Objective: To investigate the effects of electrochemically dealloying of Ti6Al4V abutments on human gingival fibroblasts (HGFs) and to provide experimental evidence for surface modification of implant abutments. Methods: The samples were divided into an NC group (negative control, no other treatment on a smooth surface), an NM-1 group (nanomesh-1, electrochemical dealloying treatment in 1 mol/L NaOH 1 h on 2 V voltage), and an NM-2 group (nanomesh-2, electrochemical dealloying treatment in 5 mol/L NaOH 1 h on 2 V voltage). The surface morphologies of the samples and the adhesion of HGFs on the sample surfaces were observed with scanning electron microscopy (SEM). The surface hydrophilicities of the samples were measured with a contact angle measuring instrument. The proliferation of HGFs on the different samples were evaluated with CCK-8, and the expression of adhesion-related genes, including collagen Ⅰ (COL1A1), collagen Ⅲ (COL3A1), fibronectin 1 (FN1), focal adhesion kinase (FAK), vinculin (VCL), integrin α2 (ITGA2), and integrin β1 (ITGB1), on the different samples was measured with qRT-PCR. The expression of vinculin on the surfaces of HGFs was observed via confocal laser scanning microscopy (CLSM) after immunofluorescent staining. Collagen fiber secretion and syntheses of HGFs from different samples were evaluated via Sirius red staining. Results: SEM revealed the formation of ordered and uniform three-dimensional mesh structures on the surfaces of the NM-1 and NM-2 groups, with grid diameters of approximately 30 nm for the NM-1 group and approximately 150 nm for the NM-2 group. Compared with that of the NC group, the water contact angles of the NM-1 group and NM-2 groups were significantly lower (P<0.000 1). Cell proliferation in the NM-1 group was significantly greater than that in the NC group (P<0.01). Moreover, there was no significant difference in the water contact angles or cell proliferation between the NM-1 group and the NM-2 group. SEM revealed that HGFs were adhered well to the surfaces of all samples, while the HGFs in the NM-1 and NM-2 groups showed more extended areas, longer morphologies, and more developed pseudopodia than did those in the NC group after 24 h. qRT-PCR revealed that the expression levels of the adhesion-related genes COL1A1, COL3A1, FN1, FAK and VCL in the NM-1 group were significantly greater than those in the NC and NM-2 groups (P<0.01). The expression of vinculin protein in the NM-1 group was the highest, and the number of focal adhesions was greatest in the NM-1 group (P<0.01). The results of Sirius red staining showed that the NM-1 group had the highest secretion and syntheses of collagen fibers (P<0.000 1). Conclusion The three-dimensional nanomechanical structure of Ti6Al4V modified by electrochemical dealloying promoted the adhesion, proliferation, collagen fiber secretion and syntheses of HGFs, and electrochemical dealloying of Ti6Al4V with a grid diameter of approximately 30 nm obviously promoted HGF formation.

Objective : To investigate the effect of miR-141-3p on LPS induced A549 cell injury by targeting high mobility group protein 1 (HMGB1) ． Methods : A549 cells derived from type Ⅱ alveolar epithelial cells were taken as the study object，miR-141-3p mimics，mimics NC，HMGB1 gene overexpression plasmid (pcDNA3. 1-HMGB1) and empty Vector were transfected into A549 cells respectively or co-transfected，then 10 μg / ml LPS was used for 24 h．Cell proliferation activity was detected by cell counting kit-8 ( CCK-8) ．The activity of lactate dehydrogenase ( LDH) in the supernatant of cell culture was detected by colorimetry．The apoptosis level of each group was detec- ted by flow cytometry．The levels of interleukin (IL) -1 β , IL-6 and tumor necrosis factor α (TNF-α) were detected by enzyme-linked immunosorbent assay (Elisa) ．Dual luciferase reporter gene assay verified the targeted regulatory relationship between miR-141-3p and HMGB1 . Results : After treatment with LPS ，the proliferative activity of A549 cells and the expression level of miR-141-3p decreased ( P ＜0. 05 ) ，the apoptosis rate increased ( P < 0. 05) ，the levels of IL-1 β , IL-6，TNF-α and the activity of LDH in supernatant increased (P＜0. 05) ．Overex- pression of miR-141-3p increased the proliferation activity of A549 cells treated with LPS (P ＜0. 05 ) ，and de- creased the apoptosis rate and the levels of IL-1 β , IL-6，TNF-α in cells and LDH activity in supernatant (P < 0. 05) ．However，overexpression of HMGB1 gene could reverse the ameliorative effect of miR-141-3p on LPS-in- duced A549 cell injury．Dual luciferase reporter gene experiment confirmed that HMGB1 was the downstream target gene of miR-141-3p． Conclusion miR-141-3p can inhibit LPS-induced apoptosis，reduce the expression level of inflammatory factors，and improve the damage of A549 cells，which may be related to the targeted regulation of HMGB1 expression.

