Electrodeposition of chitosan/graphene oxide conduit to enhance peripheral nerve regeneration

Currently available commercial nerve guidance conduits have been applied in the repair of peripheral nerve defects.However,a conduit exhibiting good biocompatibility remains to be developed.In this work,a series of chitosan/graphene oxide(GO)films with concentrations of GO varying from 0-1 wt%(collectively referred to as CHGF-n)were prepared by an electrodeposition technique.The effects of CHGF-n on proliferation and adhesion abilities of Schwann cells were evaluated.The results showed that Schwann cells exhibited elongated spindle shapes and upregulated expression of nerve regeneration-related factors such as Krox20(a key myelination factor),Zeb2(essential for Schwann cell differentiation,myelination,and nerve repair),and transforming growth factorβ(a cytokine with regenerative functions).In addition,a nerve guidance conduit with a GO content of 0.25%(CHGFC-0.25)was implanted to repair a 10-mm sciatic nerve defect in rats.The results indicated improvements in sciatic functional index,electrophysiology,and sciatic nerve and gastrocnemius muscle histology compared with the CHGFC-0 group,and similar outcomes to the autograft group.In conclusion,we provide a candidate method for the repair of peripheral nerve defects using free-standing chitosan/GO nerve conduits produced by electrodeposition.

Manufacturing N,O-carboxymethyl chitosan-reduced graphene oxide under freeze-dying for performance improvement of Li-S battery

Lithium-sulfur(Li-S) batteries can provide far higher energy density than currently commercialized lithium ion batteries, but challenges remain before it they are used in practice.One of the challenges is the shuttle effect that originates from soluble intermediates, like lithium polysulfides. To address this issue, we report a novel laminar composite, N,O-carboxymethyl chitosan-reduced graphene oxide(CC-rGO), which is manufactured via the self-assembly of CC onto GO and subsequent reduction of GO under an extreme condition of 1 Pa and-50°C. The synthesized laminar CC-rGO composite is mixed with acetylene black(AB) and coated on a commercial polypropylene(PP) membrane, resulting in a separator(CC-rGO/AB/PP) that can not only completely suppress the polysulfides penetration, but also can accelerate the lithium ion transportation, providing a Li-S battery with excellent cyclic stability and rate capability. As confirmed by theoretic simulations, this unique feature of CC-rGO is attributed to its strong repulsive interaction to polysulfide anions and its benefit for fast lithium ion transportation through the paths paved by the heteroatoms in CC.

Adsorption behavior of cross-linked chitosan modified by graphene oxide for Cu(Ⅱ) removal

Cross-linked chitosan(CS),cross-linked chitosan/graphene(CS/RGO10) and cross-linked chitosan/graphene oxide(CS/GO10) were prepared as adsorbents for Cu(Ⅱ).The effects of pH,contact time,adsorbent dosage and initial concentration of Cu(Ⅱ) on the adsorbing abilities of CS,CS/RGO10 and CS/GO10 to Cu(Ⅱ) were investigated.The results demonstrate that the adsorption capacities of CS/GO10 and CS/RGO10 are greater than that of CS,especially at pH 5.0 and the adsorption capacities are 202.5,150 and 137.5 mg/g,respectively.Their behaviors obey the Freundlich isotherm model very well.Additionally,CS/GO10 has the shortest time to achieve adsorption equilibrium among them and can be used as a perspective adsorbent for Cu(Ⅱ).

Graphene oxide-composited chitosan scaffold contributes to functional recovery of injured spinal cord in rats

