Radiotherapy(RT)is a widely used cancer treatment,and the use of metal-based nano-radiotherapy sensitizers has shown promise in enhancing its efficacy.However,efficient accumulation and deep penetration of these sensi...Radiotherapy(RT)is a widely used cancer treatment,and the use of metal-based nano-radiotherapy sensitizers has shown promise in enhancing its efficacy.However,efficient accumulation and deep penetration of these sensitizers within tumors remain challenging.In this study,we present the development of bismuth/manganese biomineralized nanoparticles(Bi Mn/BSA)with multiple radiosensitizing mechanisms,including high atomic number element-mediated radiation capture,catalase-mimic oxygenation,and activation of the stimulator of interferon genes(STING)pathway.Significantly,we demonstrate that low-dose RT induces the recruitment of macrophages and subsequent upregulation of Matrix metalloproteinases(MMP)-2 and MMP-9 that degrade the extracellular matrix(ECM).This dynamic process facilitates the targeted delivery and deep penetration of Bi Mn/BSA nanoparticles within tumors,thereby enhancing the effectiveness of RT.By combining low-dose RT with Bi Mn/BSA nanoparticles,we achieved complete suppression of tumor growth in mice with excellent biocompatibility.This study provides a novel and clinically relevant strategy for targeted nanoparticle delivery to tumors,and establishes a safe and effective sequential radiotherapy approach for cancer treatment.These findings hold great promise for improving the outcomes of RT and advancing the field of nanomedicine in cancer therapy.展开更多
Chemotherapy is an important adjuvant treatment of glioma,while the efficacy is far from satisfactory,due not only to the biological barriers of blood-brain barrier(BBB)and blood-tumor barrier(BTB)but also to the intr...Chemotherapy is an important adjuvant treatment of glioma,while the efficacy is far from satisfactory,due not only to the biological barriers of blood-brain barrier(BBB)and blood-tumor barrier(BTB)but also to the intrinsic resistance of glioma cells via multiple survival mechanisms such as upregulation of P-glycoprotein(P-gp).To address these limitations,we report a bacteria-based drug delivery strategy for BBB/BTB transportation,glioma targeting,and chemo-sensitization.Bacteria selectively colonized into hypoxic tumor region and modulated tumor microenvironment,including macrophages repolarization and neutrophils infiltration.Specifically,tumor migration of neutrophils was employed as hitchhiking delivery of doxorubicin(DOX)-loaded bacterial outer membrane vesicles(OMVs/DOX).By virtue of the surface pathogen-associated molecular patterns derived from native bacteria,OMVs/DOX could be selectively recognized by neutrophils,thus facilitating glioma targeted delivery of drug with significantly enhanced tumor accumulation by 18-fold as compared to the classical passive targeting effect.Moreover,the P-gp expression on tumor cells was silenced by bacteria typeⅢsecretion effector to sensitize the efficacy of DOX,resulting in complete tumor eradication with 100%survival of all treated mice.In addition,the colonized bacteria were finally cleared by anti-bacterial activity of DOX to minimize the potential infection risk,and cardiotoxicity of DOX was also avoided,achieving excellent compatibility.This work provides an efficient trans-BBB/BTB drug delivery strategy via cell hitchhiking for enhanced glioma therapy.展开更多
In recent years,with the development of artificial intelligence,especially deep learning technology,researches on automatic detection of cerebrovascular diseases on medical images have made tremendous progress and the...In recent years,with the development of artificial intelligence,especially deep learning technology,researches on automatic detection of cerebrovascular diseases on medical images have made tremendous progress and these models are gradually entering into clinical practice.However,because of the complexity and flexibility of the deep learning algorithms,these researches have great variability on model building,validation process,performance description and results interpretation.The lack of a reliable,consistent,standardized design protocol has,to a certain extent,affected the progress of clinical translation and technology development of computer aided detection systems.After reviewing a large number of literatures and extensive discussion with domestic experts,this position paper put forward recommendations of standardized design on the key steps of deep learning-based automatic image detection models for cerebrovascular diseases.With further research and application expansion,this position paper would continue to be updated and gradually extended to evaluate the generalizability and clinical application efficacy of such tools.展开更多
