Pretreatment of Low-Density Polyethylene(LDPE)with physicochemical methods before biodegradation has been demonstrated as an effective strategy.The pretreatment of LDPE exhibited alterations in molecular structure,red...Pretreatment of Low-Density Polyethylene(LDPE)with physicochemical methods before biodegradation has been demonstrated as an effective strategy.The pretreatment of LDPE exhibited alterations in molecular structure,reducing hydrophobicity and decreasing tensile strength.Additionally,pretreating LDPE enhanced microbial biodegradability to improve biofilm formation and significantly reduced the physical weight of LDPE film.AS3–8 consortia exhibited a maximum weight loss of 8.0%±0.5%after 45 days of incubation.While Bacillus sp.AS3 and Sphingobacterium sp.AS8 demonstrated LDPE weight loss of 5.03%±1.6%and 1.6%±0.5%,respectively.The structure of LDPE was altered after incubation with the bacterial strains,resulting in a reduction in the intensity of functional groups,including C=O,C=C,N–H,and C–N.The carbonyl index(CI)of LDPE also decreased by 7.17%after the consortia AS3–8 degradation.Consortia AS3–8 significantly impacted the physical properties of LDPE by reducing the water contact angle(WCA),decreasing to 64.21°±3.69°,and tensile strength(TS),decreasing to 17.97±0.3 MPa.Moreover,the esterase activity was measured through 45 days of incubation.SDS-PAGE analysis of the AS3–8 consortia revealed bands at 35,48,and 70 kDa molecular weights,similar to known enzymes like laccase and esterase.Furthermore,SEM observations showed rough,cracked surfaces on pretreated LDPE,with biofilms present after incubation with the bacterial strains.GC–MS analysis revealed that AS3–8 consortia produced depolymerized chemicals,including alkanes,aldehydes,and esters.The LDPE biodegradation pathway was elucidated.This study addresses critical knowledge gaps in improving plastic degradation efficiency.展开更多
Poly(butylene adipate-terephthalate)(PBAT),as one of the most common and promising biodegradable plastics,has been widely used in agriculture,packaging,and other industries due to its strong biodegradability propertie...Poly(butylene adipate-terephthalate)(PBAT),as one of the most common and promising biodegradable plastics,has been widely used in agriculture,packaging,and other industries due to its strong biodegradability properties.It is well known that PBAT suffers a series of natural weathering,mechanical wear,hydrolysis,photochemical transformation,and other abiotic degradation processes before being biodegraded.Therefore,it is particularly important to understand the role of abiotic degradation in the life cycle of PBAT.Since the abiotic degradation of PBAT has not been systematically summarized,this review aims to summarize the mechanisms and main factors of the three major abiotic degradation pathways(hydrolysis,photochemical transformation,and thermochemical degradation)of PBAT.It was found that all of them preferentially destroy the chemical bonds with higher energy(especially C-O and C=O)of PBAT,which eventually leads to the shortening of the polymer chain and then leads to reduction in molecular weight.The main factors affecting these abiotic degradations are closely related to the energy or PBAT structure.These findings provide important theoretical and practical guidance for identifying effective methods for PBAT waste management and proposing advanced schemes to regulate the degradation rate of PBAT.展开更多
BACKGROUND Proximal bile duct injury(BDI),which often occurs after laparoscopic cholecystectomy(LC),can lead to complex biliary stricture and recurrent cholangitis.This case report presented a 39-year-old woman who ex...BACKGROUND Proximal bile duct injury(BDI),which often occurs after laparoscopic cholecystectomy(LC),can lead to complex biliary stricture and recurrent cholangitis.This case report presented a 39-year-old woman who experienced proximal BDI during LC in 2017,leading to multiple episodes of cholangitis and subsequent hepaticojejunostomy in 2018.Despite these interventions,persistent biliary complications necessitated repeated hospital admissions and antibiotic treatment.Imaging studies revealed persistent stricture at the site of hepaticojejunostomy,prompting a series of percutaneous procedures,including balloon dilatation and biliary drainage.In August 2024,she underwent biodegradable biliary stenting,which significantly improved her condition.Subsequently,she remained clinically stable for 5 months without further episodes of cholangitis and had improved liver function tests.This case highlighted the complexities of managing postinjury biliary stricture,underscored the potential of biodegradable stents as an effective treatment option,and emphasized the need for a multidisciplinary approach in managing such complications.Long-term follow-up is essential for monitoring treatment effectiveness and preventing recurrence.CASE SUMMARY A 39-year-old female had a routine LC in 2017.The patient sustained a proximal BDI during the surgery.In the months that followed,recurrent bouts of cholangitis occurred.A hepaticojejunostomy biliary reconstruction was performed in 2018.However,hepatic cholangitis persisted.In 2021 and 2022,MRCP scans revealed biliary stasis,duct dilation,and a stricture at the hepaticojejunostomy site.A subsequent percutaneous transhepatic cholangiography(PTC)confirmed these findings and led to drain placement.The treatment included internal and external biliary drain placements,repeated balloon dilations of the stricture,percutaneous transhepatic cholangioscopy to extract intrahepatic lithiasis,and insertion of a biodegradable biliary stent.Since the first PTC intervention,there have been no hospital admissions for cholangitis.Liver function tests showed improvement,and for five months following the biodegradable stenting,the condition remained stable.Long-term surveillance with regular imaging and blood work has been emphasized.The final diagnosis is recurrent biliary stricture secondary to proximal BDI.Treatment,including hepaticojejunostomy,repeated PTC with balloon dilation,and biodegradable biliary stenting,has led to complete drainage of the biliary system.Ongoing follow-up remains crucial for monitoring the patient's progress and maintaining their health.CONCLUSION This case demonstrated how strictures and recurrent cholangitis complicate the management of BDI after LC.A customized and multidisciplinary approach to control chronic biliary disease was proven effective,as shown by the patient’s good outcome.This was achieved by integrating balloon dilatation sessions,biliary drainage,stone clearing,and biodegradable stent placement.Long-term follow-up and continued monitoring remain essential to ensure patient stability and prevent further complications.展开更多
Oxytetracycline(OTC)is used extensively in animal husbandry and enters the soil in different forms,causing severe environmental pollution.Previous studies have shown that the genus Pseudomonas can potentially degrade ...Oxytetracycline(OTC)is used extensively in animal husbandry and enters the soil in different forms,causing severe environmental pollution.Previous studies have shown that the genus Pseudomonas can potentially degrade antibiotics in the soil environment.Environmental conditions,such as the initial concentration of antibiotics,incubation temperature and others,have significant impacts on the activity of antibiotic-degrading bacteria.However,few reports have clarified the environmental impacts on the effectiveness of Pseudomonas spp.In the present study,we investigated the effects of different initial concentrations of OTC and incubation temperatures,as well as soil sterilization,on OTC degradation by Pseudomonas strain T4.We also focused on the microbial degradation pathways of OTC,and variations in both antibiotic resistance genes(ARGs)and microbial communities with T4 functioning under optimal conditions.The results showed that the most effective degradation occurred under an initial OTC concentration of 2.5 mg kg^(-1)at 30℃in unsterilized soil spiked with T4.These conditions yielded an OTC degradation rate of 69.53%within 63 days.The putative degradation pathways of OTC in the presence of T4 included dehydration,demethylation,deamination,hydroxylation,oxidation and ring opening.Bacteroidetes,Proteobacteria and Acidobacteria played key roles in the biodegradation of OTC with T4 in the soil.The results also showed that tet(G)was the most frequently detected ARGs among the 13 common tetracycline ARGs that were investigated.The bacterial community shift observed in this study may provide new insights into the microbial degradation of OTC in soil.展开更多
