Secondary trauma, resulting in undesirable injury and bleeding during wound dressing treatment, which will cause the treatment of chronic wounds ineffective. The medical cotton gauzes often bring strong adhesion due t...Secondary trauma, resulting in undesirable injury and bleeding during wound dressing treatment, which will cause the treatment of chronic wounds ineffective. The medical cotton gauzes often bring strong adhesion due to the exudates absorbed and clots formed. Conversely, the easily detachable wound dressings neglect the wound seepage management, rendering them ineffective in facing the complexities of chronic wounds. To address this challenge, we propose a novel draining anti-adhesion dressings(DAD) by constructing the hydrophilic microchannels array on the superhydrophobic dressing. The superhydrophobic areas facilitate stable wound fiuid repellence leading to achieve the anti-adhesion(18.7% detachment energy of cotton) and the microchannel array ensures the transportation of excess exudates(>92%) by the capillary force. Notably, our dressing demonstrates a significant healing-promoting in a chronic wound model in rats. The development of such dressings holds promise for advancing wound care practices and addressing the unique challenges posed by chronic wounds, offering a valuable solution for improved clinical outcomes.展开更多
The micromorphologies of surfaces of several typical plant leaves were investigated by scanning electron microscopy(SEM). Different non-smooth surface characteristics were described and classified. The hydrophobicit...The micromorphologies of surfaces of several typical plant leaves were investigated by scanning electron microscopy(SEM). Different non-smooth surface characteristics were described and classified. The hydrophobicity and anti-adhesion of non-smooth leaf surfaces were quantitatively measured. Results show that the morphology of epidermal cells and the morphology and distribution density of epicuticular wax directly affect the hydrophobicity and anti-adhesion. The surface with uniformly distributed convex units shows the best anti-adhesion, and the surface with regularly arranged trellis units displays better anti-adhesion. In contrast, the surface with randomly distributed hair units performs relatively bad anti-adheslon. The hydrophobic models of papilla-ciliary and fold-setal non-smooth surfaces were set up to determine the impacts of geometric parameters on the hydrophobicity. This study may provide an insight into surface machine molding and apparent morphology design for biomimetics engineering.展开更多
Bacterial adhesion and biofilm formation impose a heavy burden on the medical system. Bacterial adhesion on implant materials would induce inflammation and result in implant failure. The adhesion of bacteria on food-p...Bacterial adhesion and biofilm formation impose a heavy burden on the medical system. Bacterial adhesion on implant materials would induce inflammation and result in implant failure. The adhesion of bacteria on food-processing and handling equipment may lead to food-borne illness. To reduce and even prevent bacterial adhesion, some bacterial anti-adhesion surface designs have been developed. However,the effect of some surface properties(including surface patterning, roughness and wettability) on bacterial adhesion has not been systematically summarized. In this review, a comprehensive overview of bacterial anti-adhesion surface design is presented. Modifying the surface pattern and roughness could reduce the contact area between bacteria and surfaces to weaken the initial adhesion force. Fabricating superhydrophobic surface or modifying hydrophilic functional groups could hinder the bacterial adhesion. The analysis and discussion about influencing factors of bacterial anti-adhesion surfaces provide basic guidelines on antibacterial surface design for future researches.展开更多
Tubal obstructive infertility is one of the most common causes of female infertility.At present,the main treatment is surgical mechanical dredging and restoration of tubal anatomy.Although the success rate of recanali...Tubal obstructive infertility is one of the most common causes of female infertility.At present,the main treatment is surgical mechanical dredging and restoration of tubal anatomy.Although the success rate of recanalization is high,the postoperative reocclusion rate is also high.In addition to the destruction of fallopian tubal function,it seriously affects the long-term pregnancy rate of women.Therefore,how to reduce the re-adhesion rate after recanalization is a more concerned issue at present.This article reviews the research progress of drug therapy for anti-adhesion after recanalization of tubal obstructive infertility.展开更多
The theoretical studies of bionics of machinery have great scientific significance, and the development of bionic machines has large practical values in the field of engineering and technology. Through the rigorous se...The theoretical studies of bionics of machinery have great scientific significance, and the development of bionic machines has large practical values in the field of engineering and technology. Through the rigorous selection process of evolution, the survived living organisms have successfully developed outstanding abilities to adapt to their surroundings and to reproduce their offspring. In this review,we interpreted the fundamental principles of anti-adhesion and anti-resistance of soil animals by reviewing the current status in this research field and summarizing the work of the research group at Jilin University of China in the past decades. The principles and technologies used in morphology bionics,electric-osmosis bionics,flexibility bionics,configuration bionics and coupling bionics were examined.Finally,the applications of the engineering bionics and their extensive prospects were introduced.展开更多
A new subsoiler with placoid scale microstructure bionic surface was proposed which mimicked shark skin to reduce tillage resistance and soil adhesion during subsoiling cultivation.The contour curves of placoid scale ...A new subsoiler with placoid scale microstructure bionic surface was proposed which mimicked shark skin to reduce tillage resistance and soil adhesion during subsoiling cultivation.The contour curves of placoid scale microstructure on shark skin were fitted,and two kinds of bionic subsoiler with continuous and discontinuous microstructures were designed and fabricated,respectively.The effects of different bionic surfaces on tillage resistance were investigated by finite element simulation and experiment.The results indicated that the bionic subsoiler with discontinuous microstructure reduced the horizontal and vertical force by 21.3%and 24.8%,respectively.The subsoiler with discontinuous microstructure surface can prevent the adhesion between the soil and subsoiler surface more efficiently.展开更多
