Objective:To investigate the effects of lipopolysaccharide (LPS)-activated stimulator of interferon genes (STING) signaling on the biological behavior of periodontal ligament cells and its mechanism of action.Methods:Human periodontal ligament cells (hPDLC) were divided into the PBS group and the LPS group by stimulated with phosphate-buffered saline (PBS) and LPS derived from Porphyromonas gingivalis (ATCC 33277) for 12 hours, respectively. The intracellular distribution of 8-hydroxydeoxyguanosine (8-OHdG), a marker of DNA damage, and the activation level of STING signaling were detected by immunofluorescence. The source of intracellular double-stranded DNA was detected by live-cell probes. The levels of osteogenic-related proteins, such as special protein 7 (SP7), bone morphogenetic protein 2 (BMP2), cyclic guanosine monophosphate-adenosine monophosphate synthase (cGAS), and STING were detected by Western blotting. The cell supernatants of the PBS group and the LPS group were collected, and the levels of inflammatory cytokines, such as interleukin (IL)-1β, IL-6, and interferon (IFN)-β, were detected by double-antibody sandwich enzyme-linked immunosorbent assay (ELISA). A total of 12 cgas knockout mice and 12 littermate wild-type mice were constructed. The maxillary second molars of the mice were ligated with silk or sham surgery, respectively. After 7 days of modeling, the mice were divided into littermate control sham surgery group, littermate control periodontitis group, cgas knockout sham surgery group, and cgas knockout periodontitis group, with 6 mice in each group. Micro-CT was used to collect image data, and three-dimensional reconstructions were performed on the maxillary samples of each group. The distance from the cemento-enamel junction to the alveolar bone crest (CEJ-ABC), bone volume fraction (BV/TV), and bone mineral density (BMD) in the model area were statistically analyzed using CTAn and CTVOX software. Frozen sectioning was used to obtain sections of the maxillary molars of each group of mice, and the signal intensities of cGAS and STING proteins were detected by immunofluorescence. Results:Immunofluorescence results showed that the fluorescence signal intensity of 8-OHdG outside the nucleus in the LPS group (4.09±0.24) was significantly higher than that in the PBS group (1.00±0.10) ( t=20.33, P<0.001). The co-localization signal of mitochondrial marker TOM20 and 8-OHdG (8.56±0.53) were significantly higher than that of PBS group (1.00±0.09) ( t=24.37, P<0.001). Live cell DNA probe detection showed that the signal intensity of double-stranded DNA in LPS group (3.23±0.12) was significantly stronger than that in PBS group (1.00±0.17) ( t=18.30, P<0.001). Immunofluorescence demonstrated a significant increase in STING expression in hPDLC of the LPS group ( t=6.42, P<0.001), and it was colocalized with the Golgi marker GM130. ELISA results showed that the abundance of IL-6, IFN-β, and IL-1β in the supernatant of the LPS group were higher than those of the PBS group ( t=12.44, t=11.38, t=9.48, all P<0.001). Animal experiments confirmed that compared with the sham operation group [(207.61±38.09) and (238.97±45.90) μm], the CEJ-ABC in the periodontitis group [(420.31±35.32) and (405.16±35.51) μm] were increased ( P<0.01), while the CEJ-ABC in the cgas knockout periodontitis group [(295.11±35.43) and (309.15±32.22) μm] were significantly lower than those in the control periodontitis group of the same litter ( P<0.01). Compared with the sham operation group (45.84±6.41), the STING fluorescence signal in the periodontitis group (152.44±6.86) was significantly increased ( P<0.001). Compared with the control periodontitis group of the same litter, the STING signal in the cgas knockout periodontitis group was significantly reduced (88.31±9.70) ( P<0.001). Conclusions:LPS stimulation can activate the STING signal by generating mitochondrial-derived double-stranded DNA, stimulating hPDLC to secrete inflammatory cytokines and impairing osteogenic differentiation potential. Suppressing STING activation in animal models can reduce bone destruction in periodontitis.