The study illustrates that graphene oxide nanosheets can endow materials with continuous electrical conductivity for up to 4 weeks. Conductive nerve scaffolds can bridge a sciatic nerve injury and guide the growth of neurons;however, whether the scaffolds can be used for the repair of spinal cord nerve injuries remains to be explored. In this study, a conductive graphene oxide composited chitosan scaffold was fabricated by genipin crosslinking and lyophilization. The prepared chitosan-graphene oxide scaffold presented a porous structure with an inner diameter of 18–87 μm, and a conductivity that reached 2.83 mS/cm because of good distribution of the graphene oxide nanosheets, which could be degraded by peroxidase. The chitosan-graphene oxide scaffold was transplanted into a T9 total resected rat spinal cord. The results show that the chitosan-graphene oxide scaffold induces nerve cells to grow into the pores between chitosan molecular chains, inducing angiogenesis in regenerated tissue, and promote neuron migration and neural tissue regeneration in the pores of the scaffold, thereby promoting the repair of damaged nerve tissue. The behavioral and electrophysiological results suggest that the chitosan-graphene oxide scaffold could significantly restore the neurological function of rats. Moreover, the functional recovery of rats treated with chitosangraphene oxide scaffold was better than that treated with chitosan scaffold. The results show that graphene oxide could have a positive role in the recovery of neurological function after spinal cord injury by promoting the degradation of the scaffold, adhesion, and migration of nerve cells to the scaffold. This study was approved by the Ethics Committee of Animal Research at the First Affiliated Hospital of Third Military Medical University(Army Medical University)(approval No. AMUWEC20191327) on August 30, 2019.

Electrochemical study and application on rutin at chitosan/graphene films modified glassy carbon electrode

Graphene（G） was dispersed into 0.5% chitosan（Chit） solution,then the composite films were coated on glassy carbon electrode（GCE）,the electrochemical behavior of rutin on a Chit/G modified GCE was investigated and the electrochemical parameters of rutin were calculated.Rutin effectively accumulated on the Chit/G/GCE and caused a pair of redox peaks at around 408 mV and 482 mV（vs.SCE） in 0.1M phosphate buffer solution（pH 4.0）.Under optimized conditions,the anodic peak current was linear to the rutin concentration in the range of 5×107-1.04×105M.The regression equation was：y 9.9219x-0.0025,r=0.9958.The proposed method was successfully used for the determination of rutin content in tablet samples with satisfactory results.

Biomimetic Mineralizated and Nano-Ag Loadedgraphene Oxide/Chitosan Hybrid Scaffold for Osteoinduction and Antibacterium

Graphene oxide (GO) is a graphene derivatives that has oxygen-containing functional groups on the graphene basal plane, such as hydroxyl, carbonyl, epoxy and carboxyl groups. GO is considered as a promising material for biological applications owing to its excellent surface functionalizability, high specific suface area and good biocompatibility. In this study, GO/chitosan hybrid scaffolds were prepared for tissue engineering. Nano silver was loaded into the scaffold to improve its antibacterial ability and biomimetic Ca-P coatings were deposited on the scaffold surface to enhance its osteoconductivity. First, GO was prepared by the chemical oxidization of graphite. Secondly, nano-Ag loaded GO was prepared by chemical reducing Ag ions in GO solutions. Then, nano-Ag loaded GO solution was mixed with CS solution to form GO-CS gel. Chitosan (CS) and GO were crosslinked by electrostatic interactions between oxygen-containing functional groups of GO and NH2 groups of CS. The gel were freeze dried to produce nano-Ag loaded GO/CS hybrid porous scaffolds. Finally, the as-prepared scaffolds were immersed the into a supersaturated calcium phosphate solution (SCPS) for 7 days to deposite CaP coatings on the surface of the micropores. SEM images showed that nano-Ag uniformly distributed in the scaffold and the CaP covered most of the scaffold surfaces. In vitro cell culture and antimicrobial test indicated the biomimetic mineralized Ag-CS-GO scaffolds have good osteoconductivity and bactericidal ability.

Adsorption of Quaternized-chitosan-modified Reduced Graphene Oxide

A novel quaternized-chitosan-modified reduced graphene oxide（HACC-RGO） combined the adsorption advantages of RGO and 2-Hydroxypropyltrimethyl ammonium chloride chitosan（HACC）. The adsorption property of HACC-RGO sheets for methyl orange（MO） was demonstrated and compared with RGO and HACC. The removal ratios of HACC-RGO sheets reached 92.6% for MO after a 24 h adsorption. The adsorption kinetics, isotherms and thermodynamics were investigated to indicate that the kinetics and equilibrium adsorptions were well-described by pseudo-second-order kinetic and Freundlich isotherm model, respectively. The thermodynamic parameters suggested that the adsorption process was spontaneous and endothermic in nature. Moreover, monodisperse HACC-RGO/CS beads were fabricated by the microfluidic method. The adsorption and desorption of HACC-RGO/CS beads for MO were studied. After three adsorptiondesorption cycles, the adsorption capacity remained above 55% and the desorption capacity was not below 70%. The HACC-RGO/CS beads can be reused and have great potential applications in removing organic dyes from polluted water.

