Objective:To explore the influencing factors of absorption effect postoperative ablation area after microwave ablation(MWA)for papillary thyroid microcarcinoma(PTMC).Methods:The clinical and ultrasound data of 101 patients with single PTMC who underwent microwave ablation in Beijing Friendship Hospital between April 2019 and July 2023 were collected.According to the endpoint event of whether the ablation area disappeared one year after MWA,they were divided into disappearance group(52 cases)and non-disappearance group(49 cases).Univariate and multivariate logistic regression were used to analyze the factors of affecting the absorption effect of ablation area,and a regression model was constructed.Receiver operating characteristic(ROC)curve was drawn to test the predictive efficacy of the model.Results:There were significant differences in the age,coarse calcification in the nodule,ablation time,Hashimoto's thyroiditis between two groups(x2=4.708,12.180,19.497,8.457,P<0.05),respectively.There were also significant differences in maximum diameter of nodule,nodule volume,ablation energy between two groups(Z=-3.929,-3.969,-3.677,P<0.05).Multivariate logistic regression analysis showed that age≥50 years old,coarse calcification in the nodule,ablation time≥50s,and Hashimoto's thyroiditis were independent influencing factors for the non-disappearance of ablation area one year after MWA for PTMC(OR=4.464,3.733,10.063,4.173,P<0.05).The ROC curve analysis showed that the area under curve(AUC)of the regression model in predicting non-disappearance of ablation area after MWA for PTMC was 0.853(95%CI:0.777-0.929),and the diagnostic sensitivity and specificity of that were respectively 75.5%and 82.7%.Conclusion:The logistic regression model,that is constructed on the basis of clinical information,preoperative ultrasound features,and thermal ablation parameters,has high clinical application value in predicting the postoperative absorption of the ablation area in patients who undergo MWA for PTMC.

OBJECTIVE To investigate the acute lung injury effects of pulmonary phospholipids and their phospholipase A2(PLA2)decomposition products-lysophospholipids and fatty acids-on mice.METHODS Mice were randomly assigned to the following groups:① solvent control(PBS)and PLA2;② solvent control and glycerol phospholipid groups:1,2-dioleoyl-sn-glycero-3-phosphoserine(DOPS),1,2-dipalmitoyl-sn-glycero-3-phosphoserine(DPPS),1,2-dioleoyl-sn-glycero-3-phosphoethanol-amine(DOPE),1,2-dipalmitoyl-sn-glycero-3-phosphoethanolamine(DPPE),1,2-dipalmitoyl-sn-glycero-3-phosphocholine(DPPC),and 1-stearoyl-2-oleoyl-sn-glycero-3-phosphocholine(SOPC);③ solvent con-trol and fatty acid groups:palmitic acid(PA),oleic acid;④ solvent control and lysophospholipid groups:1-oleoyl-2-hydroxy-sn-glycero-3-phosphoserine(18∶1 LysoPS),1-stearoyl-sn-glycero-3-phosphoserine(18∶0 LysoPS),1-palmitoyl-sn-glycero-3-phosphoserine(16∶0 LysoPS),1-palmitoyl-sn-glycero-3-phos-phoethanolamine(16∶0 LysoPE),1-palmitoyl-sn-glycero-3-phosphocholine(16∶0 LysoPC);⑤ solvent control,PLA2,DPPC,PA,16∶0 LysoPC,16∶0 LysoPS,and 18∶1 LysoPS.Following anesthesia,mice were administered nebulized PBS in the solvent control group,2.1 ug·kg-1 PLA2 in PBS in the PLA2 group and 2.5 mg·kg-1 of the corresponding substance in PBS in other experimental groups.For group①,survival times were recorded and survival curves were plotted.At 1 h post-treatment,lung tissues from groups ①②③④ were collected,photographed to obtain white light images,and subjected to HE staining to assess histopathological