This article reported a pregnant woman admitted to the hospital due to "25 +2 weeks of amenorrhea and a 1-day history of shortened cervical canal accompanied by vaginal bleeding". The patient with pregestational diabetes mellitus and suboptimal glycemic control required prolonged hospitalization for tocolytic therapy due to shortened cervical length. She developed a cough at 31 weeks and 4 days of gestation, followed by right-sided intercostal pain and hypotension after coughing at 31 weeks and 6 days of gestation. Bedside chest ultrasound showed a small anechoic fluid collection (approximately 1.1 cm in width) in the right pleural cavity. The emergency cesarean section was performed at 31 weeks and 4 days of gestation. However, the intraoperative bleeding and other conditions were inconsistent with the obstetric clinical presentations of blood loss. Subsequent repeated ultrasound and CT examinations confirmed the diagnosis of pulmonary sequestration and right-sided progressive hemopneumothorax. On the same day, an emergency right lower lobectomy was performed, achieving stable postoperative recovery. Both mother and infant had favorable outcomes. Hemopneumothorax complicated by pulmonary sequestration is uncommon, and its occurrence during pregnancy is exceedingly rare. Multidisciplinary consultations, aggressive, rapid, and accurate diagnosis, and combined treatment are critical to ensuring maternal-fetal survival. Hemopneumothorax caused by the rupture of pulmonary sequestration during pregnancy represents a life-threatening condition. Emergency thoracotomy can timely clarify the cause, arrest bleeding, relieve compression, and resect the lesion, thereby reducing mortality and the complications risk.

Objective The purpose of this study was to provide a more effective method for researching the prevention and treatment of Graves'disease by comparing the effects of two plasmid vectors expressing the human thyrotropin receptor(TSHR)A subunit gene in inducing an animal model of Graves'disease via electroporation.Methods Plasmids pcDNA3.1-THSR A,and pTriEx1.1-THSR A expressing the TSHR A subunit were constructed and used to induce Graves'disease by intramuscular injection with immediate electroporation once every 3 weeks for a total of 4 times.Mice in the control group were injected with PBS.One week after the second electroporation,blood was collected to measure serum thyrotropin receptor antibody(TRAb).Three weeks following the last electroporation,echocardiography was performed on the mice.Mice were sacrificed 4 weeks after the last electroporation;blood,thyroid,and orbital tissues were collected;serum total thyroxine(TT4)was measured;and histological examination was performed.Results The average concentrations of serum TRAb in the pcDNA3.1-TSHR A group(n=15)and the pTriEx1.1-TSHR A group(n=13)were(6.9±2.0)U/L and(7.5±2.2)U/L,respectively.The latter was significantly higher than that in the control group(4.9±0.5)U/L(P=0.033).The average concentrations of serum TT4 in the pcDNA3.1-TSHR A group and pTriEx1.1-TSHR A group were(41.4±23.8)ng/mL and(63.2±53.7)ng/mL,respectively,both higher than that in the control group:(20.2±4.0)ng/mL(P＜0.01).Thyroid pathology showed thyroid follicular epithelial hyperplasia with T-cell infiltration in the model group.Echocardiography showed that the left ventricle mass in the pTriEx1.1-TSHR A group was higher than those in the control group(P=0.007)and pcDNA3.1-TSHR A group(P=0.012).Orbital pathology showed fibrotic changes in the extraocular muscles of mice in the model groups.Conclusions Both pcDNA3.1 and pTriEx1.1 expressing the TSHR A subunit were able to induce Graves'disease in mice by electroporation,and the efficiency of the two plasmids in inducing hyperthyroidism and Graves'ophthalmopathy was similar.The efficiency of pTriEx 1.1-TSHR A in inducing thyrotoxic heart disease was better than that of pcDNA3.1-TSHR A.