Fabrication and Characterization of Graphene Based Nanocomposite for Electrical Properties

In the present study, we have described the synthesis of acid functionalized graphene (GE) which was grafted to chitosan (CH) by first reacting the oxidized GE with thionyl chloride to form acyl-chlorinated GE. This product was subsequently dispersed in chitosan and covalently grafted to form GE-chitosan. GE-chitosan was further grafted onto poly(anthranilic acid) (PAA) by free radical polymerization conditions, to yield GE-g-chitosan-g-PAA for our investigations. The structure of GE-CH-PAA composites was characterized by X-ray diffraction (XRD) pattern, Fourier transform infrared (FTIR) spectroscopy, thermo gravimetric analysis (TGA), cyclovoltammetrie (CV) and transmission electron microscopy (TEM). XRD report suggested the strongly crystalline character of the specimen prepared. The performance of cycle voltammeter was attributed to the GE-CH-PAA, which provided a large number of active sites and good electrical conductivity. Experimental results suggested that nanocomposites could be combined together for industrial applications.

基于壳聚糖改性的磁性氧化石墨烯的半自动化管尖固相微萃取技术在环境水中痕量铅快速测定中的应用

以戊二醛为交联剂,采用壳聚糖(CS)和四氧化三铁(Fe_(3)O_(4))修饰氧化石墨烯(GO),制备了Fe_(3)O_(4)-GO/CS复合物(吸附剂)。将20 mg Fe_(3)O_(4)-GO/CS填装于200μL微型枪头中,两端填上少量玻璃棉,枪头旁边放置磁铁。将12 mL塑料注射器和枪头连接,用塑料注射器吸取1 mL水冲洗Fe_(3)O_(4)-GO/CS表面可能吸附的杂质。环境水样经0.22μm滤膜过滤后,将滤液酸度调至pH6.0,用塑料注射器吸取10 mL,固定在注射泵上,将水样以0.8 mL·min^(-1)流量通过枪头;再吸取1 mL 0.010 mol·L^(-1)盐酸溶液(洗脱剂),以0.5 mL·min^(-1)流量洗脱吸附在Fe_(3)O_(4)-GO/CS上的铅。收集洗脱液,用电感耦合等离子体质谱法测定。结果显示:Fe_(3)O_(4)-GO/CS对铅的平衡吸附容量为126 mg·g^(-1),可重复使用50次,吸附过程符合朗缪尔(Langmuir)等温吸附模型;铅的质量浓度在0.01~10.00μg·L^(-1)内和响应值呈线性关系,检出限为0.005μg·L^(-1)。对实际水样进行3个浓度水平的加标回收试验,回收率为84.7%~105%,测定值的相对标准偏差(n=5)为0.90%~3.9%。

氧化石墨烯/壳聚糖水凝胶中羟基磷灰石的制备

羟基磷灰石(HA)具有良好的生物兼容性和骨传导性,但其机械强度低,制约了它的广泛使用.而氧化石墨烯(GO)和壳聚糖(CS)的复合材料独特的多孔状结构使其具有优秀的力学性能,因此将HA、GO和CS三者结合在一起所得到的复合物更能符合人们的需求.文章探究了交联剂作用下CS/GO复合水凝胶的制备,并以其为载体和模板在配位和静电吸引的协同效应下诱导调控HA的结晶.利用傅里叶红外光谱仪(FT-IR)、X线粉末衍射仪(XRD)和扫描电镜(SEM)对样品的结构和形貌进行了表征和测试.结果表明,在水热反应体系中磷酸肌酸二钠缓慢水解释放磷酸根更有利于类球形复合物HA/CS/GO的形成.该方法为制备具有生物相容性的HA/凝胶复合物提供了一条途径,并为其在潜在应用提供了基础研究和探讨.