Pericardial barrier destruction,inflammatory cell infiltration,and fibrous tissue hyperplasia,trigger adhesions after cardiac surgery.There are few anti-adhesion materials that are both functional and sutureable for p...Pericardial barrier destruction,inflammatory cell infiltration,and fibrous tissue hyperplasia,trigger adhesions after cardiac surgery.There are few anti-adhesion materials that are both functional and sutureable for pericardial reconstruction.Besides,a few studies have reported on the mechanism of preventing pericardial adhesion.Herein,a functional barrier membrane with sutureability was developed via a modified electrospinning method.It was composed of poly(L-lactide-co-caprolactone)(PLCL)nanofibers,poly(vinyl alcohol)(PVA)aerogel,and melatonin,named PPMT.The PPMT had a special microstructure manifested as a staggered arrangement of nanofibers on the surface and a layered macroporous aerogel structure in a cross-section.Besides providing the porosity and hydrophilicity obtained from PVA,the structure also had suitable mechanical properties for stitching due to the addition of PLCL nanofibers.Furthermore,it inhibited the proliferation of fibroblasts by suppressing the activation of Fas and P53,and achieved anti-inflammatory effects by affecting the activity of inflammatory cells and reducing the release of pro-inflammatory factors,such as interleukin 8(IL-8)and tumor necrosis factorα(TNF-α).Finally,in vivo transplantation showed that it up-regulated the expression of matrix metalloproteinase-1(MMP1)and tissue inhibitor of metalloproteinase-1(TIMP1),and down-regulated the expression of Vinculin and transforming growth factorβ(TGF-β)in the myocardium,thereby reducing the formation of adhesions.Collectively,these results demonstrate a great potential of PPMT membrane for practical application to anti-adhesion.展开更多
Polypropylene(PP)mesh is commonly used in abdominal wall repair due to its ability to reduce the risk of organ damage,infections and other complications.However,the PP mesh often leads to adhesion formation and does n...Polypropylene(PP)mesh is commonly used in abdominal wall repair due to its ability to reduce the risk of organ damage,infections and other complications.However,the PP mesh often leads to adhesion formation and does not promote functional tissue repair.In this study,we synthesized one kind of aldehyde Bletilla striata polysaccharide(BSPA)modified chitosan(CS)hydrogel based on Schiff base reaction.The hydrogel exhibited a porous network structure,a highly hydrophilic surface and good biocompatibility.We wrapped the PP mesh inside the hydrogel and evaluated the performance of the resulting composites in a bilateral 1×1.5cm abdominal wall defect model in rats.The results of gross observation,histological staining and immunohistochemical staining demonstrated the positive impact of the CS hydrogel on anti-adhesion and wound healing effects.Notably,the addition of BSPA to the CS hydrogel further improved the performance of the composites in vivo,promoting wound healing by enhancing collagen deposition and capillary rearrangement.This study suggested that the BSPA-modified CS hydrogel significantly promoted the anti-adhesion,anti-inflammatory and pro-angiogenesis properties of PP meshes during the healing process.Overall,this work offers a novel approach to the design of abdominal wall repair patches.展开更多
An active bacterial anti-adhesion strategy based on directional transportation of bacterial droplets driven by a triboelectric nanogenerator(TENG)has not been reported to date,although passive defense approaches can p...An active bacterial anti-adhesion strategy based on directional transportation of bacterial droplets driven by a triboelectric nanogenerator(TENG)has not been reported to date,although passive defense approaches can prevent bacterial adhesion by regulating superwetting surfaces combined with incorporated antibacterial substances.Here a triboelectric nanogenerator driving droplet system(TNDDS)was built to drive directional transportation of bacterial droplets to be eliminated,which comprises TENG with periodical frictional Kapton film and aluminum foils and a superhydrophobic driving platform(SDP)with paralleled driving electrodes.The current generated by the TENG triboelectricity is transmitted to the paralleled driving electrodes to form an electric field driving the directional transportation of charged droplets.The critical value of the driven droplet volume on SDP is closely related to the distributed electrodes’distance and width,and the driving distance of droplets is related to the number of electrodes.More crucially,TNDDS can actively drive the charged droplets of prepared triangular silver nanoprisms(Ag NPs)forward and back to mix with and remove a tiny bacterial droplet on an open SDP or in a tiny semi-enclosed channel.Bacteria could be killed by releasing Ag+and effectively removed by TNDDS by regulating the motion direction.Generally,this approach offers a promising application for removing bacteria from material surfaces driven by TENG and opens a new avenue for bacterial anti-adhesion.展开更多
Adhesion of leukocytes to endothelium plays an important role in inflammation-associated diseases.Our previous studies showed that multivalent lactosides were able to inhibit this process.Using 2-azide-l,3-propandiol ...Adhesion of leukocytes to endothelium plays an important role in inflammation-associated diseases.Our previous studies showed that multivalent lactosides were able to inhibit this process.Using 2-azide-l,3-propandiol and glutamic acid as spacers,we synthesized divalent lactoside An-2 and tetravalent lactoside Gu-4 by means of convergent method.These two compounds displayed high anti-adhesive activity and showed therapeutic effect in rats with severe burn shock.In addition, investigation of the anti-adhesion biological mechanism using labeled compounds YAn-2 and YGu-4 demonstrated that the target of multivalent lactosides was CD11b,theβ2 integrin subunit,on the surface of leukocytes.In this paper,the synthesis of these two new multivalent lactosides as well as their fluorescein-labeled and biotin-labeled compounds is reported.展开更多
Wound management remains significant challenges,encompassing numerous risks such as infection,antibiotic resistance,tissue adhesion,ischemia,hypoxia,and inflammatory responses.These complications are particularly acut...Wound management remains significant challenges,encompassing numerous risks such as infection,antibiotic resistance,tissue adhesion,ischemia,hypoxia,and inflammatory responses.These complications are particularly acute in cases of bacterial infection,where conventional treatment modalities may fail to provide adequate efficacy.To address these challenges,this study introduces phytic acid(PA)@ε-polylysine(Ply)@curcumin(Cur)@Zn@Gauze(PPCZ@Gauze),an innovative multifunctional gauze tailored to enhance wound healing.PPCZ@Gauze is designed and prepared using biosafe materials(phytic acid,ε-polylysine,curcumin,and zinc ions)through advanced surface modification techniques.Both in vitro and in vivo experiments demonstrate remarkable antibacterial properties,reduced tissue adhesion,and accelerated wound healing capabilities of PPCZ@Gauze compared to conventional medical gauze.Notably,PPCZ@Gauze also exhibits ease of preparation,cost-effectiveness,and scalability for large-scale production.Overall,this innovative multifunctional gauze offers a promising solution for managing bacterial infection wounds,leading to enhanced therapeutic outcomes and patient care.展开更多
