电纺制备海藻酸辛酰胺/聚乙烯醇纤维及其性能研究

采用辛胺对海藻酸钠(SA)进行疏水改性得到具有两亲性的海藻酸辛酰胺(OAAD),并用静电纺丝法制出SA/聚乙烯醇(PVA)纤维和OAAD/PVA纤维。通过红外光谱仪、核磁共振波谱仪、表面张力仪、荧光光谱仪、电导率仪、扫描电镜和接触角测量仪分别对OAAD,电纺液和电纺纤维的性能进行了表征。结果表明,辛胺基成功接枝到SA分子链上,OAAD的表面张力比SA低,荧光实验测得OAAD的临界聚集质量浓度为0.60 g·L-1,改善了SA的疏水性。通过对比SA/PVA和OAAD/PVA电纺纤维在水中的溶解性能和疏水性能,发现改性海藻酸盐电纺纤维在水中完全溶解时间由5 h变为48 h,其接触角由31°增大至57°,这表明OAAD/PVA电纺纤维的抗水性和疏水性较SA/PVA电纺纤维得到了改善。     

差别化纤维

<正>TQ 342.820145159用于伤口敷料的静电纺皮芯型纳米纤维Cheng Feng…;Chemical Fibers International,2014,64(1),p.34(英)通过共轴静电纺制备海藻酸钠(SA)-聚乙烯醇(PVA)皮芯结构纳米纤维,SA为芯、PVA为皮。由于SA纳米纤维具有良好的止血、亲水、生物降解性能且无毒,它在生物医药领域有很大的应用潜力。然而,由于高电导率的聚电解质,分子中的斥力阻碍了SA的静电纺丝。但PVA能很容易地静电纺成纳米纤维,并且PVA纳米纤维具有很高     

添加不同物质的聚乙烯醇/海藻酸钠静电纺丝研究

分别添加少量NaCl、乙酸、表面活性剂十二烷基硫酸钠(SDS),研究少量添加物对海藻酸钠/聚乙烯醇(PVA)溶液性质和静电纺纤维的影响,并初步探讨了溶液静电纺丝机制。结果表明:NaCl改变了溶液的电导率和黏度,乙酸降低了溶液的黏度、提高了溶剂挥发性,SDS降低了溶液的表面张力;适量的添加物可使纤维形貌得到改善;添加物对电纺纤维化学结构无本质影响;无机盐离子加剧了纤维拉伸作用,结晶性有所提高;处于泰勒锥处液滴表面受到静电排斥力、表面张力、同种聚合物分子间的氢键作用力、不同聚合物分子间的氢键作用力以及聚合物同水等溶剂形成的氢键作用力。     

聚乙烯醇/壳聚糖复合电纺纤维膜的制备及表征

利用静电纺丝法制备了聚乙烯醇PVA/壳聚糖CS纳米纤维复合膜,并采用戊二醛蒸气对其交联处理。通过扫描电子显微镜(SEM)观察探讨了不同质量配比、助纺剂的添加以及电纺环境条件对复合纤维膜纤维直径及表面形貌的影响。通过傅里叶变换红外光谱(FTIR)对PVA/CS复合纳米纤维膜做了特征官能团分析,并对其热力学性能及其耐水性进行了表征。结果表明滴加7%(V/V)二甲基亚砜、0.5%(V/V)丙三醇、0.5%(V/V)吐温80的3%(V/V)的乙酸为溶剂,PVA和CS质量配比为90/10,环境湿度0±15%电纺条件下制备的复合纤维形态均一,无珠串无液滴;FTIR研究显示,复合纤维的两种组分发生一定的相互作用,成功制备了戊二醛交联PVA/CS纳米纤维膜;热重(TG)、差热(DSC)结果都进一步说明CS和PVA之间形成氢键,戊二醛交联后复合纤维的热稳定性进一步增强。交联前后纤维膜的耐水性结果表明交联后的共混纤维膜有良好的抗溶解性,在水中可以很好的保持纤维的结构。     

