BACKGROUND Peptic ulcer(PU)is an abnormal phenomenon in which there is rupture of the mucosa of the digestive tract,which not only affects patients'normal life but also causes an economic burden due to its high me...BACKGROUND Peptic ulcer(PU)is an abnormal phenomenon in which there is rupture of the mucosa of the digestive tract,which not only affects patients'normal life but also causes an economic burden due to its high medical costs.AIM To investigate the efficacy of pantoprazole(PPZ)plus perforation repair in patients with PU and its effect on the stress response.METHODS The study subjects were 108 PU patients admitted between July 2018 and July 2022,including 58 patients receiving PPZ plus perforation repair[research group(RG)]and 50 patients given simple perforation repair[control group(CG)].The efficacy,somatostatin(SS)concentration,stress reaction[malondialdehyde(MDA),lipid peroxide(LPO)],inflammatory indices[tumor necrosis factor(TNF)-α,C-reactive protein(CRP),interleukin(IL)-1β],recurrence,and complications(perforation,hemorrhage,and pyloric obstruction)were compared.RESULTS The overall response rate was higher in the RG than in the CG.Patients in the RG and IL-1β were significantly reduced to lower levels than those in the CG.Lower recurrence and complication rates were identified in the RG group.CONCLUSION Therefore,PPZ plus perforation repair is conducive to enhancing treatment outcomes in PU patients,reducing oxidative stress injury and excessive inflammatory reactions,and contributing to low recurrence and complication rates.展开更多
Development of biocompatible hydrogel adhesives with robust tissue adhesion to realize instant hemorrhage control and injury sealing,especially for emergency rescue and tissue repair,is still challenging.Herein,we rep...Development of biocompatible hydrogel adhesives with robust tissue adhesion to realize instant hemorrhage control and injury sealing,especially for emergency rescue and tissue repair,is still challenging.Herein,we report a potent hydrogel adhesive by free radical polymerization of N-acryloyl aspartic acid(AASP)in a facile and straightforward way.Through delicate adjustment of steric hindrance,the synergistic effect between interface interactions and cohesion energy can be achieved in PAASP hydrogel verified by X-ray photoelectron spectroscopy(XPS)analysis and simulation calculation compared to poly(N-acryloyl glutamic acid)(PAGLU)and poly(N-acryloyl amidomalonic acid)(PAAMI)hydrogels.The adhesion strength of the PAASP hydrogel could reach 120 kPa to firmly seal the broken organs to withstand the external force with persistent stability under physiological conditions,and rapid hemostasis in different hemorrhage models on mice is achieved using PAASP hydrogel as physical barrier.Furthermore,the paper-based Fe^(3+)transfer printing method is applied to construct PAASP-based Janus hydrogel patch with both adhesive and non-adhesive surfaces,by which simultaneous wound healing and postoperative anti-adhesion can be realized in gastric perforation model on mice.This advanced hydrogel may show vast potential as bio-adhesives for emergency rescue and tissue/organ repair.展开更多
文摘BACKGROUND Peptic ulcer(PU)is an abnormal phenomenon in which there is rupture of the mucosa of the digestive tract,which not only affects patients'normal life but also causes an economic burden due to its high medical costs.AIM To investigate the efficacy of pantoprazole(PPZ)plus perforation repair in patients with PU and its effect on the stress response.METHODS The study subjects were 108 PU patients admitted between July 2018 and July 2022,including 58 patients receiving PPZ plus perforation repair[research group(RG)]and 50 patients given simple perforation repair[control group(CG)].The efficacy,somatostatin(SS)concentration,stress reaction[malondialdehyde(MDA),lipid peroxide(LPO)],inflammatory indices[tumor necrosis factor(TNF)-α,C-reactive protein(CRP),interleukin(IL)-1β],recurrence,and complications(perforation,hemorrhage,and pyloric obstruction)were compared.RESULTS The overall response rate was higher in the RG than in the CG.Patients in the RG and IL-1β were significantly reduced to lower levels than those in the CG.Lower recurrence and complication rates were identified in the RG group.CONCLUSION Therefore,PPZ plus perforation repair is conducive to enhancing treatment outcomes in PU patients,reducing oxidative stress injury and excessive inflammatory reactions,and contributing to low recurrence and complication rates.
基金the National Natural Science Foundation of China(NSFC 52173139)the Shaanxi International Science and Technology Cooperation Program Project(2020KW-062)+1 种基金the“Young Talent Support Plan”of Xi’an Jiaotong University,and Fundamental Research Funds for the Central Universities(xzy022021040)supported by the Opening Research Fund from Key Laboratory of Shaanxi Province for Craniofacial Precision Medicine Research,College of Stomatology,Xi’an Jiaotong University(2021LHM-KFKT003).
文摘Development of biocompatible hydrogel adhesives with robust tissue adhesion to realize instant hemorrhage control and injury sealing,especially for emergency rescue and tissue repair,is still challenging.Herein,we report a potent hydrogel adhesive by free radical polymerization of N-acryloyl aspartic acid(AASP)in a facile and straightforward way.Through delicate adjustment of steric hindrance,the synergistic effect between interface interactions and cohesion energy can be achieved in PAASP hydrogel verified by X-ray photoelectron spectroscopy(XPS)analysis and simulation calculation compared to poly(N-acryloyl glutamic acid)(PAGLU)and poly(N-acryloyl amidomalonic acid)(PAAMI)hydrogels.The adhesion strength of the PAASP hydrogel could reach 120 kPa to firmly seal the broken organs to withstand the external force with persistent stability under physiological conditions,and rapid hemostasis in different hemorrhage models on mice is achieved using PAASP hydrogel as physical barrier.Furthermore,the paper-based Fe^(3+)transfer printing method is applied to construct PAASP-based Janus hydrogel patch with both adhesive and non-adhesive surfaces,by which simultaneous wound healing and postoperative anti-adhesion can be realized in gastric perforation model on mice.This advanced hydrogel may show vast potential as bio-adhesives for emergency rescue and tissue/organ repair.