changes and pathological scoring.At 2 h post-treatment,pulmonary blood flow in group ⑤ was assessed using laser speckle contrast imaging,arterial blood gas was analyzed with a blood gas analyzer,and lung function was evaluated using whole-body pleth-ysmography.At 6 hours post-treatment,blood cells from group ⑤ were analyzed using an automated hematology analyzer.RESULTS Compared with the solvent control group,severe pathological changes were observed in lung tissues of the PLA2 group,accompanied by extensive inflammatory infiltration and interstitial thickening,with all mice succumbing within 240 min.In mice treated with glyc-erol phospholipids,alveolar structures remained clear,alveolar walls were intact and continuous,and alveolar spaces were translucent,with only occasional minor inflammatory cell infiltration in the septa.No significant pathological alterations were detected in the fatty acid groups.Minor inflammatory cell infiltration was seen in the 16∶0 LysoPE and 16∶0 LysoPC groups.However,such pathological changes as patchy hemorrhage,alveolar interstitial edema,increased alveolar wall thickness,and elevated neutrophil counts were observed in the 18∶1 LysoPS,18∶0 LysoPS,and 16∶0 LysoPS groups.Pathological scores based on HE staining were significantly increased in the 16∶0 LysoPS and 18∶1 LysoPS groups com-pared with the solvent control.The percentage of the lung tissue injury area was also markedly higher in the 16∶0 LysoPS group.A significant decrease in the mean fluorescence intensity of blood flow was observed in the 16∶0 LysoPS group.Arterial partial pressure of oxygen(pO2)was significantly reduced in the PLA2 group,while arterial partial pressure of carbon dioxide(pCO2)was markedly elevated in the 16∶0 LysoPS and 18∶1 LysoPS groups.Lung function tests revealed that the 16∶0 LysoPS group exhibited significant increases in expiratory time,end-expiratory pressure,and enhanced pause,in contrast to significant decreases in tidal volume,expired volume,and minute volume.The 18∶1 LysoPS group also exhibited a significant decline in minute volume.No significant changes in inflammatory cell concentrations were detected in blood,with the exception of neutrophils in the 16∶0 LysoPS group,which showed a significant but physiologically normal increase.CONCLUSION Pulmonary phospholipids and their PLA2-derived fatty acid metabolites do not induce severe lung injury in mice while the lyso-phospholipid metabolites,particularly lysophosphatidylserine,are found to cause significant lung injury.

OBJECTIVE To construct novel central nervous system(CNS)-targeted lipid nanoparti-cles for the treatment of organophosphorus-induced brain injury in mice.METHODS(1)Preparation,screening,and characterization of lipid nanoparticles.① Lipid nanoreactivators were prepared using the thin-film hydration method,with asoxime(HI-6)as the therapeutic drug and lipid carriers composed of 1-palmitoyl-2-oleoyl-sn-glycero-3-phospho-L-serine(POPS),1,2-dipalmitoyl-sn-glycero-3-phospho-choline(DPPC),and cholesterol(CHOL)(PDC)at varying molar ratios(1∶6∶3,3∶4∶3,5∶2∶3 and 7∶0∶3)(HI-6@PDC 1∶6∶3,3∶4∶3,5∶2∶3 and 7∶0∶3).② FLU-labeled lipid nanocarriers(FLU@PDC 1∶6∶3,3∶4∶3,5∶2∶3,and 7∶0∶3)were prepared and physically mixed with phospholipase A2(PLA2)solution(at the final PLA2 concentration of 10 kU·L-1)to obtain FLU@PDC+PLA2.Male KM mice were randomly divided into normal control(PBS),FLU,and FLU@PDC+PLA2(1∶6∶3,3∶4∶3,5∶2∶3,and 7∶0∶3)groups(n=7 per group).After intravenous(iv)administration(FLU dose:1 mg·kg-1,carrier dose:80 mg·kg-1),brain tissues were collected at 1 h,homogenized,centrifuged,and analyzed via fluorescence spectrophotom-etry to screen the optimal CNS-targeted lipid carrier composition.