改性氧化石墨烯/水性环氧复合涂层的制备及性能研究

为增进水性环氧树脂涂层的力学性能与耐腐蚀性,选用聚醚胺对氧化石墨烯(GO)边缘羧基进行化学改性,并与水性环氧树脂复合制备了改性氧化石墨烯/水性环氧(AGO/EP)复合涂层。探究了AGO的含量对复合涂层微结构、力学性能和耐腐蚀性的影响。结果表明:AGO在水性环氧中均匀分散且与水性环氧存在良好的界面作用,形成了一定有序层状结构,有效提升了水性环氧树脂涂层的拉伸强度与断裂伸长率。水性环氧复合涂层(0.5%AGO/EP)的低频阻抗模值达到4.47×10^(8)Ω·cm^(2),AGO的引入有效抑制了水汽和盐离子对钢板基材的腐蚀,复合涂层的耐盐雾腐蚀性能显著提高。

壳聚糖/聚苯胺⁃氧化石墨烯尼古丁分子印迹复合材料的制备与吸附性能研究

采用壳聚糖(CS)和聚苯胺(PANI)与氧化石墨烯(GO)交联构建了抗溶胀性的CS/PANI⁃GO尼古丁分子印迹复合材料。结果表明,其在水中浸泡10 h的溶胀率为2.7%。该复合材料作为吸附剂对尼古丁的吸附容量达到了198 mg/g。研究了吸附剂的选择吸附能力,对降烟碱和可替宁的吸附选择性系数分别达到了2.9和2.4,表明其具有良好的尼古丁特异性吸附性能。

可负载阿霉素的废弃生物质基多孔复合海绵的制备及性能

为了减轻阿霉素心脏毒性,通过载药材料靶向运输可减少阿霉素在心脏组织中的浓度,并且可通过载药材料使其应用于皮肤黑色素瘤的术后治疗与伤口愈合。现有的载药材料通常具有载药率或递送效率低的问题。利用海洋废弃生物质甲壳素提取的壳聚糖(CS)与聚乙二醇(PEG)通过溶液共混和冷冻干燥制成复合多孔海绵,并在制备过程中通过氢键与电荷吸引效应实现纳米氧化石墨烯(GO)片在前驱凝胶中的均匀分散,通过将GO吸附作用与PEG特有的载药性能结合用于提高多孔复合海绵对阿霉素载药效率。对PEG-CS多孔复合海绵的表面微观结构及力学性能进行了表征与测试,优选出PEG∶CS最佳质量比为15∶2。根据优选后的比例,进一步制备了含有不同GO浓度梯度的GO/PEG/CS多孔复合海绵(GPC-HS)。经验证其载药效率发现,GPC-HS中的孔隙结构提高了材料与药物接触面积,对阿霉素的载药率最高可达66.8%,并能进一步实现缓释效果,持续释放时间可被延长至50 h,并实现高达90%左右的释放率。上述结果表明,装载纳米GO片的PEG-CS多孔复合海绵具有提高阿霉素载药及递送效率的能力。

改良QuEChERS方法结合超高效液相色谱测定火腿肠中杂环胺类化合物

以火腿肠为研究对象,建立以磁性氧化石墨烯为基质净化材料的改良QuEChERS方法,结合超高效液相色谱(UPLC)技术快速测定火腿肠中4种杂环胺(IQ、Harman、Norharman和Phe-P-1)含量,利用方法学考查该方法的分析性能,并将其用于实际样品的检测。结果表明,与传统净化材料相比,所合成的磁性氧化石墨烯材料具有更高或相当的杂环胺回收效果和基质净化能力,可用作改良QuEChERS方法的净化材料。改良QuEChERS方法的适宜条件为:提取溶剂为碱化乙腈(含体积分数1%的氨水)、用水量1 mL、涡旋萃取时间5 min、萃取盐为无水Na_(2)SO_(4)/NaCl(用量0.50 g/0.13 g)、离心时间3 min,磁性氧化石墨烯用量7.5 mg、净化时间1 min。该条件下,4种杂环胺的R2均大于0.9995,在低、中、高浓度3个加标水平下杂环胺的回收率分别为99.9%~104.3%、101.2%~106.7%和85.7%~101.2%,检出限和定量限分别为0.71~1.52 ng/g和1.00~2.53 ng/g,日内及日间精密度分别低于4.4%和4.9%,精确度和精密度均良好。11种市售火腿肠均未检出4种HAAs,但检测到多种未知物质,且其含量均高于本文方法的定量限。与其他常用前处理技术相比,本文方法具有快速、简便、单样品成本低、有机溶剂用量少等特点,可用于火腿肠中杂环胺的检测。