The advent of antibiotics revolutionized the management of bacterial infections,yet their clinical efficacy is catastrophically undermined by the global emergence of antimicrobial resistance(AMR).Furthermore,the situa...The advent of antibiotics revolutionized the management of bacterial infections,yet their clinical efficacy is catastrophically undermined by the global emergence of antimicrobial resistance(AMR).Furthermore,the situation is aggravated by the fact that the formation of bacterial biofilm on material surfaces significantly enhances their tolerance to antibiotics.Therefore,there is an urgent need for new approaches that employ antibacterial mechanisms distinct from those of conventional antibiotics to mitigate the risk of AMR.Recently,naturally occurring surfaces found on typical plants and insects that take advantage of physical topography can either inhibit bacterial adhesion or directly inactivate bacterial cells,showing innovative“outside-the-box”prospects for antibacterial applications and garnering considerable interest due to their drug-free nature.Bioinspired micro-/nanostructures that mimic natural surface patterns have been replicated on various biomaterials to enhance their antibacterial properties.This review summarizes and explains the current advances in bioinspired antibacterial surfaces,as well as the underlying mechanisms of various strategies.Subsequently,synergistic antimicrobial surfaces,comprising a combination of various physical antibacterial strategies,are reviewed to highlight their potential for highly efficient disinfection and long-lasting antibacterial performance.Finally,the biomedical applications,coupled with the future challenges of bio-inspired antibacterial strategies,were further discussed.We hope this review could provide valuable insights for developing innovative,antibiotic-free antibacterial strategies that deliver powerful performance in combating AMR.展开更多
Surgical electrodes are frequently associated with disadvantages such as high surface adhesion and severe thermal damage to adjacent normal tissues,which threaten operation quality and patient safety.In this study,by ...Surgical electrodes are frequently associated with disadvantages such as high surface adhesion and severe thermal damage to adjacent normal tissues,which threaten operation quality and patient safety.In this study,by mimicking the micromorphology and bio-anti-adhesion of shark skin,we proposed a strategy that utilized nanoscale aluminium oxide(Al_(2)O_(3))films deposited on bioinspired shark skin(BSS)microstructures to design a composite surface(Al_(2)O_(3)@BSS)and integrated it into both flat sides of the surgical electrodes.Micro/nano-manufacturing of the Al_(2)O_(3)@BSS surface was sequentially accomplished using nanosecond laser texturing,atomic layer deposition,and low-temperature annealing,endowing it with excellent blood-repellent properties.Visualisation experiments revealed that the tensile stress gradient of the blood coagulum with increasing thickness under a thermal field prompted it to separate from the Al_(2)O_(3)@BSS surface,resulting in anti-adhesion.Furthermore,it was observed for the first time that Al_(2)O_(3) films could transiently excite discharge along a dielectric surface(DADS)to ablate tissues while suppressing Joule heat,thereby minimising thermal damage.A combination of ex vivo tissue and living mouse experiments demonstrated that the Al_(2)O_(3)@BSS electrodes exhibited optimal comprehensive performance in terms of anti-adhesion,damage minimisation,and drag reduction.In addition,the Al_(2)O_(3)@BSS electrodes possessed remarkable antibacterial efficacy against E.coli and S.aureus.The proposed strategy can meet the extreme application requirements of surgical electrodes to improve operation quality and offer valuable insights for future studies.展开更多
The electroosmotic flow near an earthworm surface is simulated numerically to further understand the anti soil adhesion mechanism of earthworm. A lattice Poisson method is employed to solve electric potential and char...The electroosmotic flow near an earthworm surface is simulated numerically to further understand the anti soil adhesion mechanism of earthworm. A lattice Poisson method is employed to solve electric potential and charge .distributiorts in the electric double layer along the earthworm surface. The external electric field is obtained by solving a Laplace equation. The electroosmotic flow controlled by the Navier-Stokes equations with external body force is simulated by the lattice Boltzmann method. A benchmark test shows that accurate electric potential distributions can be obtained by the LPM. The simulation shows that the moving vortices, which probably contribute to anti soil adhesion, are formed near earthworm body surface by the nonuniform and variational electrical force.展开更多
Although laparoscopy has the potential to reduce peritoneal trauma and post-operative peritoneal adhesion formation, only one randomized controlled trial and a few comparative retrospective clinical studies have addre...Although laparoscopy has the potential to reduce peritoneal trauma and post-operative peritoneal adhesion formation, only one randomized controlled trial and a few comparative retrospective clinical studies have addressed this issue. Laparoscopy reduces de novo adhesion formation but has no efficacy in reducing adhesion reformation after adhesiolysis. Moreover, several studies have suggested that the reduction of de novo post-operative adhesions does not seem to have a significant clinical impact. Experimental data in animal models have suggested that CO<sub>2</sub> pneumoperitoneum can cause acute peritoneal inflammation during laparoscopy depending on the insufflation pressure and the surgery duration. Broad peritoneal cavity protection by the insufflation of a low-temperature humidified gas mixture of CO<sub>2</sub>, N<sub>2</sub>O and O<sub>2</sub> seems to represent the best approach for reducing peritoneal inflammation due to pneumoperitoneum. However, these experimental data have not had a significant impact on the modification of laparoscopic instrumentation. In contrast, surgeons should train themselves to perform laparoscopy quickly, and they should complete their learning curves before testing chemical anti-adhesive agents and anti-adhesion barriers. Chemical anti-adhesive agents have the potential to exert broad peritoneal cavity protection against adhesion formation, but when these agents are used alone, the concentrations needed to prevent adhesions are too high and could cause major post-operative side effects. Anti-adhesion barriers have been used mainly in open surgery, but some clinical data from laparoscopic surgeries are already available. Sprays, gels, and fluid barriers are easier to apply in laparoscopic surgery than solid barriers. Results have been encouraging with solid barriers, spray barriers, and gel barriers, but they have been ambiguous with fluid barriers. Moreover, when barriers have been used alone, the maximum protection against adhesion formation has been no greater than 60%. A recent small, randomized clinical trial suggested that the combination of broad peritoneal cavity protection with local application of a barrier could be almost 100% effective in preventing post-operative adhesion formation. Future studies should confirm the efficacy of this global strategy in preventing adhesion formation after laparoscopy by focusing on clinical end points, such as reduced incidences of bowel obstruction and abdominal pain and increased fertility.展开更多