③ The morphology of HI-6@PDC 5∶2∶3 was characterized by transmission electron microscope(TEM).The particle size,polydispersity index(PDI),and zeta potential of HI-6@PDC 5∶2∶3 were measured using a Zeta potential and particle size analyzer.Encapsulation efficiency and loading efficiency of HI-6@PDC 5∶2∶3 were determined using an ultrafiltration centrifugation method combined with high-performance liquid chromatography(HPLC).In vitro release kinetics of HI-6@PDC 5∶2∶3 and HI-6@PDC+PLA2 5∶2∶3 were assessed using a dialysis bag diffusion method combined with fluorescence spectrophotometry.(2)Validation of CNS targeting.① Cyanine7(Cy7)-labeled PDC 5∶2∶3(Cy7@PDC)was prepared and mixed with PLA2 solution(Cy7@PDC+PLA2 5∶2∶3).Mice were divided into normal control,Cy7,Cy7@PDC 5∶2∶3 and Cy7@PDC+PLA2 5∶2∶3 groups(n=3 per group).After iv injection(Cy7 dose:1 mg·kg-1,carrier dose:80 mg·kg-1),brain fluorescence was visualized at 3 h using a small animal in vivo imaging(IVIS)system.② Cyanine 3(Cy3)-labeled PDC 5∶2∶3(Cy3@PDC 5∶2∶3)was prepared and mixed with PLA2 solution(Cy3@PDC+PLA2 5∶2∶3).Mice were divided into Cy3@PDC 5∶2∶3 and Cy3@PDC+PLA2 5∶2∶3 groups(n=3 per group).After iv injection(Cy3 dose:1 mg·kg-1,carrier dose:80 mg·kg-1),brain tissues were collected at 2 h for fluorescent staining and Cy3 fluorescence observation.(3)Therapeutic efficacy eval-uation.① Male KM mice were randomly divided into normal control,brain injury,HI-6 treatment,and HI-6@PDC+PLA2 5∶2∶3 treatment groups(n=6 per group).Except for the normal control,all the mice were subcutaneously(sc)injected with soman(120 μg·kg-1),followed by immediate iv treatment(HI-6 dose:22 mg·kg-1,carrier dose:80 mg·kg-1).At 10 min,orbital blood and brain tissues were collected before brain weight was recorded.Acetylcholinesterase(AChE)reactivation in blood and brain was measured using the Ellman method.② Grouping and treatment were identical to ①(n=3 per group).At 24 h,brain tissues were collected for HE staining to assess histopathological damage.③ Mice were divided into brain injury and HI-6@PDC+PLA2 5∶2∶3 treatment groups(n=10 per group)and treated as in ①(soman dose:220 ug·kg-1).Survival rates,neurotoxic symptoms(tremors,salivation),and seizure latency were recorded,and survival curves were plotted.RESULTS(1)PDC 5∶2∶3 exhibited the highest brain fluorescence,indicating optimal CNS targeting.HI-6@PDC 5∶2∶3 appeared in regular spherical shapes,and were negatively charged,with a size of(219.4±3.1)nm,PDI of 0.4±0.02,entrapment effi-ciency of 72.9％and loading efficiency of 49.7％.HI-6@PDC+PLA2 5∶2∶3 showed a cumulative release of 43.5％at 60 min,which was lower than that of rhodamine B(RB)but sufficient for CNS therapeutic timelines.(2)In vivo fluorescence and pathological fluorescence confirmed PLA2-mediated CNS delivery.(3)HI-6@PDC+PLA2 5∶2∶3 significantly enhanced AChE reactivation in the blood and brain compared to HI-6.Histopathology revealed mitigated brain injury in treated mice.HI-6@PDC+PLA2 5∶2∶3 prolonged survival,reduced convulsions,alleviated neurotoxicity,and extended seizure latency.CONCLUSION HI-6@PDC 5∶2∶3 can effectively cross the blood-brain barrier via PLA2 mediation,demonstrating strong CNS targeting.It can significantly improve AChE reactivation in peripheral and central tissues and offers potent therapeutic efficacy against organophosphate-induced brain injury.