PVA／MC纳米纤维膜的制备与吸水性、保水性研究

采用水热工艺和电纺方法制备了PVA／MC纳米纤维膜;对PVA／MC混和溶液的粘度、PVA／MC纳米纤维膜的结构、吸水性能和保水性能进行了研究。结果表明,随着MC含量的增加,PVA／MC混和溶液的粘度逐渐增大;FESEM表明,本身不能电纺的MC在与PVA混和则可以电纺制得PVA／MC纳米纤维膜,但随着MC含量的增加,混和溶液的粘度会逐渐增大而无法电纺;在不改变电压的情况下增大电纺的接受距离,所得PVA／MC纤维膜连续、直径均匀、表面光滑平整;吸水性能和保水性能研究表明,随着MC含量的增加,PVA／MC纳米纤维膜的吸水速率和保水性能逐渐提高。     

PVDF/PANI-TSA复合纤维膜的电纺制备及电性能

利用电纺技术制备了对甲苯磺酸掺杂的聚苯胺(PANI-TSA)/聚偏氟乙烯(PVDF)复合电纺纤维膜。并用电导率仪,SEM,静电电位计,电化学工作站,力学试验机等进行表征。研究表明PANI-TSA的加入增强了纺前溶液的电导率,显著提高了膜的电导率和抗静电性能。同时由于部分PANI-TSA没有溶解,以颗粒状存在纤维中,纤维表面因此变得粗糙,拉伸强度略有降低。     

妇科抢救用抗菌止血敷料制备及应用

针对妇科抢救用止血敷料止血效果不佳，抗菌性能差的问题，提出用PVA/SA止血海绵和CS/PVA纳米纤维膜通过热熔压敏胶粘合制备新型止血敷料，并探讨了制备过程中，PVA/SA止血海绵中海藻酸钠的最佳含量、工艺和抗菌止血效果。结果表明：PVA/SA止血海绵中海藻酸钠最佳含量为2.5%；纳米纤维膜最佳纺丝工艺为电压21 kV、纺丝液流量0.4 mL/h、接收距离13 cm；在此工艺下制备的纳米纤维膜经过戊二醛交联后，性能较为稳定；与PVA/SA止血海绵粘合成的新型敷料止血性能和抑菌性能皆表现良好。     

海藻酸钠/聚乙烯醇溶液的性能及静电纺丝

将质量分数为2%的海藻酸钠(SA)与质量分数为8%的聚乙烯醇(PVA)按一定体积比混合后进 行静电纺丝,研究了SA与PVA溶液的相容性及SA/PVA共混溶液性能.结果表明:SA与PVA溶液相容;随着PVA含量的增加,SA/PVA共混溶液的粘度、表面张力、电导率则降低,共混溶液的可纺性提高;静电纺丝得到的SA/PVA超细...     

静电纺丝PBT/PVA复合膜的制备及性能研究

以三氟乙酸和二氯甲烷为混合溶剂,采用静电纺丝法制备聚对苯二甲酸丁二酯(PBT)/聚乙烯醇(PVA)复合膜。用旋转粘度计和电导率仪测定溶液的黏度和电导率,用扫描电子显微镜、拉伸和水接触角测试PBT/PVA不同比例对纤维膜的形貌、力学和亲水性能的影响。结果表明,随着PVA比例的增加,混合溶液的黏度逐渐增大,而电导率先增大后减小;当PBT/PVA的比例为90/10时,纳米纤维的平均直径最小,为323 nm,而其纳米纤维膜的力学性能与纯PBT纤维膜相比显著提高,拉伸强度、弹性模量和断裂伸长率分别增加了213%,260%和57%;PVA的加入改善PBT纤维的亲水性,制备出力学性能优异且亲水的PBT/PVA纤维膜。     

海藻酸辛酰胺协同纳米二氧化硅稳定Pickering乳液

采用辛胺疏水改性海藻酸钠合成了具有两亲性的高分子表面活性剂海藻酸辛酰胺(OAAD),并将其与SiO2纳米颗粒协同制备了稳定的Pickering乳液。通过FTIR、1HNMR、表面张力、荧光光谱、动态光散射、接触角测量、光学显微镜分别对OAAD、OAAD/SiO2纳米颗粒水分散体系和Pickering乳状液的性能进行了表征。结果表明,辛胺氨基成功接枝到海藻酸钠(SA)分子链上,OAAD界面张力较SA降低、临界聚集质量浓度为0.60 g/L,表现出良好的两亲性。将OAAD吸附在SiO2纳米颗粒表面形成的水分散体系用于稳定Pickering乳液时,发现随着OAAD质量浓度增加,SiO2纳米颗粒润湿性增加,Zeta电位减少,粒径增加;而乳液的粒径则逐渐减少,稳定性增强,其机理经初步分析为,当一定浓度的OAAD吸附在SiO2纳米颗粒表面,可导致颗粒间絮凝,从而在油水界面形成网络结构式界面膜,有利于提高Pickering乳液的稳定性。     