The concept of electroosmotically driven flow is built around understanding how the ionized particles or fluid are driven to flow by electroosmosis forces. Apart from the major applications of this concept to micro f...The concept of electroosmotically driven flow is built around understanding how the ionized particles or fluid are driven to flow by electroosmosis forces. Apart from the major applications of this concept to micro flow control elements which have been explored in parallel with the rapid developments in micro fabrication technologies, the present focus is on its application to biomimetics. As soil animals (in fact all living creatures) such as earthworms and dung beetles carry bioelectricity, the relative movement between the creatures and the surrounding soil which is a multi-component medium with moist content will generate electrophoresis or electroosmosis forces. Such forces drive the ionized moist content, normally water, to migrate from positive to negative poles under the action of electric double layer (EDL) effect, and effectively reduce the adhesion or drag.Predicting the electroosmotically driven flow in the vicinity of biological and animal surfaces is a key problem of drag/adhesion reduction and biomimetics design. The aim of this article is to demonstrate how the theory of electroosmotically driven flow has developed and to describe its broader significance for anti adhesion of soil animals and biomimetics design of soil machinery tools.展开更多
AIM:To block the adhesion of tumor cells to the extra- cellular matrix, and prevent tumor metastasis and recur- rence, the dimer of the β peptide (DLYYLMDLSYSMKG- GDLYYLMDLSYSMK, β2) was designed and synthesized and...AIM:To block the adhesion of tumor cells to the extra- cellular matrix, and prevent tumor metastasis and recur- rence, the dimer of the β peptide (DLYYLMDLSYSMKG- GDLYYLMDLSYSMK, β2) was designed and synthesized and its anti-adhesion and anti-invasion effects on hepa- tocellular carcinoma cells were assessed. Additionally, its influence on the metastasis and recurrence of mouse hepatocellular carcinoma was measured. METHODS:The anti-adhesion effect of β2 on the highly metastatic hepatocellular carcinoma cell line HCCLM6 cells and fibronectin (FN) was assayed by the MTT as- say. The inhibition of invasion of HCCLM6 cells by β2 was observed using a Transwell (modified Boyden chamber) and matrigel. Using the hepatocellular carcinoma metas- tasis model and LCI-D20 nude mice, the influence of β2 on the metastasis and recurrence of hepatocellular carci- noma after early resection was investigated. RESULTS:HCCLM6 cells co-incubated with 100 mmol/L, 50 mmol/L, 20 mmol/L or 10 mmol/L β2 for 3 h showed an obvious decrease in adhesion to FN. The adhesion inhibition ratios were 11.8%, 21.7%, 29.6% and 48.7%, respectively. Additionally, HCCLM6 cells cultured with 100 mmol/L β2 had a dramatic decrease in cell invasion. β2 was also observed to inhibit the incisal edge recur- rence and the distant metastasis of nude mice hepato- cellular carcinoma after early resection (P < 0.05). CONCLUSION:The β2 peptide can specifically block the adhesion and invasion of HCCLM6 cells, and can inhibit HCC recurrence and metastasis of LCI-D20 model pos-thepatectomy in vivo. Thus, β2 should be further studied as a new anti-tumor drug.展开更多
Polyamide(PA)thin-film composite(TFC)na nofiltration(NF)membrane has extremely broad application prospects in separation of monovalent/diva lent inorganic salts mixed solutio n.However,membrane fouling is the main obs...Polyamide(PA)thin-film composite(TFC)na nofiltration(NF)membrane has extremely broad application prospects in separation of monovalent/diva lent inorganic salts mixed solutio n.However,membrane fouling is the main obstacle to the application of PA,TFC and NF membrane.Streptomycin(SM)is a hydrophilic antibiotic containing a large number of hydroxyl and amino groups.In this work,the NF membrane was prepared via interfacial polymerization(IP)between trimesoyl chloride(TMC)in the organic phase and SM/piperazine(PIP)mixture in the aqueous phase.The NF membrane structure and performance were characterized in detail.The results showed that SM successfully participated in the IP.The negative charge and hydrophilicity of membrane surface were improved.The prepared membrane exhibited good anti-adhesion and anti-bacterial performance,Additionally,when the SM concentration was 2%,the prepared membrane exhibited the optimal permselectivity.The water permeance was 89.4L·m^(-2)·h^(-1)·MPa^(-1).The rejection of NaCl and Na_(2)SO_(4) were 17,17%and 97.84%,respectively.The NaCl/Na_(3)SO_(4) separation factor of the SM2-PIP/TMC membrane in 1000 mg·L^(-1) NaCl and 1000 mg·L^(-1)Na_(2)SO_(4) mixed solution was 40,which was 3.3 times that of PIP/TMC membrane.It indicated that SM2-PIP/TMC demonstrated excellent monovalent/divalent salts separation performance.This work provided an easy and effective approach to preparing anti-fouling NF membrane while possessing superior monovalent/divalent salts separation performance.展开更多
基金funding support by the National Nature Science Foundation of China (Nos. 22275028, 22325201, 52103136 and 22205033)the Shenzhen Science and Technology Program (No. JCYJ20210324142210027)+2 种基金the Sichuan Outstanding Young Scholars Foundation (No. 2021JDJQ0013)the Sichuan Science and Technology Program (No. 2023JDRC0081)the Fundamental Research Funds for the Central Universities (Nos. ZYGX2021YGCX009 and ZYGX2021YGLH207)。
文摘Secondary trauma, resulting in undesirable injury and bleeding during wound dressing treatment, which will cause the treatment of chronic wounds ineffective. The medical cotton gauzes often bring strong adhesion due to the exudates absorbed and clots formed. Conversely, the easily detachable wound dressings neglect the wound seepage management, rendering them ineffective in facing the complexities of chronic wounds. To address this challenge, we propose a novel draining anti-adhesion dressings(DAD) by constructing the hydrophilic microchannels array on the superhydrophobic dressing. The superhydrophobic areas facilitate stable wound fiuid repellence leading to achieve the anti-adhesion(18.7% detachment energy of cotton) and the microchannel array ensures the transportation of excess exudates(>92%) by the capillary force. Notably, our dressing demonstrates a significant healing-promoting in a chronic wound model in rats. The development of such dressings holds promise for advancing wound care practices and addressing the unique challenges posed by chronic wounds, offering a valuable solution for improved clinical outcomes.