OBJECTIVE To construct novel central nervous system(CNS)-targeted lipid nanoparti-cles for the treatment of organophosphorus-induced brain injury in mice.METHODS(1)Preparation,screening,and characterization of lipid nanoparticles.① Lipid nanoreactivators were prepared using the thin-film hydration method,with asoxime(HI-6)as the therapeutic drug and lipid carriers composed of 1-palmitoyl-2-oleoyl-sn-glycero-3-phospho-L-serine(POPS),1,2-dipalmitoyl-sn-glycero-3-phospho-choline(DPPC),and cholesterol(CHOL)(PDC)at varying molar ratios(1∶6∶3,3∶4∶3,5∶2∶3 and 7∶0∶3)(HI-6@PDC 1∶6∶3,3∶4∶3,5∶2∶3 and 7∶0∶3).② FLU-labeled lipid nanocarriers(FLU@PDC 1∶6∶3,3∶4∶3,5∶2∶3,and 7∶0∶3)were prepared and physically mixed with phospholipase A2(PLA2)solution(at the final PLA2 concentration of 10 kU·L-1)to obtain FLU@PDC+PLA2.Male KM mice were randomly divided into normal control(PBS),FLU,and FLU@PDC+PLA2(1∶6∶3,3∶4∶3,5∶2∶3,and 7∶0∶3)groups(n=7 per group).After intravenous(iv)administration(FLU dose:1 mg·kg-1,carrier dose:80 mg·kg-1),brain tissues were collected at 1 h,homogenized,centrifuged,and analyzed via fluorescence spectrophotom-etry to screen the optimal CNS-targeted lipid carrier composition.③ The morphology of HI-6@PDC 5∶2∶3 was characterized by transmission electron microscope(TEM).The particle size,polydispersity index(PDI),and zeta potential of HI-6@PDC 5∶2∶3 were measured using a Zeta potential and particle size analyzer.Encapsulation efficiency and loading efficiency of HI-6@PDC 5∶2∶3 were determined using an ultrafiltration centrifugation method combined with high-performance liquid chromatography(HPLC).In vitro release kinetics of HI-6@PDC 5∶2∶3 and HI-6@PDC+PLA2 5∶2∶3 were assessed using a dialysis bag diffusion method combined with fluorescence spectrophotometry.(2)Validation of CNS targeting.① Cyanine7(Cy7)-labeled PDC 5∶2∶3(Cy7@PDC)was prepared and mixed with PLA2 solution(Cy7@PDC+PLA2 5∶2∶3).Mice were divided into normal control,Cy7,Cy7@PDC 5∶2∶3 and Cy7@PDC+PLA2 5∶2∶3 groups(n=3 per group).After iv injection(Cy7 dose:1 mg·kg-1,carrier dose:80 mg·kg-1),brain fluorescence was visualized at 3 h using a small animal in vivo imaging(IVIS)system.② Cyanine 3(Cy3)-labeled PDC 5∶2∶3(Cy3@PDC 5∶2∶3)was prepared and mixed with PLA2 solution(Cy3@PDC+PLA2 5∶2∶3).Mice were divided into Cy3@PDC 5∶2∶3 and Cy3@PDC+PLA2 5∶2∶3 groups(n=3 per group).After iv injection(Cy3 dose:1 mg·kg-1,carrier dose:80 mg·kg-1),brain tissues were collected at 2 h for fluorescent staining and Cy3 fluorescence observation.(3)Therapeutic efficacy eval-uation.① Male KM mice were randomly divided into normal control,brain injury,HI-6 treatment,and HI-6@PDC+PLA2 5∶2∶3 treatment groups(n=6 per group).Except for the normal control,all the mice were subcutaneously(sc)injected with soman(120 μg·kg-1),followed by immediate iv treatment(HI-6 dose:22 mg·kg-1,carrier dose:80 mg·kg-1).At 10 min,orbital blood and brain tissues were collected before brain weight was recorded.Acetylcholinesterase(AChE)reactivation in blood and brain was measured using the Ellman method.② Grouping and treatment were identical to ①(n=3 per group).At 24 h,brain tissues were collected for HE staining to assess histopathological damage.③ Mice were divided into brain injury and HI-6@PDC+PLA2 5∶2∶3 treatment groups(n=10 per group)and treated as in ①(soman dose:220 ug·kg-1).Survival rates,neurotoxic symptoms(tremors,salivation),and seizure latency were recorded,and survival curves were plotted.RESULTS(1)PDC 5∶2∶3 exhibited the highest brain fluorescence,indicating optimal CNS targeting.HI-6@PDC 5∶2∶3 appeared in regular spherical shapes,and were negatively charged,with a size of(219.4±3.1)nm,PDI of 0.4±0.02,entrapment effi-ciency of 72.9％and loading efficiency of 49.7％.HI-6@PDC+PLA2 5∶2∶3 showed a cumulative release of 43.5％at 60 min,which was lower than that of rhodamine B(RB)but sufficient for CNS therapeutic timelines.(2)In vivo fluorescence and pathological fluorescence confirmed PLA2-mediated CNS delivery.(3)HI-6@PDC+PLA2 5∶2∶3 significantly enhanced AChE reactivation in the blood and brain compared to HI-6.Histopathology revealed mitigated brain injury in treated mice.HI-6@PDC+PLA2 5∶2∶3 prolonged survival,reduced convulsions,alleviated neurotoxicity,and extended seizure latency.CONCLUSION HI-6@PDC 5∶2∶3 can effectively cross the blood-brain barrier via PLA2 mediation,demonstrating strong CNS targeting.It can significantly improve AChE reactivation in peripheral and central tissues and offers potent therapeutic efficacy against organophosphate-induced brain injury.