Electrospinning fabrication and characterization of poly(vinyl alcohol)/waterborne polyurethane nanofiber membranes in aqueous solution

Poly(vinyl alcohol) (PVA)/waterborne polyurethane (WBPU) nanofiber mats were prepared using electrospinning method with aqueous solutions. Scanning electron microscopy (SEM), X‐ray diffraction (XRD), thermal gravimetric analyzer (TGA), and tensile strength testing machine (ZWICK) were used to characterize the morphology and properties of the PVA/WBPU nanofiber mats. The results showed that the morphologies of PVA/WBPU nanofiber mats changed with the total solid concentration and the mass ratio of PVA/WBPU in the spinning solution. The tensile strength and thermal stability of the fibers could be significantly affected by the WBPU contents. The electrospun PVA/WBPU membranes showed higher water uptake, which would have potential applications in wound dressings. © 2010 Wiley Periodicals, Inc. J Appl Polym Sci, 2011     

Preparation of atactic poly(vinyl alcohol)/sodium alginate blend nanowebs by electrospinning

Through the blending of a rigid polymer, sodium alginate (SA), and a flexible polymer, atactic poly(vinyl alcohol) (PVA), with various ratios of SA and PVA and through the electrospinning of SA/PVA solutions, SA/PVA blend nanowebs were successfully prepared. The structure and morphology of the SA/PVA blend nanowebs were investigated through a series of instrumental analyses. Through the examination of the morphological variations of each blend web, it was found that with only PVA, the electrospun nanowebs had very uniform and fine fiber structures, but the SA/PVA blend nanowebs had a mixture of large beads and fibers, which were generated with increasing SA content. A thermal analysis indicated that the endothermic peaks of the SA/PVA blend nanowebs decreased with an increase in the SA content. The SA content was determined by the observation of the changes in the SA peak intensity via Fourier transform infrared spectroscopy. The tensile strength decreased with increasing SA content. © 2007 Wiley Periodicals, Inc. J Appl Polym Sci 2007     

Super-hydrophilic electrospun PVDF/PVA-blended nanofiber membrane for microfiltration with ultrahigh water flux

This work provides a novel approach to improve not only water flux but also fouling resistance of Polyvinylidene fluoride (PVDF) membranes. PVDF/Poly(vinyl alcohol) (PVA)-blended nanofiber membranes were prepared via electrospinning method. The structure and performance of blended nanofiber membranes were characterized by scanning electron microscopy (SEM), atomic force microscope (AFM), attenuated total reflection-Fourier-transform infrared (ATR-FTIR) spectroscopy, X-ray photoelectron spectroscopy (XPS), contact angle measurement, tensile mechanical measurement, and filtration experiments. These results indicate that PVA was uniformly blend in the PVDF matrix. This blended nanofiber membranes with the ridge-and-valley structure and bicontinuous phase exhibited the hydrophilic performance and super-wettability, which is reflected in a drop of water fully spread within 1.44 s. Filtration experiments showed that the blended nanofiber membranes have ultrahigh flux and low irreversible fouling ratio. In general, this work enhances the possibility of hydrophilic modification of hydrophobic PVDF membranes. © 2019 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2020 , 137, 48416.     

A novel type of waterborne fluorescent nanofiber membranes with effectively suppressed ACQ phenomenon: Fabrication,properties, and applications

In this research, a novel type of waterborne fluorescent nanofiber membranes (WNFM) based on fluorescent acrylic latex (FAL) has been developed by electrospinning method using environment-friendly water as the spinning solvent. FALs are synthesized by doping Rhodamine B (Rh B) into acrylate monomers through emulsion polymerization, and then polyvinyl alcohol (PVA) is added to fabricate a series of WNFM via electrospinning process. As the hydrophilic emulsifier sodium dodecyl sulfate enriches on the surface of the latex, a portion of Rh B can be adsorbed onto the surface of FAL and form an electrical double layer to prevent its aggregation, which accounts for the enhancement in fluorescence of FALs. The relationships between the preparation conditions, morphology and properties of WNFM have been studied with a combination of techniques including fluorometry and microscopies. The developed waterborne fluorescent nanofiber membranes demonstrate a good water-resistant property with a linear response of photoluminescence intensity to temperature for many cycles. The study points a new direction to develop the nanofiber membrane using environment-friendly water as a spinning solvent in electrospinning and realize its fluorescent functionalization.     