Objective To establish autoverification rules for six routine coagulation assays(PT,APTT,TT,Fib,DD,and FDP)based on the stratification of outpatients and inpatients,in accordance with CLSI AUTO-10A,AUTO-15,and WS/T 616-2018 guide-lines,and to validate the feasibility of this stratified strategy with clinical data while optimizing verification efficiency.Methods A to-tal of 323 451 coagulation test results from Zhongshan Hospital,Fudan University in 2022 were retrospectively analyzed to define auto-verification rules involving critical values,instrument flags,logical rules,historical comparison,and numerical ranges.A stratified au-toverification system was established by applying distinct rules for outpatient and inpatient populations.Subsequently,the rules were op-timized using 87 830 coagulation test results from January to March 2024,and the consistency between autoverification and manual veri-fication was prospectively evaluated using 33 968 consecutive coagulation specimens collected in April 2024.Results A stratified au-toverification system was successfully developed,comprising a total of 53 rules.The pass rate of overall verification was 77.16％(26 210/33 968),with a true-positive rate of 19.64％(6 672/33 968),a false-positive rate of 3.20％(1 086/33 968),a true-nega-tive rate of 77.16％(26 210/33 968),and no false negatives were detected.Conclusion The proposed autoverification system signifi-cantly improved verification efficiency.The stratified design based on outpatient and inpatient populations effectively minimized the risk of false negatives,and may provide a novel approach for the further development and optimization of coagulation test autoverification.

Objective:To investigate the effects of lipopolysaccharide (LPS)-activated stimulator of interferon genes (STING) signaling on the biological behavior of periodontal ligament cells and its mechanism of action.Methods:Human periodontal ligament cells (hPDLC) were divided into the PBS group and the LPS group by stimulated with phosphate-buffered saline (PBS) and LPS derived from Porphyromonas gingivalis (ATCC 33277) for 12 hours, respectively. The intracellular distribution of 8-hydroxydeoxyguanosine (8-OHdG), a marker of DNA damage, and the activation level of STING signaling were detected by immunofluorescence. The source of intracellular double-stranded DNA was detected by live-cell probes. The levels of osteogenic-related proteins, such as special protein 7 (SP7), bone morphogenetic protein 2 (BMP2), cyclic guanosine monophosphate-adenosine monophosphate synthase (cGAS), and STING were detected by Western blotting. The cell supernatants of the PBS group and the LPS group were collected, and the levels of inflammatory cytokines, such as interleukin (IL)-1β, IL-6, and interferon (IFN)-β, were detected by double-antibody sandwich enzyme-linked immunosorbent assay (ELISA). A total of 12 cgas knockout mice and 12 littermate wild-type mice were constructed. The maxillary second molars of the mice were ligated with silk or sham surgery, respectively. After 7 days of modeling, the mice were divided into littermate control sham surgery group, littermate control periodontitis group, cgas knockout sham surgery group, and cgas knockout periodontitis group, with 6 mice in each group. Micro-CT was used to collect image data, and three-dimensional reconstructions were performed on the maxillary samples of each group. The distance from the cemento-enamel junction to the alveolar bone crest (CEJ-ABC), bone volume fraction (BV/TV), and bone mineral density (BMD) in the model area were statistically analyzed using CTAn and CTVOX software. Frozen sectioning was used to obtain sections of the maxillary molars of each group of mice, and the signal intensities of cGAS and STING proteins were detected by immunofluorescence. Results:Immunofluorescence results showed that the fluorescence signal intensity of 8-OHdG outside the nucleus in the LPS group (4.09±0.24) was significantly higher than that in the PBS group (1.00±0.10) ( t=20.33, P<0.001). The co-localization signal of mitochondrial marker TOM20 and 8-OHdG (8.56±0.53) were significantly higher than that of PBS group (1.00±0.09) ( t=24.37, P<0.001). Live cell DNA probe detection showed that the signal intensity of double-stranded DNA in LPS group (3.23±0.12) was significantly stronger than that in PBS group (1.00±0.17) ( t=18.30, P<0.001). Immunofluorescence demonstrated a significant increase in STING expression in hPDLC of the LPS group ( t=6.42, P<0.001), and it was colocalized with the Golgi marker GM130. ELISA results showed that the abundance of IL-6, IFN-β, and IL-1β in the supernatant of the LPS group were higher than those of the PBS group ( t=12.44, t=11.38, t=9.48, all P<0.001). Animal experiments confirmed that compared with the sham operation group [(207.61±38.09) and (238.97±45.90) μm], the CEJ-ABC in the periodontitis group [(420.31±35.32) and (405.16±35.51) μm] were increased ( P<0.01), while the CEJ-ABC in the cgas knockout periodontitis group [(295.11±35.43) and (309.15±32.22) μm] were significantly lower than those in the control periodontitis group of the same litter ( P<0.01). Compared with the sham operation group (45.84±6.41), the STING fluorescence signal in the periodontitis group (152.44±6.86) was significantly increased ( P<0.001). Compared with the control periodontitis group of the same litter, the STING signal in the cgas knockout periodontitis group was significantly reduced (88.31±9.70) ( P<0.001). Conclusions:LPS stimulation can activate the STING signal by generating mitochondrial-derived double-stranded DNA, stimulating hPDLC to secrete inflammatory cytokines and impairing osteogenic differentiation potential. Suppressing STING activation in animal models can reduce bone destruction in periodontitis.