Objective To investigate the cellular characteristics in the development of retinal tumors induced by MY-CN overexpression,and to find the key proteins that play an important role in this process.Methods T-MYCN Y1 and Y2 cells cultured in vitro for 1 year and 2 years were selected for the experiment.The WERI-RB-1 cell line obtained from Shanghai Cell Bank of Chinese Academy of Sciences was taken as the mature retinoblastoma(RB)control(WERI-Rb-1 group).Untreated normal human retinal tissues were used as the control group.Cells were inoculated into a 24-well plate at a density of 1 × 104 cells per well,and the cell morphology was observed under a microscope and images were collected.Cell count was performed on the 4th,8th and 12th day after inoculation.Immunofluorescence staining was employed to de-tect the expression of the proliferation marker Ki67 and cone cell marker L/M opsin in each group.Quantitative real time polymerase chain reaction(qRT-PCR)was utilized to assess the expression of MYCN,CCNB1,CDK1,SYK,and RXRγ in cells across all groups.Proteomics analysis was performed to detect variations in protein expression profiles across groups and to identify key regulatory genes.Subsequently,cell growth and proliferation were evaluated after OTX2 knockdown by lentiviruses.Results The growth curve showed that there were(59.17±4.01)× 104 cells in the T-MYCN Y1 group,(85.14±4.54)× 104 cells in the T-MYCN Y2 group and(100.73±1.99)× 104 cells in the WERI-Rb-1 group on the 12th day of in-vitro culture(all P＜0.05).Compared with those in the control group,the positive cell rates of Ki67 and L/M opsin increased in T-MYCN Y1,T-MYCN Y2 and WERI-Rb-1 groups(all P＜0.001).The relative expression levels of MYCN mR-NAs in T-MYCN Y1,T-MYCN Y2 and WERI-Rb-1 groups were significantly higher than those in the control group(all P＜0.001).The relative expression levels of CCNB1 and CDK1 mRNAs also increased significantly in the three groups,com-pared with those in the control group(all P＜0.01).There was no significant difference in the relative expression of SYK mRNAs between T-MYCN Y1 and control groups(P＞0.05).The relative expression level of RXRγ mRNAs was significantly higher in the T-MYCN Y1 group than that in the control group(P＜0.05).The relative expression levels of SYK and RXRγmRNAs in T-MYCN Y2 and WERI-Rb-1 groups were significantly increased,compared with those in the control group(all P＜0.05).GO enrichment analysis showed that these differentially-expressed proteins were enriched into protein complex assembly and mitochondria pathways.KEGG enrichment analysis revealed that the enriched pathways of these differential-ly-expressed proteins included carbon metabolism,metabolic pathway and fatty acid degradation.Both proteomics and Western blot analyses indicated that OTX2 expression levels were the highest in the WERI-Rb-1 group,second highest in the T-MYCN Y2 group,and the lowest in the T-MYCN Y1 group(all P＜0.01).According to qRT-PCR,the expression levels of OTX2 mRNAs in T-MYCN Y1,T-MYCN Y2 and WRI-Rb-1 cells with OTX2 knockdown were lower than those in empty vec-tor controls(all P＜0.05).The growth curve of cells showed that after knocking down OTX2 in the three groups of cells,both cell growth and proliferation ability decreased significantly(all P＜0.001).Conclusion During the development of retinal tumors induced by MYCN overexpression,cells gradually exhibit characteristics similar to WERI-Rb-1 cells,which are a typical RB cell line.OTX2 plays an important role in MYCN amplification or the growth and proliferation of highly ex-pressed RB.Targeting OTX2 may become a new research direction for the treatment of RB.

