As a physical treatment technique, modified electro-convulsive therapy (MECT) is used to treat mental and certain neurological disorders by causing seizures with short, suitable electrical currents applied to the brain while the patient is under general anesthesia and muscle relaxants. MECT is recognized for its therapeutic efficacy and clinical safety, rendering it one of the most prevalent interventions in psychiatric care. To enhance clinical outcomes and minimize adverse effects, this consensus document delineates the indications, therapeutic parameters, therapeutic procedures, potential adverse effects, and associated management strategies for MECT. These guidelines are informed by the latest clinical research and expert consensus, integrating evidence-based medicine methodologies. The objective is to furnish clinicians with precise operational guidelines and to advance the standardization of MECT practices in clinical settings.

Objective To explore the impact of ten-eleven translocation 2(TET2)mutations on imiquimod(IMQ)-induced psoriatic skin inflammation using a TET2-knockout(TET2-/-)mouse model.Methods Mice were divided randomly into a wild-type(WT)vaseline group,WT imiquimod group,TET2-/-vaseline group,and TET2-/-imiquimod group.IMQ was used to establish a psoriasis-like dermatitis model,and the degree of skin lesions and pathological changes in mice in the WT imiquimod and TET2-/-imiquimod groups were observed and compared daily during the modeling period.The mice were sacrificed when the phenotype had reached the peak and the spleen index was recorded in each group.Gene expression levels of the inflammatory factors tumor necrosis factor(TNF)-α,interleukin(IL)-6,IL-17A,and IL-23 in mouse back lesions were detected by quantitative reverse transcription polymerase chain reaction.Skin histopathology was compared in hematoxylin/eosin-stained sections.IL-17,interferon(INF)-γ,and TNF-α protein expression levels in the back skin of mice in the four groups were detected by immunohistochemistry.The ultrastructure of the dermis and epidermis was observed using transmission electron microscopy.Results TET2 expression was down-regulated in skin lesions in WT imiquimod group.Dermatitis lesions were more severe and progressed faster in TET2-/-imiquimod group compared with WT imiquimod group,and the psoriasis area and severity index score and spleen index were both higher.mRNA expression levels of TNF-α,IL-6,IL-17A,and IL-23 in skin lesions were higher and epidermal thickening and inflammatory cell infiltration were increased,and protein expression levels of IL-17,INF-γ,and TNF-α were significantly higher in skin lesions in TET2-/-imiquimod group compared with WT imiquimod group.In addition,cell junctions were absent in skin lesions in TET2-/-imiquimod group and mitochondrial ridges were broken and dissolved,mitochondrial vacuoles were present,and the texture of the mitochondrial membrane was darker.Conclusions Loss of TET2 promotes the inflammatory response and exacerbates IMQ-induced psoriasis-like dermatitis injury in mice.

Metastasis is a pivotal and intricate process in the progression of malignant tumors,strongly correlating with poor prognosis.Approximately 90%of cancer-related mortality is attributed to metastasis,with the five-year survival rate for patients with metastatic solid tumors ranging from 5%to 30%.Consequently,a comprehensive understanding of the underlying biological mechanisms driving metastasis is essential for unraveling its core processes and developing novel therapeutic strategies.The metastatic cascade involves tumor cells navigating numerous biological barriers,including detachment from the primary tumor,invasion of blood vessels or lymphatics,survival in circulation,extravasation into distant organs and subsequent adaptation to the microenvironment.To surmount these challenges,tumor cells undergo phenotypic changes,genetic mutations and dysregulating signaling pathways.Additionally,microenvironmental factors(such as angiogenesis,matrix remodeling and immune evasion)play a critical role,orchestrating the initiation and growth of metastatic lesions in an interdependent manner.Organ-specific metastasis,a distinct subset of metastasis,involves dynamic bidirectional interactions between tumor cells and the microenvironment of target organs.These interactions determine the selectivity of metastatic spread and drive the adaptive evolution of both the tumor and the organ,which encompasses multiple layers of cellular interactions,including cell-cell and cell-matrix signaling.Tumor cell mutations,the release of specific signaling molecules,the capacity to withstand circulatory pressures,and signaling exchanges with target organs collectively govern the selective nature of organ-specific metastasis.Furthermore,factors intrinsic to the target organ-such as its regenerative potential,metabolic profile,immune surveillance mechanisms and matrix stiffness-further facilitate the adaptive remodeling of metastatic cells within these environments.Thus,the bidirectional selection and adaptation between tumor cells and target organs form a dynamic,complex system that reshapes our understanding of metastatic tumor development.While current research emphasizes shared biological features in metastasis,the successful formation of metastatic tumors depends not only on these common mechanisms but also on the unique characteristics governing organ-specific metastasis.The interplay between generalizable and organ-specific mechanisms profoundly influences the metastatic outcome.This review aimed to consolidate our current knowledge of these shared and distinct processes,analyze the evolving understanding of the bidirectional selection between tumor cells and target organs,and assess the current status of metastatic risk prediction models for patients without metastasis.Furthermore,the paper discussed the challenges and opportunities in managing advanced-stage metastatic tumors,offering new insights and potential clinical strategies to improve prognosis and treatment outcomes.