This article reported a pregnant woman admitted to the hospital due to "25 +2 weeks of amenorrhea and a 1-day history of shortened cervical canal accompanied by vaginal bleeding". The patient with pregestational diabetes mellitus and suboptimal glycemic control required prolonged hospitalization for tocolytic therapy due to shortened cervical length. She developed a cough at 31 weeks and 4 days of gestation, followed by right-sided intercostal pain and hypotension after coughing at 31 weeks and 6 days of gestation. Bedside chest ultrasound showed a small anechoic fluid collection (approximately 1.1 cm in width) in the right pleural cavity. The emergency cesarean section was performed at 31 weeks and 4 days of gestation. However, the intraoperative bleeding and other conditions were inconsistent with the obstetric clinical presentations of blood loss. Subsequent repeated ultrasound and CT examinations confirmed the diagnosis of pulmonary sequestration and right-sided progressive hemopneumothorax. On the same day, an emergency right lower lobectomy was performed, achieving stable postoperative recovery. Both mother and infant had favorable outcomes. Hemopneumothorax complicated by pulmonary sequestration is uncommon, and its occurrence during pregnancy is exceedingly rare. Multidisciplinary consultations, aggressive, rapid, and accurate diagnosis, and combined treatment are critical to ensuring maternal-fetal survival. Hemopneumothorax caused by the rupture of pulmonary sequestration during pregnancy represents a life-threatening condition. Emergency thoracotomy can timely clarify the cause, arrest bleeding, relieve compression, and resect the lesion, thereby reducing mortality and the complications risk.

Objective The purpose of this study was to provide a more effective method for researching the prevention and treatment of Graves'disease by comparing the effects of two plasmid vectors expressing the human thyrotropin receptor(TSHR)A subunit gene in inducing an animal model of Graves'disease via electroporation.Methods Plasmids pcDNA3.1-THSR A,and pTriEx1.1-THSR A expressing the TSHR A subunit were constructed and used to induce Graves'disease by intramuscular injection with immediate electroporation once every 3 weeks for a total of 4 times.Mice in the control group were injected with PBS.One week after the second electroporation,blood was collected to measure serum thyrotropin receptor antibody(TRAb).Three weeks following the last electroporation,echocardiography was performed on the mice.Mice were sacrificed 4 weeks after the last electroporation;blood,thyroid,and orbital tissues were collected;serum total thyroxine(TT4)was measured;and histological examination was performed.Results The average concentrations of serum TRAb in the pcDNA3.1-TSHR A group(n=15)and the pTriEx1.1-TSHR A group(n=13)were(6.9±2.0)U/L and(7.5±2.2)U/L,respectively.The latter was significantly higher than that in the control group(4.9±0.5)U/L(P=0.033).The average concentrations of serum TT4 in the pcDNA3.1-TSHR A group and pTriEx1.1-TSHR A group were(41.4±23.8)ng/mL and(63.2±53.7)ng/mL,respectively,both higher than that in the control group:(20.2±4.0)ng/mL(P＜0.01).Thyroid pathology showed thyroid follicular epithelial hyperplasia with T-cell infiltration in the model group.Echocardiography showed that the left ventricle mass in the pTriEx1.1-TSHR A group was higher than those in the control group(P=0.007)and pcDNA3.1-TSHR A group(P=0.012).Orbital pathology showed fibrotic changes in the extraocular muscles of mice in the model groups.Conclusions Both pcDNA3.1 and pTriEx1.1 expressing the TSHR A subunit were able to induce Graves'disease in mice by electroporation,and the efficiency of the two plasmids in inducing hyperthyroidism and Graves'ophthalmopathy was similar.The efficiency of pTriEx 1.1-TSHR A in inducing thyrotoxic heart disease was better than that of pcDNA3.1-TSHR A.