Background and Aims:This study was designed to uncov-er the mechanism for extracellular polysaccharide(EPS1-1)-mediated effects on hepatocellular carcinoma(HCC)devel-opment.Methods:HCC cells were treated with EPS1-1,m...Background and Aims:This study was designed to uncov-er the mechanism for extracellular polysaccharide(EPS1-1)-mediated effects on hepatocellular carcinoma(HCC)devel-opment.Methods:HCC cells were treated with EPS1-1,miR-494-3p mimic,sh-TRIM36,and pcDNA3.1-TRIM36.The levels of miR-494-3p and TRIM36 were measured in nor-mal hepatocytes,THLE-2,and HepG2 and HuH7HCC cell lines,along with the protein expression of cyclin D/E and p21.The proliferation,cell cycle,and apoptosis of HCC cells were assayed.The interactions between miR-494-3p and TRIM36,and between TRIM36 and cyclin E were assessed.Finally,the expression and localization of TRIM36 and cyclin E were monitored,and tumor apoptosis was detected,in tumor xenograft model.Results:EPS1-1 suppressed HCC cell proliferation and cyclin D/E expression and promoted apoptosis and p21 expression.miR-494-3p was upregulated and TRIM36 was downregulated in HCC cells.Transfection with miR-494-3p mimic or sh-TRIM36 facilitated HCC cell proliferation and the expression of cyclin D/E protein but they inhibited apoptosis and p21 expression in the pres-ence of EPS1-1.Overexpression of TRIM36 further con-solidated EPS1-1-mediated inhibition of HCC proliferation,cyclin D/E,and the promotion of apoptosis and p21 expres-sion.Those effects were reversed by miR-494-3p overex-pression.TRIM36 was a target gene of miR-494-3p,and TRIM36 induced cyclin E ubiquitination.EPS1-1 suppressed cyclin E expression,promoted TRIM36 expression and tu-mor apoptosis,all of which were abrogated by increasing the expression of miR-494-3p in vivo.Conclusions:EPS1-1 protected against HCC by limiting its proliferation and sur-vival through the miR-494-3p/TRIM36 axis and by inducing cyclin E ubiquitination.展开更多
基金the National Natural Science Foundation of China(Nos.81771827,82071986,82372072)the Key Research and Development Program of Hunan Province(No.2022SK2025)+5 种基金the Natural Science Foundation of Hunan Province(Nos.2023JJ40966,2021JJ20084)the Science and Technology Program of Hunan Province(Nos.2021RC4017,2021RC3020)the Youth Science Foundation of Xiangya Hospital(No.2022Q13)the Central South University Frontier Cross-disciplinary Project(No.2023QYJC021)the China Postdoctoral Science Foundation(No.2023M733954)the National Postdoctoral Program for Innovative Talents(No.BX20230432)。
文摘Radiotherapy(RT)is a widely used cancer treatment,and the use of metal-based nano-radiotherapy sensitizers has shown promise in enhancing its efficacy.However,efficient accumulation and deep penetration of these sensitizers within tumors remain challenging.In this study,we present the development of bismuth/manganese biomineralized nanoparticles(Bi Mn/BSA)with multiple radiosensitizing mechanisms,including high atomic number element-mediated radiation capture,catalase-mimic oxygenation,and activation of the stimulator of interferon genes(STING)pathway.Significantly,we demonstrate that low-dose RT induces the recruitment of macrophages and subsequent upregulation of Matrix metalloproteinases(MMP)-2 and MMP-9 that degrade the extracellular matrix(ECM).This dynamic process facilitates the targeted delivery and deep penetration of Bi Mn/BSA nanoparticles within tumors,thereby enhancing the effectiveness of RT.By combining low-dose RT with Bi Mn/BSA nanoparticles,we achieved complete suppression of tumor growth in mice with excellent biocompatibility.This study provides a novel and clinically relevant strategy for targeted nanoparticle delivery to tumors,and establishes a safe and effective sequential radiotherapy approach for cancer treatment.These findings hold great promise for improving the outcomes of RT and advancing the field of nanomedicine in cancer therapy.