基金The authors are grateful to the financial support provided by the National Natural Science Foundation of China (No. 50635030);the Key Project of Chinese Ministry of Education (Grant No. 105059).
文摘The micromorphologies of surfaces of several typical plant leaves were investigated by scanning electron microscopy(SEM). Different non-smooth surface characteristics were described and classified. The hydrophobicity and anti-adhesion of non-smooth leaf surfaces were quantitatively measured. Results show that the morphology of epidermal cells and the morphology and distribution density of epicuticular wax directly affect the hydrophobicity and anti-adhesion. The surface with uniformly distributed convex units shows the best anti-adhesion, and the surface with regularly arranged trellis units displays better anti-adhesion. In contrast, the surface with randomly distributed hair units performs relatively bad anti-adheslon. The hydrophobic models of papilla-ciliary and fold-setal non-smooth surfaces were set up to determine the impacts of geometric parameters on the hydrophobicity. This study may provide an insight into surface machine molding and apparent morphology design for biomimetics engineering.
基金supported by the National Natural Science Foundation of China (52003028)Fundamental Research Funds for the Central Universities (FRF-GF-20-06B)
文摘Bacterial adhesion and biofilm formation impose a heavy burden on the medical system. Bacterial adhesion on implant materials would induce inflammation and result in implant failure. The adhesion of bacteria on food-processing and handling equipment may lead to food-borne illness. To reduce and even prevent bacterial adhesion, some bacterial anti-adhesion surface designs have been developed. However,the effect of some surface properties(including surface patterning, roughness and wettability) on bacterial adhesion has not been systematically summarized. In this review, a comprehensive overview of bacterial anti-adhesion surface design is presented. Modifying the surface pattern and roughness could reduce the contact area between bacteria and surfaces to weaken the initial adhesion force. Fabricating superhydrophobic surface or modifying hydrophilic functional groups could hinder the bacterial adhesion. The analysis and discussion about influencing factors of bacterial anti-adhesion surfaces provide basic guidelines on antibacterial surface design for future researches.
基金National R&D Program"Study on the Prevention and Control of Reproductive Health and Major Birth Defects"Key Special Project"Effect of Immunity on Gametogenesis and Embryo Development"(No.2018YFC1003900)。
文摘Tubal obstructive infertility is one of the most common causes of female infertility.At present,the main treatment is surgical mechanical dredging and restoration of tubal anatomy.Although the success rate of recanalization is high,the postoperative reocclusion rate is also high.In addition to the destruction of fallopian tubal function,it seriously affects the long-term pregnancy rate of women.Therefore,how to reduce the re-adhesion rate after recanalization is a more concerned issue at present.This article reviews the research progress of drug therapy for anti-adhesion after recanalization of tubal obstructive infertility.
基金Supported by the Key Program of the National Natural Science Foundation of China (Grant Nos.50635030 and 59835200)the Chinese National Programs for Science and Technology Development (Grant No.2005BA429C)the Key Proliferation Project for Scientific and Technological Fruits of China (Grant No.2005EC000119)
文摘The theoretical studies of bionics of machinery have great scientific significance, and the development of bionic machines has large practical values in the field of engineering and technology. Through the rigorous selection process of evolution, the survived living organisms have successfully developed outstanding abilities to adapt to their surroundings and to reproduce their offspring. In this review,we interpreted the fundamental principles of anti-adhesion and anti-resistance of soil animals by reviewing the current status in this research field and summarizing the work of the research group at Jilin University of China in the past decades. The principles and technologies used in morphology bionics,electric-osmosis bionics,flexibility bionics,configuration bionics and coupling bionics were examined.Finally,the applications of the engineering bionics and their extensive prospects were introduced.
基金This work was financially supported by Natural Science Basic Research Program of Shaanxi(Program No.2021JQ-173)Innovation and Entrepreneurship Training Program of Northwest A&F University(Program No.201910712134).
文摘A new subsoiler with placoid scale microstructure bionic surface was proposed which mimicked shark skin to reduce tillage resistance and soil adhesion during subsoiling cultivation.The contour curves of placoid scale microstructure on shark skin were fitted,and two kinds of bionic subsoiler with continuous and discontinuous microstructures were designed and fabricated,respectively.The effects of different bionic surfaces on tillage resistance were investigated by finite element simulation and experiment.The results indicated that the bionic subsoiler with discontinuous microstructure reduced the horizontal and vertical force by 21.3%and 24.8%,respectively.The subsoiler with discontinuous microstructure surface can prevent the adhesion between the soil and subsoiler surface more efficiently.
基金The National Natural Science Fund of China(81873923)Shanghai Science and Technology Development Fund(20Y11910600,18441901900)supported this study.