Amid the escalating plastic pollution issue, the development of biodegradable and recyclable polymeric materials has become a focus within the scientific community. Chain extenders, which are an important class of com...Amid the escalating plastic pollution issue, the development of biodegradable and recyclable polymeric materials has become a focus within the scientific community. Chain extenders, which are an important class of compounds, facilitate the elongation of polymer chains through reactive functional groups, thereby enhancing the performance of the materials. Epoxy-based chain extenders, due to their cost-effectiveness, low toxicity, high reaction efficiency, and effective reactivity with hydroxyl and carboxyl groups, have emerged as a promising class of chain extenders. This manuscript comprehensively elaborates on the varieties, structural characteristics, and performance of chain extenders, the challenges they face, and the methods for their modification. Special emphasis is placed on the application of epoxy-based chain extenders in biodegradable polymers, such as polylactic acid (PLA), and their subsequent influence on the structural and performance properties of these materials.展开更多
The organic compound composition ofwastewater,serves as a crucial indicator for the operational performance of activated sludge processes and has a major influence on the development of filamentous bulking in activate...The organic compound composition ofwastewater,serves as a crucial indicator for the operational performance of activated sludge processes and has a major influence on the development of filamentous bulking in activated sludge.This study focused on the impact of typical soluble and slowly-biodegradable organic compounds,investigating the pathways through which these substrates affect the occurrence of filamentous bulking in systems operated under both high-and low-oxygen conditions.Results showed that slowly-biodegradable organic compounds lead to a concentrated distribution of microorganisms within flocs,with inward growth of filamentous bacteria.Both Tween-80 and granular starch treated systems exhibited a significant increase in protein content.The glucose system,utilizing soluble substrates,exhibited a markedly higher total polysaccharide content.Microbial communities in the Tween-80 and granular starch treated systems were characterized by a higher abundance of bacteria known to enhance sludge flocculation and settling,such as Competibacter,Xanthomonadaceae and Zoogloea.These findings are of high significance for controlling the operational performance and stability of activated sludge systems,deepening our understanding and providing a novel perspective for the improvement of wastewater treatment processes.展开更多
Benzo[a]pyrene(B[a]P)is a carcinogenic environmental pollutant widely present in the environment and can enter the human body through the food chain.It is therefore essential to treat and remediate the B[a]P-contamina...Benzo[a]pyrene(B[a]P)is a carcinogenic environmental pollutant widely present in the environment and can enter the human body through the food chain.It is therefore essential to treat and remediate the B[a]P-contaminated environment.Microbial remediation of B[a]Pcontaminated environments is considered to be one of the most effective strategies,and the addition of biostimulants is a feasible method to further improve the effectiveness of microbial remediation.In this study,we used Bacillus subtilis MSC4 to screen for the stimulation of sodium gluconate,which promoted B[a]P degradation.Based on biochemical and transcriptomic analyses,Sodium gluconate was found to significantly increase the biomass of MSC4 and the expression of most genes involved in B[a]P degradation.Activities of central carbon metabolism,fatty acidβ-oxidation and oxidative phosphorylation were all promoted.The significant increase in acid-induced oxalate decarboxylase expression indicates a decrease in intracellular pH,which promoted the synthesis of acetoin and lactate.Genes involved in the nitrogen cycle,especially nitrification and denitrification,were significantly up-regulated,contributing to B[a]P degradation.Genes involved in the synthesis of enzyme cofactors,including thiamine,molybdenum cofactors,NAD and heme,were up-regulated,which contributes to increasing enzyme activity in metabolic pathways.Up-regulation of genes in flagella assembly,chemotaxis,and lipopeptide synthesis is beneficial for the dissolution and uptake of B[a]P.Genes related to the sugar transport system were upregulated,which facilitates the transport and absorption of monosaccharides and oligosaccharides by MSC4.This study provides a theoretical basis for the further application of sodium gluconate in the treatment of PAH-contaminated sites.展开更多
Axonal regeneration following surgical nerve repair is slow and often incomplete,resulting in poor functional recovery which sometimes contributes to lifelong disability.Currently,there are no FDA-approved therapies a...Axonal regeneration following surgical nerve repair is slow and often incomplete,resulting in poor functional recovery which sometimes contributes to lifelong disability.Currently,there are no FDA-approved therapies available to promote nerve regeneration.Tacrolimus accelerates axonal regeneration,but systemic side effects presently outweigh its potential benefits for peripheral nerve surgery.The authors describe herein a biodegradable polyurethane-based drug delivery system for the sustained local release of tacrolimus at the nerve repair site,with suitable properties for scalable production and clinical application,aiming to promote nerve regeneration and functional recovery with minimal systemic drug exposure.Tacrolimus is encapsulated into co-axially electrospun polycarbonate-urethane nanofibers to generate an implantable nerve wrap that releases therapeutic doses of bioactive tacrolimus over 31 days.Size and drug loading are adjustable for applications in small and large caliber nerves,and the wrap degrades within 120 days into biocompatible byproducts.Tacrolimus released from the nerve wrap promotes axon elongation in vitro and accelerates nerve regeneration and functional recovery in preclinical nerve repair models while off-target systemic drug exposure is reduced by 80%compared with systemic delivery.Given its surgical suitability and preclinical efficacy and safety,this system may provide a readily translatable approach to support axonal regeneration and recovery in patients undergoing nerve surgery.展开更多
In this study,composite films consisting of polylactic acid(PLA),ethyl cellulose(EC),and zein were prepared by solution casting method,and their performance and application in chilled fresh meat preservation were inve...In this study,composite films consisting of polylactic acid(PLA),ethyl cellulose(EC),and zein were prepared by solution casting method,and their performance and application in chilled fresh meat preservation were investigated.The results showed that the three materials had satisfactory compatibility in the composite film.Addition of EC and zein effectively improved the mechanical properties,thermodynamic properties,surface hydrophilicity,oxygen permeability,and degradation properties of PLA films.When the ratio of PLA to EC was 3:7,the tensile strength and elongation at break reached maximum values of 16.6 MPa and 30.5%,respectively.Moreover,under different conditions,the composite film exhibited better degradability than the PLA film.The composite film with a 3:7 ratio of PLA to EC had the best performance,with a degradation rate of 21.75%after 84 days.Chilled fresh meat wrapped with the composite film showed significantly improved antioxidant,antibacterial,and water-holding properties.展开更多
A type of novel biodegradable fibers,made from magnetic particles and the patient’s own blood,promises an immune-evading brain cancer therapy with minimal invasion.
