the mean mass of bilateral kidneys,and elevated levels of SCr and BUN,indicating impaired renal function(P<0.01).PAS staining revealed pronounced structural damage to the glomeruli and renal tubules,with widespread appearance of tubular casts in model group.The re-sults of Western blot and immunohistochemical staining demonstrated significantly reduced expression of antioxidant en-zymes SOD1,SOD2,GPX1,and catalase(P<0.05).The body weight of mice in the low-dose and middle-dose CA groups exhibited a significant increase than those in the model group,and the kidney weights of mice in Low-dose,middle-dose,and high-dose CA groups were significantly lower than those of mice in the model group(P<0.05).Additionally,SCr and BUN levels were significantly reduced(P<0.01).PAS staining indicated obvious recovery of glomeruli and renal tubules after CA treatment.SOD1 and GPX1 levels were elevated in the middle-dose and high-dose CA groups,and SOD2 and catalase levels were significantly higher in the middle-dose CA group(P<0.05),compared with model group.CON-CLUSION:CA can alleviate CDDP-induced kidney injury in AKI mice by enhancing the expression of antioxidant enzymes SOD1,SOD2,GPX1,and catalase.

Traditional urostomy management methods primarily rely on clinical experience, lacking precise prediction and personalized intervention approaches. In recent years, the rapid advancement of artificial intelligence technology in the medical field has provided new solutions for intelligent monitoring, risk assessment, and nursing optimization of urostomy leakage. This paper reviews the research on the application of artificial intelligence in urostomy leakage, introduces the overview of artificial intelligence, the application and effectiveness of artificial intelligence in urostomy leakage, analyzes the shortcomings of this research field, and explores future development trend, in order to provide a reference for formulating clinical nursing programs and prognosis rehabilitation suitable for the leakage of bladder cancer patients with urostomy, and reduce the incidence of leakage and maintain the health of peristomal skin.

AIM:To investigate the protective mechanism of calycosin(CA)on renal structure and antioxi-dant capacity in acute kidney injury(AKI)mice.METHODS:Thirty male C57BL/6J mice were allocated into control group,model group,and treatment group.The treatment group was further subdivided into low-dose CA,middle-dose CA,and high-dose CA groups,receiving 5 mg/kg,10 mg/kg,and 20 mg/kg CA solution by gavage for 6 days.After the pre-treatment phase,both the model and treatment groups were administered an intraperitoneal injection of 20 mg/kg of cis-platin(CDDP)to induce AKI modeling.Specimens from the mice were collected 72 hours post-modeling for further analy-sis.The body weight and the mean mass of both kidneys were assessed.Serum creatinine(SCr)and blood urea nitrogen(BUN)levels were assessed to evaluate kidney function.Kidney pathology was assessed with periodic acid-Schiff(PAS)staining,while protein levels of superoxide dismutase 1(SOD1),SOD2,glutathione peroxidase 1(GPX1),and catalase were evaluated using Western blot and immunohistochemistry assay.RESULTS:Compared with the control group,the model group exhibited a substantial reduction in body mass,a significant increase in the mean mass of bilateral kidneys,and elevated levels of SCr and BUN,indicating impaired renal function(P<0.01).PAS staining revealed pronounced structural damage to the glomeruli and renal tubules,with widespread appearance of tubular casts in model group.The re-sults of Western blot and immunohistochemical staining demonstrated significantly reduced expression of antioxidant en-zymes SOD1,SOD2,GPX1,and catalase(P<0.05).The body weight of mice in the low-dose and middle-dose CA groups exhibited a significant increase than those in the model group,and the kidney weights of mice in Low-dose,middle-dose,and high-dose CA groups were significantly lower than those of mice in the model group(P<0.05).Additionally,SCr and BUN levels were significantly reduced(P<0.01).PAS staining indicated obvious recovery of glomeruli and renal tubules after CA treatment.SOD1 and GPX1 levels were elevated in the middle-dose and high-dose CA groups,and SOD2 and catalase levels were significantly higher in the middle-dose CA group(P<0.05),compared with model group.CON-CLUSION:CA can alleviate CDDP-induced kidney injury in AKI mice by enhancing the expression of antioxidant enzymes SOD1,SOD2,GPX1,and catalase.