文摘Pericardial barrier destruction,inflammatory cell infiltration,and fibrous tissue hyperplasia,trigger adhesions after cardiac surgery.There are few anti-adhesion materials that are both functional and sutureable for pericardial reconstruction.Besides,a few studies have reported on the mechanism of preventing pericardial adhesion.Herein,a functional barrier membrane with sutureability was developed via a modified electrospinning method.It was composed of poly(L-lactide-co-caprolactone)(PLCL)nanofibers,poly(vinyl alcohol)(PVA)aerogel,and melatonin,named PPMT.The PPMT had a special microstructure manifested as a staggered arrangement of nanofibers on the surface and a layered macroporous aerogel structure in a cross-section.Besides providing the porosity and hydrophilicity obtained from PVA,the structure also had suitable mechanical properties for stitching due to the addition of PLCL nanofibers.Furthermore,it inhibited the proliferation of fibroblasts by suppressing the activation of Fas and P53,and achieved anti-inflammatory effects by affecting the activity of inflammatory cells and reducing the release of pro-inflammatory factors,such as interleukin 8(IL-8)and tumor necrosis factorα(TNF-α).Finally,in vivo transplantation showed that it up-regulated the expression of matrix metalloproteinase-1(MMP1)and tissue inhibitor of metalloproteinase-1(TIMP1),and down-regulated the expression of Vinculin and transforming growth factorβ(TGF-β)in the myocardium,thereby reducing the formation of adhesions.Collectively,these results demonstrate a great potential of PPMT membrane for practical application to anti-adhesion.
基金the National Natural Science Foundation of China(No.32171345)the Hebei Provincial Natural Science Foundation of China(No.C2022104003)+4 种基金the Beijing Nova Programme Interdisciplinary Cooperation Project(No.20230484464)the Fok Ying Tung Education Foundation(No.141039)the Fund of Key Laboratory of Advanced Materials of Ministry of Education(No.AdvMat-2023-10)the International Joint Research Center of Aerospace Biotechnology and Medical Engineering,Ministry of Science and Technology of Chinathe 111 Project(No.B13003).
文摘Polypropylene(PP)mesh is commonly used in abdominal wall repair due to its ability to reduce the risk of organ damage,infections and other complications.However,the PP mesh often leads to adhesion formation and does not promote functional tissue repair.In this study,we synthesized one kind of aldehyde Bletilla striata polysaccharide(BSPA)modified chitosan(CS)hydrogel based on Schiff base reaction.The hydrogel exhibited a porous network structure,a highly hydrophilic surface and good biocompatibility.We wrapped the PP mesh inside the hydrogel and evaluated the performance of the resulting composites in a bilateral 1×1.5cm abdominal wall defect model in rats.The results of gross observation,histological staining and immunohistochemical staining demonstrated the positive impact of the CS hydrogel on anti-adhesion and wound healing effects.Notably,the addition of BSPA to the CS hydrogel further improved the performance of the composites in vivo,promoting wound healing by enhancing collagen deposition and capillary rearrangement.This study suggested that the BSPA-modified CS hydrogel significantly promoted the anti-adhesion,anti-inflammatory and pro-angiogenesis properties of PP meshes during the healing process.Overall,this work offers a novel approach to the design of abdominal wall repair patches.
基金This work was supported by the National Natural Science Foundation of China(No.22078077).
文摘An active bacterial anti-adhesion strategy based on directional transportation of bacterial droplets driven by a triboelectric nanogenerator(TENG)has not been reported to date,although passive defense approaches can prevent bacterial adhesion by regulating superwetting surfaces combined with incorporated antibacterial substances.Here a triboelectric nanogenerator driving droplet system(TNDDS)was built to drive directional transportation of bacterial droplets to be eliminated,which comprises TENG with periodical frictional Kapton film and aluminum foils and a superhydrophobic driving platform(SDP)with paralleled driving electrodes.The current generated by the TENG triboelectricity is transmitted to the paralleled driving electrodes to form an electric field driving the directional transportation of charged droplets.The critical value of the driven droplet volume on SDP is closely related to the distributed electrodes’distance and width,and the driving distance of droplets is related to the number of electrodes.More crucially,TNDDS can actively drive the charged droplets of prepared triangular silver nanoprisms(Ag NPs)forward and back to mix with and remove a tiny bacterial droplet on an open SDP or in a tiny semi-enclosed channel.Bacteria could be killed by releasing Ag+and effectively removed by TNDDS by regulating the motion direction.Generally,this approach offers a promising application for removing bacteria from material surfaces driven by TENG and opens a new avenue for bacterial anti-adhesion.
基金National Natural Science Foundation of China (Grant No 90713004)Ministry of Science and Technology of China(Grant No.2009ZX09103044.2009ZX09301-010)
文摘Adhesion of leukocytes to endothelium plays an important role in inflammation-associated diseases.Our previous studies showed that multivalent lactosides were able to inhibit this process.Using 2-azide-l,3-propandiol and glutamic acid as spacers,we synthesized divalent lactoside An-2 and tetravalent lactoside Gu-4 by means of convergent method.These two compounds displayed high anti-adhesive activity and showed therapeutic effect in rats with severe burn shock.In addition, investigation of the anti-adhesion biological mechanism using labeled compounds YAn-2 and YGu-4 demonstrated that the target of multivalent lactosides was CD11b,theβ2 integrin subunit,on the surface of leukocytes.In this paper,the synthesis of these two new multivalent lactosides as well as their fluorescein-labeled and biotin-labeled compounds is reported.
基金supported by Shanghai Special Project on Artificial Intelligence Facilitating the Reform of Scientific Research Paradigms to Empower Disciplinary Advancement(No.Z-2024-114-022)the Horizontal Project of Fuzhou Water Quality Monitoring Co.,Ltd.(No.H-2025-312-012)+2 种基金the General Program of the National Natural Science Foundation of China(No.82073266)Science and Technology Research Project of Jiangxi Provincial Department of Education(No.GJJ2201639)the Doctoral Research Start-up Fund Project of Jinggangshan University(No.JZB2117).