Objective To investigate the effects of electrochemically dealloying of Ti6Al4V abutments on human gingival fibroblasts(HGFs)and to provide experimental evidence for surface modification of implant abutments.Methods The samples were divided into an NC group(negative control,no other treatment on a smooth surface),an NM-1 group(nanomesh-1,electrochemical dealloying treatment in 1 mol/L NaOH 1 h on 2 V voltage),and an NM-2 group(nanomesh-2,electrochemical dealloying treatment in 5 mol/L NaOH 1 h on 2 V voltage).The surface morpholo-gies of the samples and the adhesion of HGFs on the sample surfaces were observed with scanning electron microscopy(SEM).The surface hydrophilicities of the samples were measured with a contact angle measuring instrument.The prolif-eration of HGFs on the different samples were evaluated with CCK-8,and the expression of adhesion-related genes,in-cluding collagen Ⅰ(COL1A1),collagen Ⅲ(COL3A1),fibronectin 1(FN1),focal adhesion kinase(FAK),vinculin(VCL),integrin α2(ITGA2),and integrin β1(ITGB1),on the different samples was measured with qRT-PCR.The ex-pression of vinculin on the surfaces of HGFs was observed via confocal laser scanning microscopy(CLSM)after immuno-fluorescent staining.Collagen fiber secretion and syntheses of HGFs from different samples were evaluated via Sirius red staining.Results SEM revealed the formation of ordered and uniform three-dimensional mesh structures on the surfaces of the NM-1 and NM-2 groups,with grid diameters of approximately 30 nm for the NM-1 group and approxi-mately 150 nm for the NM-2 group.Compared with that of the NC group,the water contact angles of the NM-1 group and NM-2 groups were significantly lower(P＜0.000 1).Cell proliferation in the NM-1 group was significantly greater than that in the NC group(P＜0.01).Moreover,there was no significant difference in the water contact angles or cell prolifer-ation between the NM-1 group and the NM-2 group.SEM revealed that HGFs were adhered well to the surfaces of all samples,while the HGFs in the NM-1 and NM-2 groups showed more extended areas,longer morphologies,and more de-veloped pseudopodia than did those in the NC group after 24 h.qRT-PCR revealed that the expression levels of the ad-hesion-related genes COL1A1,COL3A1,FN1,FAK and VCL in the NM-1 group were significantly greater than those in the NC and NM-2 groups(P＜0.01).The expression of vinculin protein in the NM-1 group was the highest,and the num-ber of focal adhesions was greatest in the NM-1 group(P＜0.01).The results of Sirius red staining showed that the NM-1 group had the highest secretion and syntheses of collagen fibers(P＜0.000 1).Conclusion The three-dimensional nanomechanical structure of Ti6Al4V modified by electrochemical dealloying promoted the adhesion,proliferation,colla-gen fiber secretion and syntheses of HGFs,and electrochemical dealloying of Ti6Al4V with a grid diameter of approxi-mately 30 nm obviously promoted HGF formation.