The biliary microbiota is an important component of the biliary system, the structure changes and dysbiosis of the biliary microbiota are closely related to the occurrence and development of biliary diseases. Recent studies have found that the dysbiosis of the biliary microbiota can lead to the occurrence of various biliary diseases such as cholelithiasis, cholangitis, and biliary tract cancer. However, the specific mechanisms of some of these diseases remain unclear. In addition, the alternation of biliary microbiota may also lead to the occurrence of postoperative complications of biliary diseases, such as the risk of infection increased after laparoscopic cholecystectomy (LC) and endoscopic retrograde cholangiopancreatography (ERCP). Although some studies have begun to explore the connection between biliary microbiota and biliary diseases, most research have mainly focused on a single disease type or specific microorganisms. There has been no comprehensive and systematic review of the overall changes in biliary microbiota across different diseases and their association with post biliary surgery infection.Therefore, this article presents a systematic review of current advances linking the alternations of biliary microbiota to the development of biliary diseases and their postoperative infections, as well as the changes in the biliary microbiota before and after various biliary diseases and their surgeries, aiming to provide insightful methods for the early diagnosis, prevention and treatment of biliary diseases and management of postoperative infections.

Mechanical pain is one of the most common causes of clinical pain, but there remains a lack of effective treatment for debilitating mechanical and chronic forms of neuropathic pain. Recently, neurotoxin GsMTx4, a selective mechanosensitive (MS) channel inhibitor, has been found to be effective, while the underlying mechanism remains elusive. Here, with multiple rodent pain models, we demonstrated that a GsMTx4-based 17-residue peptide, which we call P10581, was able to reduce mechanical hyperalgesia and neuropathic pain. The analgesic effects of P10581 can be as strong as morphine but is not toxic in animal models. The anti-hyperalgesic effect of the peptide was resistant to naloxone (an μ-opioid receptor antagonist) and showed no side effects of morphine, including tolerance, motor impairment, and conditioned place preference. Pharmacological inhibition of TRPV4 by P10581 in a heterogeneous expression system, combined with the use of Trpv4 knockout mice indicates that TRPV4 channels may act as the potential target for the analgesic effect of P10581. Our study identified a potential drug for curing mechanical pain and exposed its mechanism.

BACKGROUND: Concurrent chemo-radiotherapy (CCRT) is the standard treatment for locally advanced cervical cancer (LACC), but there are still many patients who suffer tumor recurrence. However, valuable predictors of treatment outcomes remain limited. This study aimed to assess the value of the serum immune biomarkers to predict the prognosis. METHODS: We reviewed cervical cancer patients treated with CCRT between January 2014 and May 2018 at Peking Union Medical College Hospital. The systemic immune inflammation index (SII), systemic inflammation response index (SIRI), and lactate dehydrogenase (LDH) were calculated using blood samples. The relationship between immune markers and the treatment outcome was analyzed. The area under the receiver operating characteristic (ROC) curve was used to evaluate the predictive efficiency. The Cox proportional hazards model and log-rank were used to predict overall survival (OS) and disease-free survival (DFS). RESULTS: This study included 667 patients. Among them, 195 (29.2%) patients were defined as treatment failure, including 127 (19.0%) patients with pelvic failure, 94 (14.1%) distant failure, and 25 (3.7%) concurrent pelvic and distant failure. It revealed that the tumor stage, size, metastatic lymph nodes (MLNs), and serum immune biomarkers, such as SII, SIRI, and LDH, were significantly related to treatment outcomes. We demonstrated that the optimal cut-off of the SII, SIRI, and LDH were 970.4 × 10 9 /L, 1.3 × 10 9 /L, and 207.52 U/L, respectively. Importantly, this study presented that LDH level had the highest OR (OR = 4.2; 95% CI [2.3-10.8]). Furthermore, the OS and DFS for patients with pre-SII ≥970.5 × 10 9 /L were significantly worse than those with pre-SII <970.5 × 10 9 /L. Similarly, pre-SIRI ≥1.25 × 10 9 /L and pre-LDH ≥207.5 U/L were related to poor survival outcomes. CONCLUSIONS This study demonstrated that the baseline SII, SIRI, and LDH levels can be used to accurately and effectively predict the treatment outcomes after CCRT and long-term prognosis. Our results may offer additional prognostic information in clinical, which helps to detect the potential recurrent metastasis in time.