文摘Wound management remains significant challenges,encompassing numerous risks such as infection,antibiotic resistance,tissue adhesion,ischemia,hypoxia,and inflammatory responses.These complications are particularly acute in cases of bacterial infection,where conventional treatment modalities may fail to provide adequate efficacy.To address these challenges,this study introduces phytic acid(PA)@ε-polylysine(Ply)@curcumin(Cur)@Zn@Gauze(PPCZ@Gauze),an innovative multifunctional gauze tailored to enhance wound healing.PPCZ@Gauze is designed and prepared using biosafe materials(phytic acid,ε-polylysine,curcumin,and zinc ions)through advanced surface modification techniques.Both in vitro and in vivo experiments demonstrate remarkable antibacterial properties,reduced tissue adhesion,and accelerated wound healing capabilities of PPCZ@Gauze compared to conventional medical gauze.Notably,PPCZ@Gauze also exhibits ease of preparation,cost-effectiveness,and scalability for large-scale production.Overall,this innovative multifunctional gauze offers a promising solution for managing bacterial infection wounds,leading to enhanced therapeutic outcomes and patient care.
基金financial support through the National Science Foundation of China(No.52305317)the research collaboration project between the National Natural Science Foundation of China and the National Research Foundation of Korea(No.W2412095)+1 种基金Natural Science Foundation of Shandong Province(No.ZR2022QB040,ZR2022QH006,ZR20230B113)the Youth Innovation Team of Shandong Province(2024KJH045).
文摘The advent of antibiotics revolutionized the management of bacterial infections,yet their clinical efficacy is catastrophically undermined by the global emergence of antimicrobial resistance(AMR).Furthermore,the situation is aggravated by the fact that the formation of bacterial biofilm on material surfaces significantly enhances their tolerance to antibiotics.Therefore,there is an urgent need for new approaches that employ antibacterial mechanisms distinct from those of conventional antibiotics to mitigate the risk of AMR.Recently,naturally occurring surfaces found on typical plants and insects that take advantage of physical topography can either inhibit bacterial adhesion or directly inactivate bacterial cells,showing innovative“outside-the-box”prospects for antibacterial applications and garnering considerable interest due to their drug-free nature.Bioinspired micro-/nanostructures that mimic natural surface patterns have been replicated on various biomaterials to enhance their antibacterial properties.This review summarizes and explains the current advances in bioinspired antibacterial surfaces,as well as the underlying mechanisms of various strategies.Subsequently,synergistic antimicrobial surfaces,comprising a combination of various physical antibacterial strategies,are reviewed to highlight their potential for highly efficient disinfection and long-lasting antibacterial performance.Finally,the biomedical applications,coupled with the future challenges of bio-inspired antibacterial strategies,were further discussed.We hope this review could provide valuable insights for developing innovative,antibiotic-free antibacterial strategies that deliver powerful performance in combating AMR.
基金financially supported by the National Natural Science Foundation of China(Grant Nos.52275425,52405473,and 52405472)the Natural Science Foundation of Guangdong Province(Grant No.2024A1515010993)。
文摘Surgical electrodes are frequently associated with disadvantages such as high surface adhesion and severe thermal damage to adjacent normal tissues,which threaten operation quality and patient safety.In this study,by mimicking the micromorphology and bio-anti-adhesion of shark skin,we proposed a strategy that utilized nanoscale aluminium oxide(Al_(2)O_(3))films deposited on bioinspired shark skin(BSS)microstructures to design a composite surface(Al_(2)O_(3)@BSS)and integrated it into both flat sides of the surgical electrodes.Micro/nano-manufacturing of the Al_(2)O_(3)@BSS surface was sequentially accomplished using nanosecond laser texturing,atomic layer deposition,and low-temperature annealing,endowing it with excellent blood-repellent properties.Visualisation experiments revealed that the tensile stress gradient of the blood coagulum with increasing thickness under a thermal field prompted it to separate from the Al_(2)O_(3)@BSS surface,resulting in anti-adhesion.Furthermore,it was observed for the first time that Al_(2)O_(3) films could transiently excite discharge along a dielectric surface(DADS)to ablate tissues while suppressing Joule heat,thereby minimising thermal damage.A combination of ex vivo tissue and living mouse experiments demonstrated that the Al_(2)O_(3)@BSS electrodes exhibited optimal comprehensive performance in terms of anti-adhesion,damage minimisation,and drag reduction.In addition,the Al_(2)O_(3)@BSS electrodes possessed remarkable antibacterial efficacy against E.coli and S.aureus.The proposed strategy can meet the extreme application requirements of surgical electrodes to improve operation quality and offer valuable insights for future studies.
文摘The electroosmotic flow near an earthworm surface is simulated numerically to further understand the anti soil adhesion mechanism of earthworm. A lattice Poisson method is employed to solve electric potential and charge .distributiorts in the electric double layer along the earthworm surface. The external electric field is obtained by solving a Laplace equation. The electroosmotic flow controlled by the Navier-Stokes equations with external body force is simulated by the lattice Boltzmann method. A benchmark test shows that accurate electric potential distributions can be obtained by the LPM. The simulation shows that the moving vortices, which probably contribute to anti soil adhesion, are formed near earthworm body surface by the nonuniform and variational electrical force.