Objective To investigate the effects of electrochemically dealloying of Ti6Al4V abutments on human gingival fibroblasts(HGFs)and to provide experimental evidence for surface modification of implant abutments.Methods The samples were divided into an NC group(negative control,no other treatment on a smooth surface),an NM-1 group(nanomesh-1,electrochemical dealloying treatment in 1 mol/L NaOH 1 h on 2 V voltage),and an NM-2 group(nanomesh-2,electrochemical dealloying treatment in 5 mol/L NaOH 1 h on 2 V voltage).The surface morpholo-gies of the samples and the adhesion of HGFs on the sample surfaces were observed with scanning electron microscopy(SEM).The surface hydrophilicities of the samples were measured with a contact angle measuring instrument.The prolif-eration of HGFs on the different samples were evaluated with CCK-8,and the expression of adhesion-related genes,in-cluding collagen Ⅰ(COL1A1),collagen Ⅲ(COL3A1),fibronectin 1(FN1),focal adhesion kinase(FAK),vinculin(VCL),integrin α2(ITGA2),and integrin β1(ITGB1),on the different samples was measured with qRT-PCR.The ex-pression of vinculin on the surfaces of HGFs was observed via confocal laser scanning microscopy(CLSM)after immuno-fluorescent staining.Collagen fiber secretion and syntheses of HGFs from different samples were evaluated via Sirius red staining.Results SEM revealed the formation of ordered and uniform three-dimensional mesh structures on the surfaces of the NM-1 and NM-2 groups,with grid diameters of approximately 30 nm for the NM-1 group and approxi-mately 150 nm for the NM-2 group.Compared with that of the NC group,the water contact angles of the NM-1 group and NM-2 groups were significantly lower(P＜0.000 1).Cell proliferation in the NM-1 group was significantly greater than that in the NC group(P＜0.01).Moreover,there was no significant difference in the water contact angles or cell prolifer-ation between the NM-1 group and the NM-2 group.SEM revealed that HGFs were adhered well to the surfaces of all samples,while the HGFs in the NM-1 and NM-2 groups showed more extended areas,longer morphologies,and more de-veloped pseudopodia than did those in the NC group after 24 h.qRT-PCR revealed that the expression levels of the ad-hesion-related genes COL1A1,COL3A1,FN1,FAK and VCL in the NM-1 group were significantly greater than those in the NC and NM-2 groups(P＜0.01).The expression of vinculin protein in the NM-1 group was the highest,and the num-ber of focal adhesions was greatest in the NM-1 group(P＜0.01).The results of Sirius red staining showed that the NM-1 group had the highest secretion and syntheses of collagen fibers(P＜0.000 1).Conclusion The three-dimensional nanomechanical structure of Ti6Al4V modified by electrochemical dealloying promoted the adhesion,proliferation,colla-gen fiber secretion and syntheses of HGFs,and electrochemical dealloying of Ti6Al4V with a grid diameter of approxi-mately 30 nm obviously promoted HGF formation.

Objective To investigate the effects of electrochemically dealloying of Ti6Al4V abutments on human gingival fibroblasts(HGFs)and to provide experimental evidence for surface modification of implant abutments.Methods The samples were divided into an NC group(negative control,no other treatment on a smooth surface),an NM-1 group(nanomesh-1,electrochemical dealloying treatment in 1 mol/L NaOH 1 h on 2 V voltage),and an NM-2 group(nanomesh-2,electrochemical dealloying treatment in 5 mol/L NaOH 1 h on 2 V voltage).The surface morpholo-gies of the samples and the adhesion of HGFs on the sample surfaces were observed with scanning electron microscopy(SEM).The surface hydrophilicities of the samples were measured with a contact angle measuring instrument.The prolif-eration of HGFs on the different samples were evaluated with CCK-8,and the expression of adhesion-related genes,in-cluding collagen Ⅰ(COL1A1),collagen Ⅲ(COL3A1),fibronectin 1(FN1),focal adhesion kinase(FAK),vinculin(VCL),integrin α2(ITGA2),and integrin β1(ITGB1),on the different samples was measured with qRT-PCR.The ex-pression of vinculin on the surfaces of HGFs was observed via confocal laser scanning microscopy(CLSM)after immuno-fluorescent staining.Collagen fiber secretion and syntheses of HGFs from different samples were evaluated via Sirius red staining.Results SEM revealed the formation of ordered and uniform three-dimensional mesh structures on the surfaces of the NM-1 and NM-2 groups,with grid diameters of approximately 30 nm for the NM-1 group and approxi-mately 150 nm for the NM-2 group.Compared with that of the NC group,the water contact angles of the NM-1 group and NM-2 groups were significantly lower(P＜0.000 1).Cell proliferation in the NM-1 group was significantly greater than that in the NC group(P＜0.01).Moreover,there was no significant difference in the water contact angles or cell prolifer-ation between the NM-1 group and the NM-2 group.SEM revealed that HGFs were adhered well to the surfaces of all samples,while the HGFs in the NM-1 and NM-2 groups showed more extended areas,longer morphologies,and more de-veloped pseudopodia than did those in the NC group after 24 h.qRT-PCR revealed that the expression levels of the ad-hesion-related genes COL1A1,COL3A1,FN1,FAK and VCL in the NM-1 group were significantly greater than those in the NC and NM-2 groups(P＜0.01).The expression of vinculin protein in the NM-1 group was the highest,and the num-ber of focal adhesions was greatest in the NM-1 group(P＜0.01).The results of Sirius red staining showed that the NM-1 group had the highest secretion and syntheses of collagen fibers(P＜0.000 1).Conclusion The three-dimensional nanomechanical structure of Ti6Al4V modified by electrochemical dealloying promoted the adhesion,proliferation,colla-gen fiber secretion and syntheses of HGFs,and electrochemical dealloying of Ti6Al4V with a grid diameter of approxi-mately 30 nm obviously promoted HGF formation.