Mesoporous silica nanoparticles(MsNs)are thought to be an attractive drug delivery material because of their advantages including high specific surface area,tunable pore size and morphology,easy sur-face modification ...Mesoporous silica nanoparticles(MsNs)are thought to be an attractive drug delivery material because of their advantages including high specific surface area,tunable pore size and morphology,easy sur-face modification and good biocompatibility.However,as a result of the poor biodegradability of MsNs,their biomedical applications are limited.To break the bottleneck of limited biomedical applications of MSNs,more and more researchers tend to design biodegradable MSNs(b-MSNs)nanosystems to obtain biodegradable as well as safe and reliable drug delivery carriers.In this review,we focused on sum-marizing strategies to improve the degradability of MsNs and innovatively proposed a series of advan-tages of b-MsNs,including controlled cargo release behavior,multifunctional frameworks,nano-catalysis,bio-imaging capabilities and enhanced therapeutic effects.Based on these advantages,we have inno-vatively summarized the applications of b-MsNs for enhanced tumor theranostics,including enhanced chemotherapy,delivery of nanosensitizers,gas molecules and biomacromolecules,initiation of immune response,synergistic therapies and image-guided tumor diagnostics.Finally,the challenges and further clinical translation potential of nanosystems based on b-MsNs are fully discussed and prospected.We believe that such b-MsNs delivery carriers will provide a timely reference for further applications in tu-mor theranostics.展开更多
The growing presence of emerging pollutants in the environment has led to a focus on developing new treatment technologies to address the limitations of traditional methods.Recent advancements in combining photocataly...The growing presence of emerging pollutants in the environment has led to a focus on developing new treatment technologies to address the limitations of traditional methods.Recent advancements in combining photocatalysis with biodegradation for pollutant treatment have garnered significant attention.This is due to the rapid and uncontrolled chemical reactions in single photocatalytic processes,which often result in the buildup of harmful by-products and over-oxidation residues.Additionally,relying solely on biodegradation is challenging for breaking down emerging pollutants that possess high concentrations and intricate structures.Therefore,the intimately coupled photocatalysis and biodegradation(ICPB)systems,along with the photocatalytic microbial fuel cells(PMFCs),as a new approach to treat pollutants.These systems combine the benefits of biodegradation and photocatalytic reactions,providing cost-effective,eco-friendly,and sustainable solutions with significant promise.In order to demonstrate the ICPB system and the PMFCs system as rational options for pollutant removal,the mechanisms of pollutant degradation by the two systems have been analyzed in depth,and recent advances in photocatalysts,biofilms,and carriers/configurations in the two systems have been summarized.Furthermore,the practical applications of the ICPB system versus the PMFCs system for pollutant removal are also summarized and highlighted.This review further points out the current limitations,such as photocatalytic materials that are still challenging in terms of commercial viability for practical applications,and looks forward to the prospects of the ICPB system versus the PMFCs system for the treatment of pollutants to promote practical applications.展开更多
The study of microbial hydrocarbons removal is of great importance for the development of future bioremediation strategies.In this study,we evaluated the removal of a gaseous mixture containing toluene,m-xylene,ethylb...The study of microbial hydrocarbons removal is of great importance for the development of future bioremediation strategies.In this study,we evaluated the removal of a gaseous mixture containing toluene,m-xylene,ethylbenzene,cyclohexane,butane,pentane,hexane and heptane in aerated stirred bioreactors inoculated with Rhodococcus erythropolis and operated under non-sterile conditions.For the real-time measurement of hydrocarbons,a novel systematic approachwas implemented using Selected-Ion Flow TubeMass Spectrometry(SIFTMS).The effect of the carbon source(~9.5 ppmv)on(i)the bioreactors’performance(BR1:dosed with only cyclohexane as a single hydrocarbon versus BR2:dosed with a mixture of the 8 hydrocarbons)and(ii)the evolution of microbial communities over time were investigated.The results showed that cyclohexane reached a maximum removal efficiency(RE)of 53%±4%in BR1.In BR2,almost complete removal of toluene,m-xylene and ethylbenzene,being the most water-soluble and easy-to-degrade carbon sources,was observed.REs below 32%were obtained for the remaining compounds.By exposing the microbial consortium to only the five most recalcitrant hydrocarbons,REs between 45%±5%and 98%±1%were reached.In addition,we observed that airborne microorganisms populated the bioreactors and that the type of carbon source influenced the microbial communities developed.The abundance of species belonging to the genus Rhodococcus was below 10%in all bioreactors at the end of the experiments.This work provides fundamental insights to understand the complex behavior of gaseous hydrocarbon mixtures in bioreactors,along with a systematic approach for the development of SIFT-MS methods.展开更多
This study aimed to develop and characterize biodegradable packaging film from blends of two natural polysaccharides,i.e.,agar and glucomannan.The glucomannan used was derived from the specific tuber plant Amorphophal...This study aimed to develop and characterize biodegradable packaging film from blends of two natural polysaccharides,i.e.,agar and glucomannan.The glucomannan used was derived from the specific tuber plant Amorphophallus oncophyllus(locally known as“porang”),which grows abundantly in Indonesian forests and remains underutilized.Various ratios of agar and porang-glucomannan(PG)proportions were formulated to produce a food packaging film,which was subsequently tested for its mechanical,physical,chemical,and thermal properties.The results showed that the inclusion of PG to the film formulations notably enhanced the stretchability of agar films,achieving maximum a twofold increase,while concurrently reducing their water resistance such as increased water solubility and water swelling for up to 125%and 105%,respectively.The mechanical and thermal properties,as well as the water vapor permeability of the resulting film,were significantly affected by the polymer matrix structure formed by the varying proportions of the two biopolymers.The enhancement of these properties was associated with a more solid/compact film structure,as corroborated by cross-sectional images obtained through SEM analysis.The study’s findings suggest that utilizing agar and porang biomass has significant potential for further development as an environmentally friendly food packaging material.展开更多
Nowadays,the development of effective bioplastics aims to combine traditional plastics’functionality with environmentally friendly properties.The most effective and durable modern bioplastics are made from the edible...Nowadays,the development of effective bioplastics aims to combine traditional plastics’functionality with environmentally friendly properties.The most effective and durable modern bioplastics are made from the edible part of crops.This forces bioplastics to competewith food production because the crops that produce bioplastics can also be used for human nutrition.That is why the article’s main focus is on creating bioplastics using renewable,non-food raw materials(cellulose,lignin,etc.).Eco-friendly composites based on a renewable bioplastic blend of polybutylene adipate-co-terephthalate,corn starch,and poly(lactic acid)with reed and hemp waste as a filler.The physic-chemical features of the structure and surface,as well as the technological characteristics of reed and hemp waste as the organic fillers for renewable bioplastic blend of polybutylene adipate-co-terephthalate,corn starch,and poly(lactic acid),were studied.Theeffect of the fractional composition analysis,morphology,and nature of reed and hempwaste on the quality of the design of eco-friendly biodegradable composites and their ability to disperse in the matrix of renewable bioplastic blend of polybutylene adipate-co-terephthalate,corn starch and poly(lactic acid)was carried out.The influence of different content and morphology of reed and hemp waste on the composite characteristics was investigated.It is shown that the most optimal direction for obtaining strong eco-friendly biodegradable composites based on a renewable bioplastic blend of polybutylene adipate-co-terephthalate,corn starch,and poly(lactic acid)is associated with the use of waste reed stalks,with its optimal content at the level of 50 wt.%.展开更多