Objective To elucidate the molecular mechanisms underlying the effects of Kanggan Mixture(KGM)on key targets in rats with acute lung injury,network pharmacology and in vivo micro-CT experiments were employed.Methods Network pharmacology was utilized to forecast the target genes and principal pathways involved in the intervention of KGM in acute lung injury(ALI).Lipopolysaccharide(LPS)-induced ALI rat models were utilized,and micro-computed tomography(micro-CT)was employed to evaluate the extent of lung injury in vivo.Experiments were conducted to verify the intervention mechanism of KGM on ALI rats.Results The findings revealed that 190 chemical constituents were identified from KGM,and 579 potential targets and 204 pathways associated with KGM's impact on ALI were predicted.The principal components of KGM,such as quercetin,luteolin,kaempferol,betulin,and lupenone,exhibit anti-viral,anti-inflammatory,and immunomodulatory properties by targeting TP53,AKT1,SRC,EP300,and STAT3,and modulating the FoxO signaling pathway,TNF signaling pathway,PI3K-Akt signaling pathway,and MAPK signaling pathway,demonstrating an influence on acute lung injury.Micro-CT results suggest that KGM can improve lung texture enhancement and lung injury in ALI rats,with an increase in end-expiratory lung volume(inspiratory phase-expiratory phase).The HE and W/D ratio results indicate that KGM can improve lung tissue injury and reduce the lung tissue wet/dry weight ratio(P<0.01).Blood cell analysis results show that the anti-inflammatory agent can decrease the WBC(white blood cell count)and N%(neutrophil percentage)in ALI rats'blood(P<0.01),and increase lymphocytes(P<0.05).Real-time quantitative PCR,WES,and immunohistochemistry results suggest that KGM can decrease the mRNA expression,protein distribution,and protein expression levels of TP53,AKT1,SRC,EP300,and STAT3 in lung tissue of ALI rats(P<0.05).Conclusion KGM has a certain intervention effect on acute lung injury,mainly achieved through the core targets STAT3,EP300,SRC,AKT1,and TP53.

Retinitis pigmentosa (RP) is a kind of ophthalmic hereditary disease characterized by degenerative dystrophy of photoreceptors in the retina.It is one of the main causes of hereditary visual impairment and blindness. USH2A gene is the primary pathogenic gene of both syndromic RP (e.g., Usher syndrome type Ⅱ, USH2) and non-syndromic RP, so elucidating its function and pathogenesis is of important theoretical significance and clinical application value.However, due to the wide range of USH2A gene variations, as well as USH2A protein has huge molecular weight and complex protein structure, the molecular pathogenesis of RP caused by USH2A variations remains unknown, which has hindered the progress of gene therapy and also poses many challenges to researchers and clinicians.Recently, with the development of gene editing technology and the establishment of animal models, the function of USH2A gene has been further studied.For example, USH2A is involved in cell adhesion at retinal basal membrane.USH2A interacts with other USH proteins to maintain photoreceptor structure and plasticity.USH2A can participate in vesicle transport from the inner segment to the outer segment of photoreceptors.USH2A maintains the normal function of photoreceptor cells by regulating autophagy.This article reviews the pathogenesis of RP induced by variations of USH2A gene.