Objective:To evaluate the accuracy of a self-developed extraoral scanning system based on photogrammetry technology, and to provide evidence for advancing the development and clinical application evaluation of domestically produced scanning devices.Methods:This research group developed a photogrammetry-based implant extraoral scanning system with customized scan bodies. Two distinct edentulous implant resin models were designed and three-dimensional (3D)-printed by Center of Digital Dentistry, Peking University School and Hospital of Stomatology, containing 6 (Model 1) and 8 (Model 2) abutment analogs respectively. Reference data acquisition was performed using a high-precision denture 3D scanner with scan caps mounted on the analogs. Specialized scan bodies were then mounted on the analogs for 3D positional data acquisition using both the self-developed system (experimental group) and the clinically established system (control group). Each system conducted 10 repeated scans per model. Trueness was assessed through root mean square error (RMSE), linear deviation (LD), and angular deviation (AD) relative to reference data, while precision was determined through intra-group RMSE analysis. Systematic comparisons included inter-group performance on identical models and intra-group variability across different models.Results:For Model 1, the experimental group showed statistically significant advantages over controls in intra-group RMSE [(3.10±0.71) μm vs (4.61±1.51) μm, P<0.001], reference-data RMSE [(21.48±0.60) μm vs (32.50±0.63) μm, P<0.001], linear deviation [23.64 (32.35) μm vs 44.86 (55.73) μm, P<0.001], and angular deviation [0.29° (0.29°) vs 0.23° (0.33°), P<0.001]. In Model 2, significant improvements were observed in intra-group RMSE [(4.47±1.58) μm vs (6.21±2.07) μm, P<0.001], reference-data RMSE [(38.84±0.86) μm vs (43.69±1.34) μm, P<0.001], and linear deviation [37.95 (50.68) μm vs 49.71 (58.89) μm, P<0.001]. Both groups exhibited model-dependent variability, with RMSE of precision and trueness of both groups, linear deviation of experimental group, angular deviation of control group showing statistically significant increases (all P<0.001) corresponding to abutment analog quantity. Conclusions:The self-developed scanning system demonstrates superior accuracy in 3D positional acquisition of abutment analogs compared to the contral group system, with implant number identified as a critical determinant of extraoral scanning accuracy.

Objective:To develop an efficient and robust method based on three dimensional facial landmarks for evaluating chin region asymmetry at the soft tissue level and to compare it with the tradi-tional mirror-overlap analysis method in order to test its availability.Methods:Standard symmetrical face was used for mental tubercle coordinate transformation so as to filter soft tissue three dimensional spatial angle and construct corresponding three dimensional spatial angle wireframe template.Ten patients aged 12-32 years with clinical chin region asymmetry diagnosis at the Department of Orthodontics of Peking University Hospital of Stomatology from November 2020 to November 2021 were randomly selected.Three dimensional soft tissue face scan data of the patients were collected by three dimensional face scanner and the landmark points were automatically determined by the Meshmonk non-rigid registration algorithm pro-gram,and in this way,the asymmetric three dimensional spatial angle wireframe template and corre-sponding spatial angle parameters were generated.Mirror-overlap analysis of face scan data was also per-formed in Geomagic Studio 2015 software and deviation color maps were generated.This study took mirror-overlap analysis as the gold standard method,the response rate of chin region asymmetry was eva-luated by the outcomes of the mirror-overlap analysis and three dimensional spatial angle wireframe tem-plate analysis.Results:Nine three dimensional spatial angle indicators were selected through coordinate transformation,and the response rate was calculated using mirror-overlap analysis as the gold standard method.Among these ten selected patients,the response rate of the total chin region asymmetry was 90％(9/10).Using the deviation value of mirror-overlap analysis as a reference,the response rate of chin region asymmetry in the X dimension was 86％,the response rate of chin region asymmetry in the Y dimension was 89％,and the response rate of chin region asymmetry in the Z dimension was 100％.Conclusion:The three dimensional soft tissue spatial angle wireframe template proposed in this study has some feasibility in evaluating chin region asymmetry at the soft tissue level,and its ability to recognize asymmetry separately in the three dimensional direction is better than the mirror-overlap analysis method,and the indicators recognition rate still needs to be further improved.

To explore the technical process and the therapeutic effect of using sequential surgical guide with independent intellectual property rights assisting immediate implantation and restoration of the full arch, with the support from the periodontal splint for mobile supporting teeth, patients with severe periodontitis who planned to undergo immediate full arch implantation were recruited from August 2019 to December 2020 at the Department of Prosthodontics, Department of Periodontology, Department of Implantology and First Clinical Division, Peking University School and Hospital of Stomatology. Through the procedure of collecting preoperative maxillofacial data, making systematic diagnostic design, making periodontal splints fixation, producing surgical guide, and carrying out guided surgery for full arch immediate implantation, eight cases were included. By registering the postoperative cone-beam CT (CBCT) with the preoperative data, the difference between the actual three-dimensional position of the implants and the virtual design was observed, and the accuracy of the implant placement position guided by the sequential guide was statistically analyzed using SPSS 25.0 software. Analysis indicators include coronal and apical global displacement, coronal horizontal and vertical displacement, apical horizontal and vertical displacement, and angular deviation. Results revealed that the 8 patients [2 males and 6 females, aged (49.0±9.3) years (38-65 years)] of recruited cases included 7 cases of maxilla and 1 cases of mandible. A total of 48 implants, of which 44 implants were placed upright and 4 were placed tilted, 16 implants in the anterior region and 32 implants in the posterior region. No guide plate fracture or damage to important anatomical structures were reported. The overall displacement at the coronal point [(0.83±0.48) mm] and the global displacement at the apical point [(1.36±0.57) mm] were within the clinically acceptable safety range, and the horizontal displacement and vertical displacement at the coronal point, horizontal displacement and vertical displacement at the apical point, and the angle deviation of implants axial have no statistic significant difference in the anterior and posterior region ( P>0.05). Periodontal splints combined with sequential surgical guides to assist patients with severe periodontitis for immediate full arch implantation and immediate restoration can expand the indications of guide assisted implant surgery. It meets the safety requirements in clinical applications.