基金supported by the National Natural Science Foundation of China(Nos.U1903125,82071986,82073799,and 81771827)Natural Science Foundation of Hunan province in China(2021JJ20084)+2 种基金the Science and Technology Project of Hunan Province(2021RC4017 and 2021RC3020,China)the Furong Scholars Programme of Hunan Provincethe Wisdom Accumulation and Talent Cultivation Project of the Third Xiangya Hospital of Central South University(China)。
文摘Chemotherapy is an important adjuvant treatment of glioma,while the efficacy is far from satisfactory,due not only to the biological barriers of blood-brain barrier(BBB)and blood-tumor barrier(BTB)but also to the intrinsic resistance of glioma cells via multiple survival mechanisms such as upregulation of P-glycoprotein(P-gp).To address these limitations,we report a bacteria-based drug delivery strategy for BBB/BTB transportation,glioma targeting,and chemo-sensitization.Bacteria selectively colonized into hypoxic tumor region and modulated tumor microenvironment,including macrophages repolarization and neutrophils infiltration.Specifically,tumor migration of neutrophils was employed as hitchhiking delivery of doxorubicin(DOX)-loaded bacterial outer membrane vesicles(OMVs/DOX).By virtue of the surface pathogen-associated molecular patterns derived from native bacteria,OMVs/DOX could be selectively recognized by neutrophils,thus facilitating glioma targeted delivery of drug with significantly enhanced tumor accumulation by 18-fold as compared to the classical passive targeting effect.Moreover,the P-gp expression on tumor cells was silenced by bacteria typeⅢsecretion effector to sensitize the efficacy of DOX,resulting in complete tumor eradication with 100%survival of all treated mice.In addition,the colonized bacteria were finally cleared by anti-bacterial activity of DOX to minimize the potential infection risk,and cardiotoxicity of DOX was also avoided,achieving excellent compatibility.This work provides an efficient trans-BBB/BTB drug delivery strategy via cell hitchhiking for enhanced glioma therapy.
基金Project supported by the Key Program of the National Natural Sci-ence Foundation of China(Grant Nos.81830057 and 82230068)the Young Scientists Fund of the National Natural Science Foundation of China(Grant No.82102155).
文摘In recent years,with the development of artificial intelligence,especially deep learning technology,researches on automatic detection of cerebrovascular diseases on medical images have made tremendous progress and these models are gradually entering into clinical practice.However,because of the complexity and flexibility of the deep learning algorithms,these researches have great variability on model building,validation process,performance description and results interpretation.The lack of a reliable,consistent,standardized design protocol has,to a certain extent,affected the progress of clinical translation and technology development of computer aided detection systems.After reviewing a large number of literatures and extensive discussion with domestic experts,this position paper put forward recommendations of standardized design on the key steps of deep learning-based automatic image detection models for cerebrovascular diseases.With further research and application expansion,this position paper would continue to be updated and gradually extended to evaluate the generalizability and clinical application efficacy of such tools.
文摘Background and Aims:This study was designed to uncov-er the mechanism for extracellular polysaccharide(EPS1-1)-mediated effects on hepatocellular carcinoma(HCC)devel-opment.Methods:HCC cells were treated with EPS1-1,miR-494-3p mimic,sh-TRIM36,and pcDNA3.1-TRIM36.The levels of miR-494-3p and TRIM36 were measured in nor-mal hepatocytes,THLE-2,and HepG2 and HuH7HCC cell lines,along with the protein expression of cyclin D/E and p21.The proliferation,cell cycle,and apoptosis of HCC cells were assayed.The interactions between miR-494-3p and TRIM36,and between TRIM36 and cyclin E were assessed.Finally,the expression and localization of TRIM36 and cyclin E were monitored,and tumor apoptosis was detected,in tumor xenograft model.Results:EPS1-1 suppressed HCC cell proliferation and cyclin D/E expression and promoted apoptosis and p21 expression.miR-494-3p was upregulated and TRIM36 was downregulated in HCC cells.Transfection with miR-494-3p mimic or sh-TRIM36 facilitated HCC cell proliferation and the expression of cyclin D/E protein but they inhibited apoptosis and p21 expression in the pres-ence of EPS1-1.Overexpression of TRIM36 further con-solidated EPS1-1-mediated inhibition of HCC proliferation,cyclin D/E,and the promotion of apoptosis and p21 expres-sion.Those effects were reversed by miR-494-3p overex-pression.TRIM36 was a target gene of miR-494-3p,and TRIM36 induced cyclin E ubiquitination.EPS1-1 suppressed cyclin E expression,promoted TRIM36 expression and tu-mor apoptosis,all of which were abrogated by increasing the expression of miR-494-3p in vivo.Conclusions:EPS1-1 protected against HCC by limiting its proliferation and sur-vival through the miR-494-3p/TRIM36 axis and by inducing cyclin E ubiquitination.