The possible application of magnesium(Mg)in glaucoma surgical treatment has been investigated in our previous work.In this paper,the degradation behavior and biocompatibility of Mg coated with hydroxyapatite(HA)and di...The possible application of magnesium(Mg)in glaucoma surgical treatment has been investigated in our previous work.In this paper,the degradation behavior and biocompatibility of Mg coated with hydroxyapatite(HA)and dicalcium phosphate dihydrate(DCPD)in eye environment were evaluated,and uncoated Mg was used for comparison.It was found that uniform corrosion occurred macroscopically to the coated Mg samples in sodium lactate ringer’s injection(SLRI)as well as in the rabbit eyes.In micro-scale,the corrosion was characterized by local cracking and pitting primarily.Mg and calcium(Ca)were incorporated into the surface corrosion products and a multi-layer structure was formed.Compared to other samples,HA-coated Mg slowed down dramatically the alkalinity of the solution and the ion release of the sample,and exhibited the lowest corrosion rate in SLRI,which was about 0.22 mm/a.In terms of biocompatibility,fibroblasts demonstrated high viability in the HA-coated and DCPD-coated Mg groups(p<0.05)in vitro.In vivo,HA-coated Mg was found to show lower inflammatory response and fibrosis than the other groups did,as indicated by hematoxylin-eosin and immunofluorescence staining.During the degrading process of HA-coated Mg in the rabbits’eyes,no inflammation was found in the anterior chamber,lens,and vitreous body.HA-coated Mg was fully biodegraded fifteen weeks post-operation,and the scleral drainage channel(SDC)was formed without obvious scarring.It is concluded that HA-coated Mg implantation is a promising adjunctive procedure to improve the success rate of trabeculectomy.Statement of significance:Magnesium(Mg)has shown to be a potential biomaterial for ophthalmic implants in our previous work.However,inflammatory response resulted from the low corrosion resistance of Mg is a major concern.It is shown here that Mg coated with different calcium phosphates can improve these properties in varying degrees and keep the scleral drainage channel unobstructed and unscarred.Based on our in vitro and in vivo studies,HA-coated Mg exhibited a better degradation behavior and excellent biocompatibility.The scleral drainage channel still exists and aqueous humor flows out smoothly after the full degradation of the implant.It is concluded that HA-coated Mg is a promising biomaterial to increase the therapeutic efficiency of trabeculectomy for glaucoma.展开更多
Biodegradable plastics are types of plastics that can decompose into water and carbon dioxide the actions of living organisms,mostly by bacteria.Generally,biodegradable plastics are obtained from renewable raw materia...Biodegradable plastics are types of plastics that can decompose into water and carbon dioxide the actions of living organisms,mostly by bacteria.Generally,biodegradable plastics are obtained from renewable raw materials,microorganisms,petrochemicals,or a combination of all three.This study aims to develop an innovative bioplastic by combining chitosan and lignin.Bioplastic was prepared by casting method and characterized by measuring the mechanical properties like tensile strength,Young’smodulus,and elongation at break.The chemical structure,together with the interactions among chitosan and lignin and the presence of new chemical bonds,were evaluated by FTIR,while the thermal properties were assessed by thermogravimetric analysis.The water vapor permeability,tests and transparency as well as biodegradability,were also carried out.The results show a tensile strength value of 34.82 MPa,Young’s modulus of 18.54 MPa,and elongation at a break of 2.74%.Moreover,the interaction between chitosan and lignin affects the intensity of the absorption peak,leading to reduced transparency and increased thermal stability.The chitosan/lignin interactions also influence the crystalline size,making it easier to degrade andmore flexible rather than rigid.The contact angle shows the bioplastic’s ability to resist water absorption for 4minutes.In the biodegradation test,the sample began to degrade after 30 days of soil burial test observation.展开更多
Biodegradable magnesium(Mg)-based metals can undergo spontaneous corrosion and full degradation in the human body,releasing magnesium ions,hydroxides,and hydrogen.Mg and its alloys have shown preliminary success as an...Biodegradable magnesium(Mg)-based metals can undergo spontaneous corrosion and full degradation in the human body,releasing magnesium ions,hydroxides,and hydrogen.Mg and its alloys have shown preliminary success as an implantable biomaterial.Current research on biodegradable Mg-based metals addresses clinical challenges,including material design and preparation,property enhancement,and exploring relevant biological functions.This review provides a comprehensive overview of the biomedical applications of Mg-based implants across eight fields:cardiovascular,orthopedics,stomatology,general surgery,neurosurgery,fat metabolism,and other potential areas,building upon previously published work.The challenges and prospects of biodegradable Mg-based implants in these application fields are discussed.展开更多
Due to its excellent biocompatibility and biodegradability,Mg has received widespread attention in biomaterials as implants and even biobatteries.However,the poor corrosion resistance makes it difficult to meet the gr...Due to its excellent biocompatibility and biodegradability,Mg has received widespread attention in biomaterials as implants and even biobatteries.However,the poor corrosion resistance makes it difficult to meet the growing demand for implant materials.This study developed a biodegradable nano-heterogeneous Mg(48 wt%)-Zn(52 wt%)-based metal(NHMZ)comprising nanocrystalline matrix phase Mg_(51)Zn_(20) and nanoscale MgZn_(2) precipitates.The unique microstructure of NHMZ enhances its corrosion resistance.The spherical aberration-corrected transmission electron microscope(AC-TEM)and precession electron diffraction(PED)characterized the microstructures.The corrosion rate of NHMZ is about 0.21 mm y^(-1) after soaking for 4 weeks,approximately 58% of high pure Mg.In addition,the anode discharge of NHMZ is more stable than Mg,indicating it has great potential in biological batteries.This work hopes to broaden the development direction of biodegradable metallic materials and break through the performance limitation of current biodegradable Mg alloys.展开更多
[Objectives]This study was conducted to investigate the effects of lignin-based fully biodegradable plastic film on the growth and quality of lettuce under open-field cultivation conditions.[Methods]In this experiment...[Objectives]This study was conducted to investigate the effects of lignin-based fully biodegradable plastic film on the growth and quality of lettuce under open-field cultivation conditions.[Methods]In this experiment,compared with bare soil,a polyethylene plastic film(PE)treatment and two lignin-based fully biodegradable plastic film treatments(LBF-0.01 and LBF-0.008)with different thicknesses were set to study the effects on the growth and quality of lettuce.[Results]During autumn cultivation in Shanghai,the thermal insulation performance and yield-increasing effect of the two degradable plastic films were consistent with those of PE film,and effectively met lettuce growth requirements,but treatment LBF-0.01was better than treatment LBF-0.008.Moreover,lignin-based fully biodegradable plastic film could significantly increase the contents of Vc,soluble sugar and carotenoids in lettuce,and treatment LBF-0.008 showed the best effect.It could be seen that under the experimental conditions,the two kinds of lignin-based biodegradable plastic films with different thicknesses could be applied to the cultivation of lettuce in the open field in Shanghai in autumn,and LBF-0.01 had the best effect of increasing temperature and increasing yield,while LBF-0.008 had the best effect of improving quality.[Conclusions]This study provides theoretical basis and technical support for the further application of lignin-based fully biodegradable plastic film.展开更多
文摘Pretreatment of Low-Density Polyethylene(LDPE)with physicochemical methods before biodegradation has been demonstrated as an effective strategy.The pretreatment of LDPE exhibited alterations in molecular structure,reducing hydrophobicity and decreasing tensile strength.Additionally,pretreating LDPE enhanced microbial biodegradability to improve biofilm formation and significantly reduced the physical weight of LDPE film.AS3–8 consortia exhibited a maximum weight loss of 8.0%±0.5%after 45 days of incubation.While Bacillus sp.AS3 and Sphingobacterium sp.AS8 demonstrated LDPE weight loss of 5.03%±1.6%and 1.6%±0.5%,respectively.The structure of LDPE was altered after incubation with the bacterial strains,resulting in a reduction in the intensity of functional groups,including C=O,C=C,N–H,and C–N.The carbonyl index(CI)of LDPE also decreased by 7.17%after the consortia AS3–8 degradation.Consortia AS3–8 significantly impacted the physical properties of LDPE by reducing the water contact angle(WCA),decreasing to 64.21°±3.69°,and tensile strength(TS),decreasing to 17.97±0.3 MPa.Moreover,the esterase activity was measured through 45 days of incubation.SDS-PAGE analysis of the AS3–8 consortia revealed bands at 35,48,and 70 kDa molecular weights,similar to known enzymes like laccase and esterase.Furthermore,SEM observations showed rough,cracked surfaces on pretreated LDPE,with biofilms present after incubation with the bacterial strains.GC–MS analysis revealed that AS3–8 consortia produced depolymerized chemicals,including alkanes,aldehydes,and esters.The LDPE biodegradation pathway was elucidated.This study addresses critical knowledge gaps in improving plastic degradation efficiency.