Objective To investigate the effects of galectin-3(Gal3)on autophagy in high glucose-induced human telomerase reverse transcriptase-immortalized retinal pigment epithelial(hTERT-RPE)cells.Methods The hTERT-RPE cells cultured in vitro were randomly divided into a normal group(group C),a high glucose group(group HG),a high glu-cose+si-NC group(group HG+si-NC)and a high glucose+si-Gal3 group(group HG+si-Gal3).Reverse transcrip-tion polymerase chain reaction(RT-PCR)was used to detect the relative mRNA expression levels of Gal3,intercellular ad-hesion molecule(ICAM)-1,interleukin(IL)-6 and tumor necrosis factor(TNF)-α in hTERT-RPE cells of each group.The expression levels of IL-1 and IL-6 in the supernatant of hTERT-RPE cells were measured by enzyme-linked immunosorbent assay(ELISA).The expression level of reactive oxygen species(ROS),the activity of superoxide dismutase(SOD)and the content of malondialdehyde(MDA)in hTERT-RPE cells were analyzed by dichlorofluorescin diacetate(DCFH-DA)staining,the colorimetric method and the microplate method,respectively.The protein expression levels of Gal3,the ratio of microtubule associated protein 1 light chain 3(LC3)type Ⅱ to type Ⅰ(LC3 Ⅱ/LC3 Ⅰ),Beclin 1,and autophagy-associat-ed 5(ATG5)and 7(ATG7)in hTERT-RPE cells from each group were detected by Western blot analysis.After the hTERT-RPE cells in each group were transfected with double fluorescent mRFP-GFP-LC3 plasmids alone and with RFP-LAMP1 and GFP-LC3 plasmids jointly,the changes of autophagy flow in hTERT-RPE cells were detected by laser confocal microscopy.Results Compared with the group C,the group HG showed an increase in the expression of Gal3,IL-1,IL-6,TNF-α,ICAM-1,P62,ROS and MDA content(all P＜0.05).However,the expression of LC3 Ⅱ/LC3 Ⅰ,Beclin1,ATG7,ATG5,the SOD activity,and the number of red(autolysosomes)and yellow fluorescence spots(autophagosomes)of the double fluo-rescent mRFP-GFP-LC3 plasmid were all lower in the group HG than those in the group C(all P＜0.05).There was no sig-nificant difference in the number of yellow fluorescent spots(autolysosomes)co-located by RFP-LAMP1 and GFP-LC3 plas-mids between groups C and HG(P＞0.05).There were no significant differences in the expression levels of the above-mentioned indexes in hTERT-RPE cells between groups HG and HG+si-NC(all P＞0.05).The expression levels of Gal3,IL-1,IL-6,TNF-α,ICAM-1,P62,ROS and MDA content in hTERT-RPE cells of the group HG+si-Gal3 were lower than those of the group HG+si-NC(all P＜0.05).Compared with those in the group HG+si-NC,the expression levels of LC3 Ⅱ/LC3 Ⅰ,Beclin1,ATG7,ATG5,SOD activity,and the number of red and yellow fluorescent spots of the double fluo-rescent mRFP-GFP-LC3 plasmid were increased in the group HG+si-Gal3(all P＜0.05).There was no significant differ-ence in the number of yellow fluorescent spots co-located by RFP-LAMP1 and GFP-LC3 plasmids between groups HG+si-GaL3 and HG+si-NC(P＞0.05).Conclusion Gal3 is significantly elevated in hTERT-RPE cells induced by high glu-cose,resulting in impaired autophagy flow.It produces a direct regulatory effect on the formation of autophagosomes,and plays a highly active role in oxidative damage and expression of inflammatory factors in hTERT-RPE cells induced by high glucose.

Retinitis pigmentosa (RP) is a kind of ophthalmic hereditary disease characterized by degenerative dystrophy of photoreceptors in the retina.It is one of the main causes of hereditary visual impairment and blindness. USH2A gene is the primary pathogenic gene of both syndromic RP (e.g., Usher syndrome type Ⅱ, USH2) and non-syndromic RP, so elucidating its function and pathogenesis is of important theoretical significance and clinical application value.However, due to the wide range of USH2A gene variations, as well as USH2A protein has huge molecular weight and complex protein structure, the molecular pathogenesis of RP caused by USH2A variations remains unknown, which has hindered the progress of gene therapy and also poses many challenges to researchers and clinicians.Recently, with the development of gene editing technology and the establishment of animal models, the function of USH2A gene has been further studied.For example, USH2A is involved in cell adhesion at retinal basal membrane.USH2A interacts with other USH proteins to maintain photoreceptor structure and plasticity.USH2A can participate in vesicle transport from the inner segment to the outer segment of photoreceptors.USH2A maintains the normal function of photoreceptor cells by regulating autophagy.This article reviews the pathogenesis of RP induced by variations of USH2A gene.