Objective To investigate the effects of electrochemically dealloying of Ti6Al4V abutments on human gingival fibroblasts(HGFs)and to provide experimental evidence for surface modification of implant abutments.Methods The samples were divided into an NC group(negative control,no other treatment on a smooth surface),an NM-1 group(nanomesh-1,electrochemical dealloying treatment in 1 mol/L NaOH 1 h on 2 V voltage),and an NM-2 group(nanomesh-2,electrochemical dealloying treatment in 5 mol/L NaOH 1 h on 2 V voltage).The surface morpholo-gies of the samples and the adhesion of HGFs on the sample surfaces were observed with scanning electron microscopy(SEM).The surface hydrophilicities of the samples were measured with a contact angle measuring instrument.The prolif-eration of HGFs on the different samples were evaluated with CCK-8,and the expression of adhesion-related genes,in-cluding collagen Ⅰ(COL1A1),collagen Ⅲ(COL3A1),fibronectin 1(FN1),focal adhesion kinase(FAK),vinculin(VCL),integrin α2(ITGA2),and integrin β1(ITGB1),on the different samples was measured with qRT-PCR.The ex-pression of vinculin on the surfaces of HGFs was observed via confocal laser scanning microscopy(CLSM)after immuno-fluorescent staining.Collagen fiber secretion and syntheses of HGFs from different samples were evaluated via Sirius red staining.Results SEM revealed the formation of ordered and uniform three-dimensional mesh structures on the surfaces of the NM-1 and NM-2 groups,with grid diameters of approximately 30 nm for the NM-1 group and approxi-mately 150 nm for the NM-2 group.Compared with that of the NC group,the water contact angles of the NM-1 group and NM-2 groups were significantly lower(P＜0.000 1).Cell proliferation in the NM-1 group was significantly greater than that in the NC group(P＜0.01).Moreover,there was no significant difference in the water contact angles or cell prolifer-ation between the NM-1 group and the NM-2 group.SEM revealed that HGFs were adhered well to the surfaces of all samples,while the HGFs in the NM-1 and NM-2 groups showed more extended areas,longer morphologies,and more de-veloped pseudopodia than did those in the NC group after 24 h.qRT-PCR revealed that the expression levels of the ad-hesion-related genes COL1A1,COL3A1,FN1,FAK and VCL in the NM-1 group were significantly greater than those in the NC and NM-2 groups(P＜0.01).The expression of vinculin protein in the NM-1 group was the highest,and the num-ber of focal adhesions was greatest in the NM-1 group(P＜0.01).The results of Sirius red staining showed that the NM-1 group had the highest secretion and syntheses of collagen fibers(P＜0.000 1).Conclusion The three-dimensional nanomechanical structure of Ti6Al4V modified by electrochemical dealloying promoted the adhesion,proliferation,colla-gen fiber secretion and syntheses of HGFs,and electrochemical dealloying of Ti6Al4V with a grid diameter of approxi-mately 30 nm obviously promoted HGF formation.