基金supported by the National Key R&D Program of China(No.2022YFC3901800)the National Natural Science Foundation of China(No.22176041)Guangzhou Science and Technology Planning Project(No.2023A04J0918)。
文摘Poly(butylene adipate-terephthalate)(PBAT),as one of the most common and promising biodegradable plastics,has been widely used in agriculture,packaging,and other industries due to its strong biodegradability properties.It is well known that PBAT suffers a series of natural weathering,mechanical wear,hydrolysis,photochemical transformation,and other abiotic degradation processes before being biodegraded.Therefore,it is particularly important to understand the role of abiotic degradation in the life cycle of PBAT.Since the abiotic degradation of PBAT has not been systematically summarized,this review aims to summarize the mechanisms and main factors of the three major abiotic degradation pathways(hydrolysis,photochemical transformation,and thermochemical degradation)of PBAT.It was found that all of them preferentially destroy the chemical bonds with higher energy(especially C-O and C=O)of PBAT,which eventually leads to the shortening of the polymer chain and then leads to reduction in molecular weight.The main factors affecting these abiotic degradations are closely related to the energy or PBAT structure.These findings provide important theoretical and practical guidance for identifying effective methods for PBAT waste management and proposing advanced schemes to regulate the degradation rate of PBAT.
文摘BACKGROUND Proximal bile duct injury(BDI),which often occurs after laparoscopic cholecystectomy(LC),can lead to complex biliary stricture and recurrent cholangitis.This case report presented a 39-year-old woman who experienced proximal BDI during LC in 2017,leading to multiple episodes of cholangitis and subsequent hepaticojejunostomy in 2018.Despite these interventions,persistent biliary complications necessitated repeated hospital admissions and antibiotic treatment.Imaging studies revealed persistent stricture at the site of hepaticojejunostomy,prompting a series of percutaneous procedures,including balloon dilatation and biliary drainage.In August 2024,she underwent biodegradable biliary stenting,which significantly improved her condition.Subsequently,she remained clinically stable for 5 months without further episodes of cholangitis and had improved liver function tests.This case highlighted the complexities of managing postinjury biliary stricture,underscored the potential of biodegradable stents as an effective treatment option,and emphasized the need for a multidisciplinary approach in managing such complications.Long-term follow-up is essential for monitoring treatment effectiveness and preventing recurrence.CASE SUMMARY A 39-year-old female had a routine LC in 2017.The patient sustained a proximal BDI during the surgery.In the months that followed,recurrent bouts of cholangitis occurred.A hepaticojejunostomy biliary reconstruction was performed in 2018.However,hepatic cholangitis persisted.In 2021 and 2022,MRCP scans revealed biliary stasis,duct dilation,and a stricture at the hepaticojejunostomy site.A subsequent percutaneous transhepatic cholangiography(PTC)confirmed these findings and led to drain placement.The treatment included internal and external biliary drain placements,repeated balloon dilations of the stricture,percutaneous transhepatic cholangioscopy to extract intrahepatic lithiasis,and insertion of a biodegradable biliary stent.Since the first PTC intervention,there have been no hospital admissions for cholangitis.Liver function tests showed improvement,and for five months following the biodegradable stenting,the condition remained stable.Long-term surveillance with regular imaging and blood work has been emphasized.The final diagnosis is recurrent biliary stricture secondary to proximal BDI.Treatment,including hepaticojejunostomy,repeated PTC with balloon dilation,and biodegradable biliary stenting,has led to complete drainage of the biliary system.Ongoing follow-up remains crucial for monitoring the patient's progress and maintaining their health.CONCLUSION This case demonstrated how strictures and recurrent cholangitis complicate the management of BDI after LC.A customized and multidisciplinary approach to control chronic biliary disease was proven effective,as shown by the patient’s good outcome.This was achieved by integrating balloon dilatation sessions,biliary drainage,stone clearing,and biodegradable stent placement.Long-term follow-up and continued monitoring remain essential to ensure patient stability and prevent further complications.
基金funded by the earmarked fund for China Agriculture Research System(CARS-29-zp-10)。
文摘Oxytetracycline(OTC)is used extensively in animal husbandry and enters the soil in different forms,causing severe environmental pollution.Previous studies have shown that the genus Pseudomonas can potentially degrade antibiotics in the soil environment.Environmental conditions,such as the initial concentration of antibiotics,incubation temperature and others,have significant impacts on the activity of antibiotic-degrading bacteria.However,few reports have clarified the environmental impacts on the effectiveness of Pseudomonas spp.In the present study,we investigated the effects of different initial concentrations of OTC and incubation temperatures,as well as soil sterilization,on OTC degradation by Pseudomonas strain T4.We also focused on the microbial degradation pathways of OTC,and variations in both antibiotic resistance genes(ARGs)and microbial communities with T4 functioning under optimal conditions.The results showed that the most effective degradation occurred under an initial OTC concentration of 2.5 mg kg^(-1)at 30℃in unsterilized soil spiked with T4.These conditions yielded an OTC degradation rate of 69.53%within 63 days.The putative degradation pathways of OTC in the presence of T4 included dehydration,demethylation,deamination,hydroxylation,oxidation and ring opening.Bacteroidetes,Proteobacteria and Acidobacteria played key roles in the biodegradation of OTC with T4 in the soil.The results also showed that tet(G)was the most frequently detected ARGs among the 13 common tetracycline ARGs that were investigated.The bacterial community shift observed in this study may provide new insights into the microbial degradation of OTC in soil.