3种多糖对猪肉糜脯中游离态和结合态杂环胺及品质的影响

探讨桑葚多糖、壳聚糖、草菇多糖3种多糖对猪肉糜脯中杂环胺(heterocyclic aromatic amines,HAAs)形成及物理品质的影响。结果表明:猪肉糜脯中共检出9种游离态HAAs和6种结合态HAAs;添加桑葚多糖和壳聚糖可以显著抑制9H-吡啶并[3,4-b]吲哚(9H-pyrido[3,4-b]indole,Norharman)、1-甲基-9H-吡啶并[3,4-b]吲哚(1-methyl-9H-pyrido[3,4-b]indole,Harman)、3-氨基-1,4-二甲基-5H-吡啶并[4,3-b]吲哚(3-amino-1,4-dimethyl-5H-pyrido[4,3-b]indole,Trp-P-1)、2-氨基-3,4-二甲基咪唑并[4,5-ƒ]喹啉、2-氨基-3,8-二甲基咪唑并[4,5-ƒ]喹喔啉(2-amino-3,8-dimethyl-imidazo[4,5-f]quinoxaline,MeIQx)5种游离态HAAs和Norharman、Harman、Trp-P-1、MeIQx、2-氨基-1-甲基-6-苯基咪唑并[4,5-b]吡啶5种结合态HAAs的生成(P<0.05),且桑葚多糖抑制效果更佳;抑制蛋白质氧化是多糖减少猪肉糜脯中HAAs生成的最主要途径,其次为抑制脂质氧化和Maillard反应途径;桑葚多糖和壳聚糖可能通过清除2,2’-联氮-双(3-乙基-苯并噻唑啉-6-磺酸)阳离子自由基、抑制蛋白质氧化、脂质氧化和Maillard反应,进而减少猪肉糜脯加工过程中游离态和结合态HAAs的生成,且桑葚多糖对猪肉糜脯的色泽和质构均无显著影响。由此可见,桑葚多糖具有提升猪肉糜脯质量安全的应用潜力,可促进传统肉制品产业高质量发展。

正电性碳纳米材料对水性聚氨酯性能的影响

碳纳米材料如氧化石墨烯、碳纳米管等作为高性能填料近年来得到诸多关注与研究。通过物理共混法制备了氮掺杂石墨烯/水性聚氨酯(N-GO/WPU)和氨基化碳纳米管/水性聚氨酯(CNT-NH_(2)/WPU)两种复合材料。研究结果表明,当碳纳米材料用量为2%时,复合材料的物理力学性能最好,N-GO/WPU和CNT-NH_(2)/WPU的拉伸强度、断裂伸长率、杨氏模量分别为41.3 MPa、745.2%、10.3 MPa和43.2 MPa、825.1%、12.4 MPa。5%碳纳米材料用量下,复合材料电磁屏蔽性能和疏水性能最佳,N-GO/WPU和CNT-NH_(2)/WPU的电阻、水接触角分别为2.10×10^(9)Ω、78.3°和8.70×10^(10)Ω、76.6°。从粒子性能上看,复合材料的综合性能与碳纳米材料在聚氨酯基质中的分散能力有关。

硫化铜/氧化石墨烯/壳聚糖/纳米羟基磷灰石复合材料的抗菌及促成骨作用

目的探讨硫化铜(CuS)/氧化石墨烯(GO)/壳聚糖(CS)/纳米羟基磷灰石(nHA)复合材料(CGCHs)的抗菌和促成骨作用及其作用机制。方法采用水热法合成CuS/GO纳米颗粒,通过原位沉淀法合成CS/nHA支架和CGCHs支架,检测材料表征、光热转换性能和生物安全性,评估CGCHs组和近红外光(NIR)照射下CGCHs(CGCHs+NIR)组的细菌抑制效果及其对细菌生物膜相关基因表达的影响,观察CGCHs和CS/nHA不同材料组的促成骨分化和成骨、破骨相关基因表达。结果CGCHs是具有高度孔隙率的三维支架,在CuS/GO浓度为200μg/mL时CGCHs同时兼具良好的红外升温效果和生物安全性。琼脂糖平板涂菌和细菌死活染色结果均表明CGCHs+NIR组抗菌性能最佳,生物膜相关基因qPCR检测证实其具有抑制细菌生物膜相关基因表达的作用。茜素红染色结果表明CGCHs具有良好的体外促成骨性能,体外共培养3、7、14、21和28 d qPCR结果表明CGCHs对成骨早期和晚期相关基因表达均具有促进作用。与破骨细胞共培养结果可观察到CGCHs具有抑制破骨细胞形成的作用,细胞凋亡检测结果进一步验证这一结论,破骨分化相关基因qPCR检测结果表明,CGCHs主要通过抑制抗酒石酸酸性磷酸酶、组织蛋白酶K、CTR、P65和P38在共培养7、14 d的表达来抑制破骨细胞的分化。结论作为纳米复合材料,CGCHs生物安全性好,具有良好的红外光热协同抗菌作用,在促成骨分化的同时抑制破骨细胞分化,有望为感染性骨缺损治疗提供新的思路。