Metastasis is a pivotal and intricate process in the progression of malignant tumors,strongly correlating with poor prognosis.Approximately 90%of cancer-related mortality is attributed to metastasis,with the five-year survival rate for patients with metastatic solid tumors ranging from 5%to 30%.Consequently,a comprehensive understanding of the underlying biological mechanisms driving metastasis is essential for unraveling its core processes and developing novel therapeutic strategies.The metastatic cascade involves tumor cells navigating numerous biological barriers,including detachment from the primary tumor,invasion of blood vessels or lymphatics,survival in circulation,extravasation into distant organs and subsequent adaptation to the microenvironment.To surmount these challenges,tumor cells undergo phenotypic changes,genetic mutations and dysregulating signaling pathways.Additionally,microenvironmental factors(such as angiogenesis,matrix remodeling and immune evasion)play a critical role,orchestrating the initiation and growth of metastatic lesions in an interdependent manner.Organ-specific metastasis,a distinct subset of metastasis,involves dynamic bidirectional interactions between tumor cells and the microenvironment of target organs.These interactions determine the selectivity of metastatic spread and drive the adaptive evolution of both the tumor and the organ,which encompasses multiple layers of cellular interactions,including cell-cell and cell-matrix signaling.Tumor cell mutations,the release of specific signaling molecules,the capacity to withstand circulatory pressures,and signaling exchanges with target organs collectively govern the selective nature of organ-specific metastasis.Furthermore,factors intrinsic to the target organ-such as its regenerative potential,metabolic profile,immune surveillance mechanisms and matrix stiffness-further facilitate the adaptive remodeling of metastatic cells within these environments.Thus,the bidirectional selection and adaptation between tumor cells and target organs form a dynamic,complex system that reshapes our understanding of metastatic tumor development.While current research emphasizes shared biological features in metastasis,the successful formation of metastatic tumors depends not only on these common mechanisms but also on the unique characteristics governing organ-specific metastasis.The interplay between generalizable and organ-specific mechanisms profoundly influences the metastatic outcome.This review aimed to consolidate our current knowledge of these shared and distinct processes,analyze the evolving understanding of the bidirectional selection between tumor cells and target organs,and assess the current status of metastatic risk prediction models for patients without metastasis.Furthermore,the paper discussed the challenges and opportunities in managing advanced-stage metastatic tumors,offering new insights and potential clinical strategies to improve prognosis and treatment outcomes.