文摘Amid the escalating plastic pollution issue, the development of biodegradable and recyclable polymeric materials has become a focus within the scientific community. Chain extenders, which are an important class of compounds, facilitate the elongation of polymer chains through reactive functional groups, thereby enhancing the performance of the materials. Epoxy-based chain extenders, due to their cost-effectiveness, low toxicity, high reaction efficiency, and effective reactivity with hydroxyl and carboxyl groups, have emerged as a promising class of chain extenders. This manuscript comprehensively elaborates on the varieties, structural characteristics, and performance of chain extenders, the challenges they face, and the methods for their modification. Special emphasis is placed on the application of epoxy-based chain extenders in biodegradable polymers, such as polylactic acid (PLA), and their subsequent influence on the structural and performance properties of these materials.
基金supported by the Opening Project of National Engineering Laboratory for Advanced Municipal Wastewater Treatment and Reuse Technology,and the National Natural Science Foundation of China(No.52270017).
文摘The organic compound composition ofwastewater,serves as a crucial indicator for the operational performance of activated sludge processes and has a major influence on the development of filamentous bulking in activated sludge.This study focused on the impact of typical soluble and slowly-biodegradable organic compounds,investigating the pathways through which these substrates affect the occurrence of filamentous bulking in systems operated under both high-and low-oxygen conditions.Results showed that slowly-biodegradable organic compounds lead to a concentrated distribution of microorganisms within flocs,with inward growth of filamentous bacteria.Both Tween-80 and granular starch treated systems exhibited a significant increase in protein content.The glucose system,utilizing soluble substrates,exhibited a markedly higher total polysaccharide content.Microbial communities in the Tween-80 and granular starch treated systems were characterized by a higher abundance of bacteria known to enhance sludge flocculation and settling,such as Competibacter,Xanthomonadaceae and Zoogloea.These findings are of high significance for controlling the operational performance and stability of activated sludge systems,deepening our understanding and providing a novel perspective for the improvement of wastewater treatment processes.
基金supported by the National Key R&D Program of China(No.2020YFC1808803).
文摘Benzo[a]pyrene(B[a]P)is a carcinogenic environmental pollutant widely present in the environment and can enter the human body through the food chain.It is therefore essential to treat and remediate the B[a]P-contaminated environment.Microbial remediation of B[a]Pcontaminated environments is considered to be one of the most effective strategies,and the addition of biostimulants is a feasible method to further improve the effectiveness of microbial remediation.In this study,we used Bacillus subtilis MSC4 to screen for the stimulation of sodium gluconate,which promoted B[a]P degradation.Based on biochemical and transcriptomic analyses,Sodium gluconate was found to significantly increase the biomass of MSC4 and the expression of most genes involved in B[a]P degradation.Activities of central carbon metabolism,fatty acidβ-oxidation and oxidative phosphorylation were all promoted.The significant increase in acid-induced oxalate decarboxylase expression indicates a decrease in intracellular pH,which promoted the synthesis of acetoin and lactate.Genes involved in the nitrogen cycle,especially nitrification and denitrification,were significantly up-regulated,contributing to B[a]P degradation.Genes involved in the synthesis of enzyme cofactors,including thiamine,molybdenum cofactors,NAD and heme,were up-regulated,which contributes to increasing enzyme activity in metabolic pathways.Up-regulation of genes in flagella assembly,chemotaxis,and lipopeptide synthesis is beneficial for the dissolution and uptake of B[a]P.Genes related to the sugar transport system were upregulated,which facilitates the transport and absorption of monosaccharides and oligosaccharides by MSC4.This study provides a theoretical basis for the further application of sodium gluconate in the treatment of PAH-contaminated sites.
基金supported by the German Research Foundation(DA 2255/1-1to SCD)+4 种基金a SickKids Research Training Competition(RESTRACOMP)Graduate Scholarship(to KJWS)an Ontario Graduate Scholarship(to KJWS)a grant from Natural Sciences and Engineering Research Council of Canada(NSERC)(to KJWS)a Kickstarter grant from the Institute of Biomedical Engineering(BME)at the University of Toronto(to KJWS)the Abe Frank Fund from the Riley’s Children Foundation(GHB)。
文摘Axonal regeneration following surgical nerve repair is slow and often incomplete,resulting in poor functional recovery which sometimes contributes to lifelong disability.Currently,there are no FDA-approved therapies available to promote nerve regeneration.Tacrolimus accelerates axonal regeneration,but systemic side effects presently outweigh its potential benefits for peripheral nerve surgery.The authors describe herein a biodegradable polyurethane-based drug delivery system for the sustained local release of tacrolimus at the nerve repair site,with suitable properties for scalable production and clinical application,aiming to promote nerve regeneration and functional recovery with minimal systemic drug exposure.Tacrolimus is encapsulated into co-axially electrospun polycarbonate-urethane nanofibers to generate an implantable nerve wrap that releases therapeutic doses of bioactive tacrolimus over 31 days.Size and drug loading are adjustable for applications in small and large caliber nerves,and the wrap degrades within 120 days into biocompatible byproducts.Tacrolimus released from the nerve wrap promotes axon elongation in vitro and accelerates nerve regeneration and functional recovery in preclinical nerve repair models while off-target systemic drug exposure is reduced by 80%compared with systemic delivery.Given its surgical suitability and preclinical efficacy and safety,this system may provide a readily translatable approach to support axonal regeneration and recovery in patients undergoing nerve surgery.
文摘In this study,composite films consisting of polylactic acid(PLA),ethyl cellulose(EC),and zein were prepared by solution casting method,and their performance and application in chilled fresh meat preservation were investigated.The results showed that the three materials had satisfactory compatibility in the composite film.Addition of EC and zein effectively improved the mechanical properties,thermodynamic properties,surface hydrophilicity,oxygen permeability,and degradation properties of PLA films.When the ratio of PLA to EC was 3:7,the tensile strength and elongation at break reached maximum values of 16.6 MPa and 30.5%,respectively.Moreover,under different conditions,the composite film exhibited better degradability than the PLA film.The composite film with a 3:7 ratio of PLA to EC had the best performance,with a degradation rate of 21.75%after 84 days.Chilled fresh meat wrapped with the composite film showed significantly improved antioxidant,antibacterial,and water-holding properties.
文摘A type of novel biodegradable fibers,made from magnetic particles and the patient’s own blood,promises an immune-evading brain cancer therapy with minimal invasion.
基金from"XingLiao Talent Program"of Liaoning Province(No.XLYC2203156)Shenyang Young and Middle-aged Science and Technology Innovation Talent Support Program(No.RC220397)are greatly acknowledged。
文摘Mesoporous silica nanoparticles(MsNs)are thought to be an attractive drug delivery material because of their advantages including high specific surface area,tunable pore size and morphology,easy sur-face modification and good biocompatibility.However,as a result of the poor biodegradability of MsNs,their biomedical applications are limited.To break the bottleneck of limited biomedical applications of MSNs,more and more researchers tend to design biodegradable MSNs(b-MSNs)nanosystems to obtain biodegradable as well as safe and reliable drug delivery carriers.In this review,we focused on sum-marizing strategies to improve the degradability of MsNs and innovatively proposed a series of advan-tages of b-MsNs,including controlled cargo release behavior,multifunctional frameworks,nano-catalysis,bio-imaging capabilities and enhanced therapeutic effects.Based on these advantages,we have inno-vatively summarized the applications of b-MsNs for enhanced tumor theranostics,including enhanced chemotherapy,delivery of nanosensitizers,gas molecules and biomacromolecules,initiation of immune response,synergistic therapies and image-guided tumor diagnostics.Finally,the challenges and further clinical translation potential of nanosystems based on b-MsNs are fully discussed and prospected.We believe that such b-MsNs delivery carriers will provide a timely reference for further applications in tu-mor theranostics.