Voltammetric Determination of Epinephrine in the Presence of Uric Acid Based on Aminated Graphene and Ag NPs Hybrid Membrane Modified Electrode

A hybrid membrane consisted of aminated graphene and Ag nanoparticles（Ag NPs） was prepared on the surface of glassy carbon electrode（GCE） by cyclic voltammetry（CV） with aminated graphene（GR-NH2） as matrix for immobilizing Ag NPs.The morphology and electrochemical properties of this hybrid membrane were characterized by scanning electron microscopy（SEM） and CV,respectively,and on this membrane,the voltammetric behaviors of epinephrine（EP） were studied in detail.The membrane exhibited excellent eletro-catalytic activities for the redox of EP,and could resolve the electrochemical response of EP and uric acid（UA） into two oxidation peaks.The peak current of EP was linear with its concentration in the ranges of 0.916-18.3 μmol/L and 18.3-184 μmol/L.The detection limit was 2.0 nmol/L（S/N=3）.The proposed modified electrode retained the advantages of easy fabrication,high sensitivity and good repeatability for the determination of EP.

端羟基超支化聚(胺-酯)非共价改性氧化石墨烯

采用改进的Hummer方法制备了氧化石墨烯(GO),并利用端羟基超支化聚(胺-酯)对其非共价功能化。采用傅里叶变换红外光谱(FT-IR)、拉曼光谱(Raman)、X射线衍射(XRD)、扫描电镜(SEM)和热重分析(TG)及紫外可见分光光度等方法对氧化石墨烯表面改性的性能进行了分析。FT-IR,Raman,XRD和TG分析结果表明,超支化聚(胺-酯)分子成功改性了氧化石墨烯;XRD分析表明,随着超支化聚(胺-酯)含量的增加,石墨烯片层层间距增大,这说明超支化分子能够渗透插入到氧化石墨烯片层之间;Raman分析表明,吸附在氧化石墨烯表面的超支化聚(胺-酯)提高了氧化石墨烯表面的无序化程度和石墨烯结构的不完善程度。SEM形貌分析表明超支化聚(胺-酯)大分子覆盖在氧化石墨烯的表面上,且通过对改性前后氧化石墨烯在乙醇和正己烷中透光率的对比,表明改性后的氧化石墨烯分散性能得到了明显提高。

聚醚胺接枝氧化石墨烯对沥青性能的影响

为了改善氧化石墨烯(GO)在沥青基体中的分散性,提升GO及其衍生物改性沥青的性能,合成了聚醚胺接枝氧化石墨烯(PEA-GO)并通过傅里叶红外光谱(FTIR)试验和X射线衍射光电子能谱(XPS)对聚醚胺接枝前后的GO进行化学结构表征,验证了PEA-GO的成功合成.对不同掺量GO及PEA-GO改性沥青的性能规律进行了分析,结果表明:相较于GO,PEA-GO对沥青常规性能的改善作用更加明显.在相同掺量下,PEA-GO改性沥青的针入度、延度、软化点均高于GO改性沥青,而PEA-GO改性沥青的黏度低于GO改性沥青.在相同掺量下,PEA-GO改性沥青的G^(*)、G^(*)/sinδ均高于GO改性沥青,当PEA-GO的掺量为沥青质量的0.05%时,改性沥青的G^(*)最高,且PEA-GO改性沥青的δ均低于GO改性沥青,表明PEA-GO对沥青的高温抗变形能力、弹性恢复能力、抗车辙能力的改善优于GO.