Objective To investigate the effects of electrochemically dealloying of Ti6Al4V abutments on human gingival fibroblasts(HGFs)and to provide experimental evidence for surface modification of implant abutments.Methods The samples were divided into an NC group(negative control,no other treatment on a smooth surface),an NM-1 group(nanomesh-1,electrochemical dealloying treatment in 1 mol/L NaOH 1 h on 2 V voltage),and an NM-2 group(nanomesh-2,electrochemical dealloying treatment in 5 mol/L NaOH 1 h on 2 V voltage).The surface morpholo-gies of the samples and the adhesion of HGFs on the sample surfaces were observed with scanning electron microscopy(SEM).The surface hydrophilicities of the samples were measured with a contact angle measuring instrument.The prolif-eration of HGFs on the different samples were evaluated with CCK-8,and the expression of adhesion-related genes,in-cluding collagen Ⅰ(COL1A1),collagen Ⅲ(COL3A1),fibronectin 1(FN1),focal adhesion kinase(FAK),vinculin(VCL),integrin α2(ITGA2),and integrin β1(ITGB1),on the different samples was measured with qRT-PCR.The ex-pression of vinculin on the surfaces of HGFs was observed via confocal laser scanning microscopy(CLSM)after immuno-fluorescent staining.Collagen fiber secretion and syntheses of HGFs from different samples were evaluated via Sirius red staining.Results SEM revealed the formation of ordered and uniform three-dimensional mesh structures on the surfaces of the NM-1 and NM-2 groups,with grid diameters of approximately 30 nm for the NM-1 group and approxi-mately 150 nm for the NM-2 group.Compared with that of the NC group,the water contact angles of the NM-1 group and NM-2 groups were significantly lower(P＜0.000 1).Cell proliferation in the NM-1 group was significantly greater than that in the NC group(P＜0.01).Moreover,there was no significant difference in the water contact angles or cell prolifer-ation between the NM-1 group and the NM-2 group.SEM revealed that HGFs were adhered well to the surfaces of all samples,while the HGFs in the NM-1 and NM-2 groups showed more extended areas,longer morphologies,and more de-veloped pseudopodia than did those in the NC group after 24 h.qRT-PCR revealed that the expression levels of the ad-hesion-related genes COL1A1,COL3A1,FN1,FAK and VCL in the NM-1 group were significantly greater than those in the NC and NM-2 groups(P＜0.01).The expression of vinculin protein in the NM-1 group was the highest,and the num-ber of focal adhesions was greatest in the NM-1 group(P＜0.01).The results of Sirius red staining showed that the NM-1 group had the highest secretion and syntheses of collagen fibers(P＜0.000 1).Conclusion The three-dimensional nanomechanical structure of Ti6Al4V modified by electrochemical dealloying promoted the adhesion,proliferation,colla-gen fiber secretion and syntheses of HGFs,and electrochemical dealloying of Ti6Al4V with a grid diameter of approxi-mately 30 nm obviously promoted HGF formation.

Objective To investigate the effects of electrochemically dealloying of Ti6Al4V abutments on human gingival fibroblasts(HGFs)and to provide experimental evidence for surface modification of implant abutments.Methods The samples were divided into an NC group(negative control,no other treatment on a smooth surface),an NM-1 group(nanomesh-1,electrochemical dealloying treatment in 1 mol/L NaOH 1 h on 2 V voltage),and an NM-2 group(nanomesh-2,electrochemical dealloying treatment in 5 mol/L NaOH 1 h on 2 V voltage).The surface morpholo-gies of the samples and the adhesion of HGFs on the sample surfaces were observed with scanning electron microscopy(SEM).The surface hydrophilicities of the samples were measured with a contact angle measuring instrument.The prolif-eration of HGFs on the different samples were evaluated with CCK-8,and the expression of adhesion-related genes,in-cluding collagen Ⅰ(COL1A1),collagen Ⅲ(COL3A1),fibronectin 1(FN1),focal adhesion kinase(FAK),vinculin(VCL),integrin α2(ITGA2),and integrin β1(ITGB1),on the different samples was measured with qRT-PCR.The ex-pression of vinculin on the surfaces of HGFs was observed via confocal laser scanning microscopy(CLSM)after immuno-fluorescent staining.Collagen fiber secretion and syntheses of HGFs from different samples were evaluated via Sirius red staining.Results SEM revealed the formation of ordered and uniform three-dimensional mesh structures on the surfaces of the NM-1 and NM-2 groups,with grid diameters of approximately 30 nm for the NM-1 group and approxi-mately 150 nm for the NM-2 group.Compared with that of the NC group,the water contact angles of the NM-1 group and NM-2 groups were significantly lower(P＜0.000 1).Cell proliferation in the NM-1 group was significantly greater than that in the NC group(P＜0.01).Moreover,there was no significant difference in the water contact angles or cell prolifer-ation between the NM-1 group and the NM-2 group.SEM revealed that HGFs were adhered well to the surfaces of all samples,while the HGFs in the NM-1 and NM-2 groups showed more extended areas,longer morphologies,and more de-veloped pseudopodia than did those in the NC group after 24 h.qRT-PCR revealed that the expression levels of the ad-hesion-related genes COL1A1,COL3A1,FN1,FAK and VCL in the NM-1 group were significantly greater than those in the NC and NM-2 groups(P＜0.01).The expression of vinculin protein in the NM-1 group was the highest,and the num-ber of focal adhesions was greatest in the NM-1 group(P＜0.01).The results of Sirius red staining showed that the NM-1 group had the highest secretion and syntheses of collagen fibers(P＜0.000 1).Conclusion The three-dimensional nanomechanical structure of Ti6Al4V modified by electrochemical dealloying promoted the adhesion,proliferation,colla-gen fiber secretion and syntheses of HGFs,and electrochemical dealloying of Ti6Al4V with a grid diameter of approxi-mately 30 nm obviously promoted HGF formation.