文摘The growing presence of emerging pollutants in the environment has led to a focus on developing new treatment technologies to address the limitations of traditional methods.Recent advancements in combining photocatalysis with biodegradation for pollutant treatment have garnered significant attention.This is due to the rapid and uncontrolled chemical reactions in single photocatalytic processes,which often result in the buildup of harmful by-products and over-oxidation residues.Additionally,relying solely on biodegradation is challenging for breaking down emerging pollutants that possess high concentrations and intricate structures.Therefore,the intimately coupled photocatalysis and biodegradation(ICPB)systems,along with the photocatalytic microbial fuel cells(PMFCs),as a new approach to treat pollutants.These systems combine the benefits of biodegradation and photocatalytic reactions,providing cost-effective,eco-friendly,and sustainable solutions with significant promise.In order to demonstrate the ICPB system and the PMFCs system as rational options for pollutant removal,the mechanisms of pollutant degradation by the two systems have been analyzed in depth,and recent advances in photocatalysts,biofilms,and carriers/configurations in the two systems have been summarized.Furthermore,the practical applications of the ICPB system versus the PMFCs system for pollutant removal are also summarized and highlighted.This review further points out the current limitations,such as photocatalytic materials that are still challenging in terms of commercial viability for practical applications,and looks forward to the prospects of the ICPB system versus the PMFCs system for the treatment of pollutants to promote practical applications.
基金supported by Ghent University through a special research grant(No.BOFSTG2019005701)The assistance provided by Ann Dirckx in the microbiology lab was greatly appreciated.Allan A.Alvarado-Alvarado thanks the European Commission under the Erasmus+EMJMD Program for funding his research at Ghent University(No.2017-1957/001-001-EMJMD).
文摘The study of microbial hydrocarbons removal is of great importance for the development of future bioremediation strategies.In this study,we evaluated the removal of a gaseous mixture containing toluene,m-xylene,ethylbenzene,cyclohexane,butane,pentane,hexane and heptane in aerated stirred bioreactors inoculated with Rhodococcus erythropolis and operated under non-sterile conditions.For the real-time measurement of hydrocarbons,a novel systematic approachwas implemented using Selected-Ion Flow TubeMass Spectrometry(SIFTMS).The effect of the carbon source(~9.5 ppmv)on(i)the bioreactors’performance(BR1:dosed with only cyclohexane as a single hydrocarbon versus BR2:dosed with a mixture of the 8 hydrocarbons)and(ii)the evolution of microbial communities over time were investigated.The results showed that cyclohexane reached a maximum removal efficiency(RE)of 53%±4%in BR1.In BR2,almost complete removal of toluene,m-xylene and ethylbenzene,being the most water-soluble and easy-to-degrade carbon sources,was observed.REs below 32%were obtained for the remaining compounds.By exposing the microbial consortium to only the five most recalcitrant hydrocarbons,REs between 45%±5%and 98%±1%were reached.In addition,we observed that airborne microorganisms populated the bioreactors and that the type of carbon source influenced the microbial communities developed.The abundance of species belonging to the genus Rhodococcus was below 10%in all bioreactors at the end of the experiments.This work provides fundamental insights to understand the complex behavior of gaseous hydrocarbon mixtures in bioreactors,along with a systematic approach for the development of SIFT-MS methods.
基金funded by a research grant from the Lembaga Pengelola Dana Pendidikan-Ministry of Finance Republic of Indonesia(https://risprolpdp.kemenkeu.go.id/)(accessed on 13 September 2024)awarded under the Riset dan Inovasi untuk Indonesia Maju program with grant number 82/II.7/HK/2022.
文摘This study aimed to develop and characterize biodegradable packaging film from blends of two natural polysaccharides,i.e.,agar and glucomannan.The glucomannan used was derived from the specific tuber plant Amorphophallus oncophyllus(locally known as“porang”),which grows abundantly in Indonesian forests and remains underutilized.Various ratios of agar and porang-glucomannan(PG)proportions were formulated to produce a food packaging film,which was subsequently tested for its mechanical,physical,chemical,and thermal properties.The results showed that the inclusion of PG to the film formulations notably enhanced the stretchability of agar films,achieving maximum a twofold increase,while concurrently reducing their water resistance such as increased water solubility and water swelling for up to 125%and 105%,respectively.The mechanical and thermal properties,as well as the water vapor permeability of the resulting film,were significantly affected by the polymer matrix structure formed by the varying proportions of the two biopolymers.The enhancement of these properties was associated with a more solid/compact film structure,as corroborated by cross-sectional images obtained through SEM analysis.The study’s findings suggest that utilizing agar and porang biomass has significant potential for further development as an environmentally friendly food packaging material.
文摘Nowadays,the development of effective bioplastics aims to combine traditional plastics’functionality with environmentally friendly properties.The most effective and durable modern bioplastics are made from the edible part of crops.This forces bioplastics to competewith food production because the crops that produce bioplastics can also be used for human nutrition.That is why the article’s main focus is on creating bioplastics using renewable,non-food raw materials(cellulose,lignin,etc.).Eco-friendly composites based on a renewable bioplastic blend of polybutylene adipate-co-terephthalate,corn starch,and poly(lactic acid)with reed and hemp waste as a filler.The physic-chemical features of the structure and surface,as well as the technological characteristics of reed and hemp waste as the organic fillers for renewable bioplastic blend of polybutylene adipate-co-terephthalate,corn starch,and poly(lactic acid),were studied.Theeffect of the fractional composition analysis,morphology,and nature of reed and hempwaste on the quality of the design of eco-friendly biodegradable composites and their ability to disperse in the matrix of renewable bioplastic blend of polybutylene adipate-co-terephthalate,corn starch and poly(lactic acid)was carried out.The influence of different content and morphology of reed and hemp waste on the composite characteristics was investigated.It is shown that the most optimal direction for obtaining strong eco-friendly biodegradable composites based on a renewable bioplastic blend of polybutylene adipate-co-terephthalate,corn starch,and poly(lactic acid)is associated with the use of waste reed stalks,with its optimal content at the level of 50 wt.%.
基金supported by the Natural Science Foundation of Chongqing(Grant No.csts2018jcyjAX0016)Funded by the Senior Medical Talents Program of Chongqing for Young and Middle-aged.