Humans ; Female ; Uterine Cervical Neoplasms/drug therapy* ; Middle Aged ; Adult ; Aged ; Chemoradiotherapy/methods* ; L-Lactate Dehydrogenase/blood* ; Treatment Outcome ; Disease-Free Survival ; Prognosis ; ROC Curve ; Biomarkers, Tumor/blood* ; Proportional Hazards Models

ObjectiveTo investigate the pharmacodynamic effects of Houshihei San （HSHS） recorded with the effects of treating wind and limb heaviness on muscle tissue injury after middle cerebral artery occlusion （MCAO） in rats through the ferroptosis pathway. MethodsThirty SD male rats were selected and randomly grouped as follows： sham， MCAO， deferoxamine mesylate， high-dose HSHS （HSHS-H， 0.54 g·kg^-1）， and low-dose HSHS （HSHS-L， 0.27 g·kg^-1）， with 6 rats in each group. A laser scattering system was used to evaluate the stability of the MCAO model， and rats were administrated with corresponding agents by gavage for 7 days. During the administration period， behavioral， imaging and other methods were used to systematically evaluate the skeletal muscle tissue injury after MCAO and the therapeutic effect in each administration group. Hematoxylin-eosin staining was employed to evaluate the cross-section of muscle cells. Subsequently， immunohistochemistry was used to detect tumor suppressor p53 and glutathione peroxidase 4 （GPX4） in the soleus tissue. Western blot was employed to determine the protein levels of p53， GPX4， myogenic differentiation 1 （MyoD1）， nuclear factor E₂-related factor 2 （Nrf2）， Myostatin， solute carrier family 7 member 11 （SLC7A11）， muscle ring-finger protein-1 （MuRF1）， and muscle atrophy F-box protein （MAFbx） to verify the therapeutic effect in each group. ResultsCompared with the MCAO group， HSHS enhanced the locomotor ability and promoted muscle regeneration， which suggested that the pharmacological effects of HSHS were related to the inhibition of muscle tissue ferroptosis to reduce the expression of muscle atrophy factors. Behavioral and imaging results suggested that compared with the MCAO group， HSHS ameliorated neurological impairments in rats on day 7 （P<0.01）， enhanced 5-min locomotor distance and postural control （P<0.01）， strengthened grasping power and promoted muscle growth （P<0.01）， stabilized skeletal muscle length and weight （P<0.01）， and increased the cross-section of muscle cells （P<0.01）. Compared with the MCAO group， HSHS promoted the increases in glutathione and superoxide dismutase content and inhibited the increase in malondialdehyde content （P<0.05，P<0.01）. Ferroptosis pathway-related assays suggested that HSHS reduced the p53-positive cells and increased the GPX4-positive cells （P<0.01）. HSHS ameliorated muscle function decline after stroke by promoting the expression of GPX4， Nrf2， SLC7A11， and MyoD1 and inhibiting the expression of p53， Myostatin， MurRF1， and MAFbx to reduce ferroptosis in the muscle （P<0.01）. ConclusionHSHS， prepared with reference to the method in the Synopsis of Golden Chamber， can simultaneously reduce the myolysis and increase the protein synthesis in the skeletal muscle tissue after ischemic stroke by regulating the ferroptosis pathway.