Objective To investigate the effects of electrochemically dealloying of Ti6Al4V abutments on human gingival fibroblasts(HGFs)and to provide experimental evidence for surface modification of implant abutments.Methods The samples were divided into an NC group(negative control,no other treatment on a smooth surface),an NM-1 group(nanomesh-1,electrochemical dealloying treatment in 1 mol/L NaOH 1 h on 2 V voltage),and an NM-2 group(nanomesh-2,electrochemical dealloying treatment in 5 mol/L NaOH 1 h on 2 V voltage).The surface morpholo-gies of the samples and the adhesion of HGFs on the sample surfaces were observed with scanning electron microscopy(SEM).The surface hydrophilicities of the samples were measured with a contact angle measuring instrument.The prolif-eration of HGFs on the different samples were evaluated with CCK-8,and the expression of adhesion-related genes,in-cluding collagen Ⅰ(COL1A1),collagen Ⅲ(COL3A1),fibronectin 1(FN1),focal adhesion kinase(FAK),vinculin(VCL),integrin α2(ITGA2),and integrin β1(ITGB1),on the different samples was measured with qRT-PCR.The ex-pression of vinculin on the surfaces of HGFs was observed via confocal laser scanning microscopy(CLSM)after immuno-fluorescent staining.Collagen fiber secretion and syntheses of HGFs from different samples were evaluated via Sirius red staining.Results SEM revealed the formation of ordered and uniform three-dimensional mesh structures on the surfaces of the NM-1 and NM-2 groups,with grid diameters of approximately 30 nm for the NM-1 group and approxi-mately 150 nm for the NM-2 group.Compared with that of the NC group,the water contact angles of the NM-1 group and NM-2 groups were significantly lower(P＜0.000 1).Cell proliferation in the NM-1 group was significantly greater than that in the NC group(P＜0.01).Moreover,there was no significant difference in the water contact angles or cell prolifer-ation between the NM-1 group and the NM-2 group.SEM revealed that HGFs were adhered well to the surfaces of all samples,while the HGFs in the NM-1 and NM-2 groups showed more extended areas,longer morphologies,and more de-veloped pseudopodia than did those in the NC group after 24 h.qRT-PCR revealed that the expression levels of the ad-hesion-related genes COL1A1,COL3A1,FN1,FAK and VCL in the NM-1 group were significantly greater than those in the NC and NM-2 groups(P＜0.01).The expression of vinculin protein in the NM-1 group was the highest,and the num-ber of focal adhesions was greatest in the NM-1 group(P＜0.01).The results of Sirius red staining showed that the NM-1 group had the highest secretion and syntheses of collagen fibers(P＜0.000 1).Conclusion The three-dimensional nanomechanical structure of Ti6Al4V modified by electrochemical dealloying promoted the adhesion,proliferation,colla-gen fiber secretion and syntheses of HGFs,and electrochemical dealloying of Ti6Al4V with a grid diameter of approxi-mately 30 nm obviously promoted HGF formation.

To analyze the interest distribution relationship and symbiotic mode in the construction of urban medi-cal groups,based on the symbiotic theory,a framework for analyzing the interest distribution relationship of urban medical groups is constructed.Based on actual cases,urban medical groups are summarized and divided into four types:one-way supply type,partial benefit symbiosis type,asymmetric reciprocity symbiosis type,and symmetric reciprocity symbiosis type.The focus of a one-way supply oriented urban medical group is on reshaping the profit distribution mechanism,a partial benefit symbiotic urban medical group is on establishing a profit compensation mechanism for benefit medical institutions,and an asymmetric and mutually beneficial symbiotic urban medical group is on building a long-term benefit balance mechanism.