文摘The possible application of magnesium(Mg)in glaucoma surgical treatment has been investigated in our previous work.In this paper,the degradation behavior and biocompatibility of Mg coated with hydroxyapatite(HA)and dicalcium phosphate dihydrate(DCPD)in eye environment were evaluated,and uncoated Mg was used for comparison.It was found that uniform corrosion occurred macroscopically to the coated Mg samples in sodium lactate ringer’s injection(SLRI)as well as in the rabbit eyes.In micro-scale,the corrosion was characterized by local cracking and pitting primarily.Mg and calcium(Ca)were incorporated into the surface corrosion products and a multi-layer structure was formed.Compared to other samples,HA-coated Mg slowed down dramatically the alkalinity of the solution and the ion release of the sample,and exhibited the lowest corrosion rate in SLRI,which was about 0.22 mm/a.In terms of biocompatibility,fibroblasts demonstrated high viability in the HA-coated and DCPD-coated Mg groups(p<0.05)in vitro.In vivo,HA-coated Mg was found to show lower inflammatory response and fibrosis than the other groups did,as indicated by hematoxylin-eosin and immunofluorescence staining.During the degrading process of HA-coated Mg in the rabbits’eyes,no inflammation was found in the anterior chamber,lens,and vitreous body.HA-coated Mg was fully biodegraded fifteen weeks post-operation,and the scleral drainage channel(SDC)was formed without obvious scarring.It is concluded that HA-coated Mg implantation is a promising adjunctive procedure to improve the success rate of trabeculectomy.Statement of significance:Magnesium(Mg)has shown to be a potential biomaterial for ophthalmic implants in our previous work.However,inflammatory response resulted from the low corrosion resistance of Mg is a major concern.It is shown here that Mg coated with different calcium phosphates can improve these properties in varying degrees and keep the scleral drainage channel unobstructed and unscarred.Based on our in vitro and in vivo studies,HA-coated Mg exhibited a better degradation behavior and excellent biocompatibility.The scleral drainage channel still exists and aqueous humor flows out smoothly after the full degradation of the implant.It is concluded that HA-coated Mg is a promising biomaterial to increase the therapeutic efficiency of trabeculectomy for glaucoma.
基金funded by the joint research collaboration of the Research Organization of Agriculture and Food National Research and Innovation Agency(BRIN)FY 2024(Grant number:6/III.11/HK/2024),with Widya Fatriasari as the Principal Investigator.
文摘Biodegradable plastics are types of plastics that can decompose into water and carbon dioxide the actions of living organisms,mostly by bacteria.Generally,biodegradable plastics are obtained from renewable raw materials,microorganisms,petrochemicals,or a combination of all three.This study aims to develop an innovative bioplastic by combining chitosan and lignin.Bioplastic was prepared by casting method and characterized by measuring the mechanical properties like tensile strength,Young’smodulus,and elongation at break.The chemical structure,together with the interactions among chitosan and lignin and the presence of new chemical bonds,were evaluated by FTIR,while the thermal properties were assessed by thermogravimetric analysis.The water vapor permeability,tests and transparency as well as biodegradability,were also carried out.The results show a tensile strength value of 34.82 MPa,Young’s modulus of 18.54 MPa,and elongation at a break of 2.74%.Moreover,the interaction between chitosan and lignin affects the intensity of the absorption peak,leading to reduced transparency and increased thermal stability.The chitosan/lignin interactions also influence the crystalline size,making it easier to degrade andmore flexible rather than rigid.The contact angle shows the bioplastic’s ability to resist water absorption for 4minutes.In the biodegradation test,the sample began to degrade after 30 days of soil burial test observation.
基金supported by grants from the Fundamental Research Funds for the Central Universities(No.2232024D-34 and No 2232023A-10)the National Natural Science Foundation of China(No.52201300)+4 种基金the National Key R&D Program of China(No.2023YFC2416800)the Shanghai Pujiang Program(No.23PJ1400500 and No 23PJ1400600)the State Key Laboratory for Modification of Chemical Fibers and Polymer Materials,Major/key program(No.23M1060280)the Science and Technology Project of Jiangsu Province(No.BE2022758)the Medicine-Engineering Interdisciplinary Project of Shanghai Xuhui District Dental Center(No.SHXYFYG202305).
文摘Biodegradable magnesium(Mg)-based metals can undergo spontaneous corrosion and full degradation in the human body,releasing magnesium ions,hydroxides,and hydrogen.Mg and its alloys have shown preliminary success as an implantable biomaterial.Current research on biodegradable Mg-based metals addresses clinical challenges,including material design and preparation,property enhancement,and exploring relevant biological functions.This review provides a comprehensive overview of the biomedical applications of Mg-based implants across eight fields:cardiovascular,orthopedics,stomatology,general surgery,neurosurgery,fat metabolism,and other potential areas,building upon previously published work.The challenges and prospects of biodegradable Mg-based implants in these application fields are discussed.
基金supported by grants from the National Natural Science Foundation of China(No.52201300)the National Key R&D Program of China(No.2023YFC2416800)+1 种基金China Postdoctoral Science Foundation(No.2021M702090)Changshu Science and Technology Program(Industrial)Project(No.CG202107).
文摘Due to its excellent biocompatibility and biodegradability,Mg has received widespread attention in biomaterials as implants and even biobatteries.However,the poor corrosion resistance makes it difficult to meet the growing demand for implant materials.This study developed a biodegradable nano-heterogeneous Mg(48 wt%)-Zn(52 wt%)-based metal(NHMZ)comprising nanocrystalline matrix phase Mg_(51)Zn_(20) and nanoscale MgZn_(2) precipitates.The unique microstructure of NHMZ enhances its corrosion resistance.The spherical aberration-corrected transmission electron microscope(AC-TEM)and precession electron diffraction(PED)characterized the microstructures.The corrosion rate of NHMZ is about 0.21 mm y^(-1) after soaking for 4 weeks,approximately 58% of high pure Mg.In addition,the anode discharge of NHMZ is more stable than Mg,indicating it has great potential in biological batteries.This work hopes to broaden the development direction of biodegradable metallic materials and break through the performance limitation of current biodegradable Mg alloys.
基金Supported by Shanghai Science and Technology Innovation Action Plan,China(22N51900900).
文摘[Objectives]This study was conducted to investigate the effects of lignin-based fully biodegradable plastic film on the growth and quality of lettuce under open-field cultivation conditions.[Methods]In this experiment,compared with bare soil,a polyethylene plastic film(PE)treatment and two lignin-based fully biodegradable plastic film treatments(LBF-0.01 and LBF-0.008)with different thicknesses were set to study the effects on the growth and quality of lettuce.[Results]During autumn cultivation in Shanghai,the thermal insulation performance and yield-increasing effect of the two degradable plastic films were consistent with those of PE film,and effectively met lettuce growth requirements,but treatment LBF-0.01was better than treatment LBF-0.008.Moreover,lignin-based fully biodegradable plastic film could significantly increase the contents of Vc,soluble sugar and carotenoids in lettuce,and treatment LBF-0.008 showed the best effect.It could be seen that under the experimental conditions,the two kinds of lignin-based biodegradable plastic films with different thicknesses could be applied to the cultivation of lettuce in the open field in Shanghai in autumn,and LBF-0.01 had the best effect of increasing temperature and increasing yield,while LBF-0.008 had the best effect of improving quality.[Conclusions]This study provides theoretical basis and technical support for the further application of lignin-based fully biodegradable plastic film.