Objective To establish autoverification rules for six routine coagulation assays(PT,APTT,TT,Fib,DD,and FDP)based on the stratification of outpatients and inpatients,in accordance with CLSI AUTO-10A,AUTO-15,and WS/T 616-2018 guide-lines,and to validate the feasibility of this stratified strategy with clinical data while optimizing verification efficiency.Methods A to-tal of 323 451 coagulation test results from Zhongshan Hospital,Fudan University in 2022 were retrospectively analyzed to define auto-verification rules involving critical values,instrument flags,logical rules,historical comparison,and numerical ranges.A stratified au-toverification system was established by applying distinct rules for outpatient and inpatient populations.Subsequently,the rules were op-timized using 87 830 coagulation test results from January to March 2024,and the consistency between autoverification and manual veri-fication was prospectively evaluated using 33 968 consecutive coagulation specimens collected in April 2024.Results A stratified au-toverification system was successfully developed,comprising a total of 53 rules.The pass rate of overall verification was 77.16％(26 210/33 968),with a true-positive rate of 19.64％(6 672/33 968),a false-positive rate of 3.20％(1 086/33 968),a true-nega-tive rate of 77.16％(26 210/33 968),and no false negatives were detected.Conclusion The proposed autoverification system signifi-cantly improved verification efficiency.The stratified design based on outpatient and inpatient populations effectively minimized the risk of false negatives,and may provide a novel approach for the further development and optimization of coagulation test autoverification.

Objective To explore the evaluation of platelet aggregation degree through blood smear micros-copy and calculate the correction formula for false decrease in platelet count based on it,in order to achieve ac-curate platelet counting.Methods Venous blood samples with EDTA-K2 anticoagulant causing platelet aggre-gation and sodium citrate anticoagulant not causing platelet aggregation.The manual microscopic examination of blood smears was used to analyze the optimal blood volume and angle for manual slide analysis.Human ma-chine slide comparison and manual slide repeatability comparison were conducted to evaluate the degree of platelet aggregation,its relationship with the degree of false decrease in platelet count was analyzed,and the correction formula for false decrease in platelet count was calculated.Results The results showed that 45° 4μL of artificial smear,and observing 10 oil-immersion fields at the tail junction could more objectively reflect the degree of platelet aggregation.Through fitting of regression equations,platelet aggregation rate,platelet aggregation count,and platelet aggregation pile count showed good linear regression relationships with platelet pseudo-decrease(R2=0.905).Three parameters of platelet aggregation could be obtained through blood smear microscopic examination.The difference in platelet pseudo-decrease could be calculated using the regression e-quation,the sum of the difference and the aggregated EDTA-K2 anticoagulant platelet count result resulted in the corrected platelet count.Conclusion By using blood smear microscopy to calculate platelet aggregation rate,platelet aggregation quantity,and platelet aggregation pile number,three parameters could be effectively corrected for false decrease in platelet count caused by platelet aggregation,achieving accurate platelet count-ing.The operation is simple,economical,and has good clinical and grassroots application value.