基金Supported by University of Cagliari,Italy,through the CAR Fund for 2012
文摘Although laparoscopy has the potential to reduce peritoneal trauma and post-operative peritoneal adhesion formation, only one randomized controlled trial and a few comparative retrospective clinical studies have addressed this issue. Laparoscopy reduces de novo adhesion formation but has no efficacy in reducing adhesion reformation after adhesiolysis. Moreover, several studies have suggested that the reduction of de novo post-operative adhesions does not seem to have a significant clinical impact. Experimental data in animal models have suggested that CO<sub>2</sub> pneumoperitoneum can cause acute peritoneal inflammation during laparoscopy depending on the insufflation pressure and the surgery duration. Broad peritoneal cavity protection by the insufflation of a low-temperature humidified gas mixture of CO<sub>2</sub>, N<sub>2</sub>O and O<sub>2</sub> seems to represent the best approach for reducing peritoneal inflammation due to pneumoperitoneum. However, these experimental data have not had a significant impact on the modification of laparoscopic instrumentation. In contrast, surgeons should train themselves to perform laparoscopy quickly, and they should complete their learning curves before testing chemical anti-adhesive agents and anti-adhesion barriers. Chemical anti-adhesive agents have the potential to exert broad peritoneal cavity protection against adhesion formation, but when these agents are used alone, the concentrations needed to prevent adhesions are too high and could cause major post-operative side effects. Anti-adhesion barriers have been used mainly in open surgery, but some clinical data from laparoscopic surgeries are already available. Sprays, gels, and fluid barriers are easier to apply in laparoscopic surgery than solid barriers. Results have been encouraging with solid barriers, spray barriers, and gel barriers, but they have been ambiguous with fluid barriers. Moreover, when barriers have been used alone, the maximum protection against adhesion formation has been no greater than 60%. A recent small, randomized clinical trial suggested that the combination of broad peritoneal cavity protection with local application of a barrier could be almost 100% effective in preventing post-operative adhesion formation. Future studies should confirm the efficacy of this global strategy in preventing adhesion formation after laparoscopy by focusing on clinical end points, such as reduced incidences of bowel obstruction and abdominal pain and increased fertility.
文摘The concept of electroosmotically driven flow is built around understanding how the ionized particles or fluid are driven to flow by electroosmosis forces. Apart from the major applications of this concept to micro flow control elements which have been explored in parallel with the rapid developments in micro fabrication technologies, the present focus is on its application to biomimetics. As soil animals (in fact all living creatures) such as earthworms and dung beetles carry bioelectricity, the relative movement between the creatures and the surrounding soil which is a multi-component medium with moist content will generate electrophoresis or electroosmosis forces. Such forces drive the ionized moist content, normally water, to migrate from positive to negative poles under the action of electric double layer (EDL) effect, and effectively reduce the adhesion or drag.Predicting the electroosmotically driven flow in the vicinity of biological and animal surfaces is a key problem of drag/adhesion reduction and biomimetics design. The aim of this article is to demonstrate how the theory of electroosmotically driven flow has developed and to describe its broader significance for anti adhesion of soil animals and biomimetics design of soil machinery tools.
基金National High-Tech Program of China, No. 2001AA215411 and No. 2004AA215201Shanghai Science and Technology Developing Program, No. 024319212
文摘AIM:To block the adhesion of tumor cells to the extra- cellular matrix, and prevent tumor metastasis and recur- rence, the dimer of the β peptide (DLYYLMDLSYSMKG- GDLYYLMDLSYSMK, β2) was designed and synthesized and its anti-adhesion and anti-invasion effects on hepa- tocellular carcinoma cells were assessed. Additionally, its influence on the metastasis and recurrence of mouse hepatocellular carcinoma was measured. METHODS:The anti-adhesion effect of β2 on the highly metastatic hepatocellular carcinoma cell line HCCLM6 cells and fibronectin (FN) was assayed by the MTT as- say. The inhibition of invasion of HCCLM6 cells by β2 was observed using a Transwell (modified Boyden chamber) and matrigel. Using the hepatocellular carcinoma metas- tasis model and LCI-D20 nude mice, the influence of β2 on the metastasis and recurrence of hepatocellular carci- noma after early resection was investigated. RESULTS:HCCLM6 cells co-incubated with 100 mmol/L, 50 mmol/L, 20 mmol/L or 10 mmol/L β2 for 3 h showed an obvious decrease in adhesion to FN. The adhesion inhibition ratios were 11.8%, 21.7%, 29.6% and 48.7%, respectively. Additionally, HCCLM6 cells cultured with 100 mmol/L β2 had a dramatic decrease in cell invasion. β2 was also observed to inhibit the incisal edge recur- rence and the distant metastasis of nude mice hepato- cellular carcinoma after early resection (P < 0.05). CONCLUSION:The β2 peptide can specifically block the adhesion and invasion of HCCLM6 cells, and can inhibit HCC recurrence and metastasis of LCI-D20 model pos-thepatectomy in vivo. Thus, β2 should be further studied as a new anti-tumor drug.
基金supported by the Joint Funds of the National Natural Science Foundation of China(U2006220)。
文摘Polyamide(PA)thin-film composite(TFC)na nofiltration(NF)membrane has extremely broad application prospects in separation of monovalent/diva lent inorganic salts mixed solutio n.However,membrane fouling is the main obstacle to the application of PA,TFC and NF membrane.Streptomycin(SM)is a hydrophilic antibiotic containing a large number of hydroxyl and amino groups.In this work,the NF membrane was prepared via interfacial polymerization(IP)between trimesoyl chloride(TMC)in the organic phase and SM/piperazine(PIP)mixture in the aqueous phase.The NF membrane structure and performance were characterized in detail.The results showed that SM successfully participated in the IP.The negative charge and hydrophilicity of membrane surface were improved.The prepared membrane exhibited good anti-adhesion and anti-bacterial performance,Additionally,when the SM concentration was 2%,the prepared membrane exhibited the optimal permselectivity.The water permeance was 89.4L·m^(-2)·h^(-1)·MPa^(-1).The rejection of NaCl and Na_(2)SO_(4) were 17,17%and 97.84%,respectively.The NaCl/Na_(3)SO_(4) separation factor of the SM2-PIP/TMC membrane in 1000 mg·L^(-1) NaCl and 1000 mg·L^(-1)Na_(2)SO_(4) mixed solution was 40,which was 3.3 times that of PIP/TMC membrane.It indicated that SM2-PIP/TMC demonstrated excellent monovalent/divalent salts separation performance.This work provided an easy and effective approach to preparing anti-fouling NF membrane while possessing superior monovalent/divalent salts separation performance.