Objective To investigate the effects of galectin-3(Gal3)on autophagy in high glucose-induced human telomerase reverse transcriptase-immortalized retinal pigment epithelial(hTERT-RPE)cells.Methods The hTERT-RPE cells cultured in vitro were randomly divided into a normal group(group C),a high glucose group(group HG),a high glu-cose+si-NC group(group HG+si-NC)and a high glucose+si-Gal3 group(group HG+si-Gal3).Reverse transcrip-tion polymerase chain reaction(RT-PCR)was used to detect the relative mRNA expression levels of Gal3,intercellular ad-hesion molecule(ICAM)-1,interleukin(IL)-6 and tumor necrosis factor(TNF)-α in hTERT-RPE cells of each group.The expression levels of IL-1 and IL-6 in the supernatant of hTERT-RPE cells were measured by enzyme-linked immunosorbent assay(ELISA).The expression level of reactive oxygen species(ROS),the activity of superoxide dismutase(SOD)and the content of malondialdehyde(MDA)in hTERT-RPE cells were analyzed by dichlorofluorescin diacetate(DCFH-DA)staining,the colorimetric method and the microplate method,respectively.The protein expression levels of Gal3,the ratio of microtubule associated protein 1 light chain 3(LC3)type Ⅱ to type Ⅰ(LC3 Ⅱ/LC3 Ⅰ),Beclin 1,and autophagy-associat-ed 5(ATG5)and 7(ATG7)in hTERT-RPE cells from each group were detected by Western blot analysis.After the hTERT-RPE cells in each group were transfected with double fluorescent mRFP-GFP-LC3 plasmids alone and with RFP-LAMP1 and GFP-LC3 plasmids jointly,the changes of autophagy flow in hTERT-RPE cells were detected by laser confocal microscopy.Results Compared with the group C,the group HG showed an increase in the expression of Gal3,IL-1,IL-6,TNF-α,ICAM-1,P62,ROS and MDA content(all P＜0.05).However,the expression of LC3 Ⅱ/LC3 Ⅰ,Beclin1,ATG7,ATG5,the SOD activity,and the number of red(autolysosomes)and yellow fluorescence spots(autophagosomes)of the double fluo-rescent mRFP-GFP-LC3 plasmid were all lower in the group HG than those in the group C(all P＜0.05).There was no sig-nificant difference in the number of yellow fluorescent spots(autolysosomes)co-located by RFP-LAMP1 and GFP-LC3 plas-mids between groups C and HG(P＞0.05).There were no significant differences in the expression levels of the above-mentioned indexes in hTERT-RPE cells between groups HG and HG+si-NC(all P＞0.05).The expression levels of Gal3,IL-1,IL-6,TNF-α,ICAM-1,P62,ROS and MDA content in hTERT-RPE cells of the group HG+si-Gal3 were lower than those of the group HG+si-NC(all P＜0.05).Compared with those in the group HG+si-NC,the expression levels of LC3 Ⅱ/LC3 Ⅰ,Beclin1,ATG7,ATG5,SOD activity,and the number of red and yellow fluorescent spots of the double fluo-rescent mRFP-GFP-LC3 plasmid were increased in the group HG+si-Gal3(all P＜0.05).There was no significant differ-ence in the number of yellow fluorescent spots co-located by RFP-LAMP1 and GFP-LC3 plasmids between groups HG+si-GaL3 and HG+si-NC(P＞0.05).Conclusion Gal3 is significantly elevated in hTERT-RPE cells induced by high glu-cose,resulting in impaired autophagy flow.It produces a direct regulatory effect on the formation of autophagosomes,and plays a highly active role in oxidative damage and expression of inflammatory factors in hTERT-RPE cells induced by high glucose.

Objective To elucidate the molecular mechanisms underlying the effects of Kanggan Mixture(KGM)on key targets in rats with acute lung injury,network pharmacology and in vivo micro-CT experiments were employed.Methods Network pharmacology was utilized to forecast the target genes and principal pathways involved in the intervention of KGM in acute lung injury(ALI).Lipopolysaccharide(LPS)-induced ALI rat models were utilized,and micro-computed tomography(micro-CT)was employed to evaluate the extent of lung injury in vivo.Experiments were conducted to verify the intervention mechanism of KGM on ALI rats.Results The findings revealed that 190 chemical constituents were identified from KGM,and 579 potential targets and 204 pathways associated with KGM's impact on ALI were predicted.The principal components of KGM,such as quercetin,luteolin,kaempferol,betulin,and lupenone,exhibit anti-viral,anti-inflammatory,and immunomodulatory properties by targeting TP53,AKT1,SRC,EP300,and STAT3,and modulating the FoxO signaling pathway,TNF signaling pathway,PI3K-Akt signaling pathway,and MAPK signaling pathway,demonstrating an influence on acute lung injury.Micro-CT results suggest that KGM can improve lung texture enhancement and lung injury in ALI rats,with an increase in end-expiratory lung volume(inspiratory phase-expiratory phase).The HE and W/D ratio results indicate that KGM can improve lung tissue injury and reduce the lung tissue wet/dry weight ratio(P<0.01).Blood cell analysis results show that the anti-inflammatory agent can decrease the WBC(white blood cell count)and N%(neutrophil percentage)in ALI rats'blood(P<0.01),and increase lymphocytes(P<0.05).Real-time quantitative PCR,WES,and immunohistochemistry results suggest that KGM can decrease the mRNA expression,protein distribution,and protein expression levels of TP53,AKT1,SRC,EP300,and STAT3 in lung tissue of ALI rats(P<0.05).Conclusion KGM has a certain intervention effect on acute lung injury,mainly achieved through the core targets STAT3,EP300,SRC,AKT1,and TP53.