Electrospinning of heated gelatin‐sodium alginate‐water solutions

Most polymers that are electrospun are dissolved in a solvent and are spun at ambient temperature. Gelatin, a natural polymer, has excellent potential in medical applications as a biodegradable polymer, especially when combined with sodium alginate. Unfortunately, gelatin/water or gelatin/sodium alginate/water solutions cannot be electrospun at ambient temperature without the incorporation of substances that are considered potentially toxic to the human body, such as acetic acid. In this study, gelatin/water solutions with and without sodium alginate were successfully electrospun without the use of additional solvents by using heated water solutions. The effect of electrospinning parameters such as solution concentration and applied voltage on the nanofiber morphology of these solutions was studied. These nanofibers from heated gelatin/water solutions exhibited good morphology with an average size of 291 ± 67 nm at 18% concentration to 414 ± 52 nm at 20% concentration. Similar sizes were observed when sodium alginate was incorporated into the gelatin/water solutions, although the relationship was dependent upon the amount of sodium alginate in the solution as well as the total concentration. Typically, these nanofibers containing sodium alginate were produced at a lower gelatin concentration compared with the gelatin/water nanofibers because of the increase of viscosity and conductivity of the solutions due to the addition of the highly viscous and conductivity sodium alginate. POLYM. ENG. SCI., 2009. © 2009 Society of Plastics Engineers     

“Dialdehyde Cellulose” Nanofibers by Electrospinning as Polyvinyl Alcohol Blends: Manufacture and Product Characterization

A nanofiber was obtained by electrospinning of “dialdehyde cellulose” (periodate-oxidized cellulose, DAC) and polyvinyl alcohol (PVA), using only water as the solvent. Celluloses of four different origins were fully oxidized with sodium periodate to water-soluble DAC. Aqueous solution of DAC showed inadequate spinnability regardless of the polymer concentration and the electrospinning conditions used. Addition of PVA improved the solution's viscoelasticity and, consequently, the solution's spinnability. We examined the effects of DAC/PVA composition and electrospinning parameters on fiber morphology. Highly homogeneous nanofibers were prepared from 1:1 up to 2:1 (weight) DAC/PVA blends while samples of lower viscosity or higher relative DAC contents resulted in continuous, beaded fiber networks. Characterization of the electrospun fabrics revealed a highly crosslinked DAC structure reinforced with PVA, strongly interacting through hemiacetal bonds and hydrogen bonding. Fluorescence labeling confirmed the presence of reactive aldehyde functionalities in the electrospun web. The versatile properties of DAC as reactive material can now be imparted on electrospun fiber and nanofiber material – which was not possible so far –further widening the application scope of this interesting cellulose derivative.     

海藻酸钠/聚乙烯醇/银复合纤维的静电纺丝

采用静电纺丝方法,在不同海藻酸钠/聚乙烯醇质量比、含银量、纺丝电压、纺丝液流速、接收距离条件下,制备了海藻酸钠/聚乙烯醇/银复合纤维,利用扫描电镜分析了纤维直径分布及形态。结果表明:海藻酸钠与聚乙烯醇的质量比和含银量对复合纤维成纤性和纤维形态的影响较为显著。海藻酸钠与聚乙烯醇质量比为2∶8、银占溶质质量分数的0.1%、纺丝电压为20 kV、纺丝液流速为0.1 mL/h、接收距离为8 cm时,纺丝效果最佳,纤维形态最好。     

Mechanical reinforcement of electrospun water‐soluble polymer nanofibers using nanodiamonds

Optimization of the mechanical properties is necessary in the applications of electrospun nanofibrous matrices. In this work, mechanical reinforcement of electrospun nanofiber membranes of water‐soluble polymer by the incorporation of commercial nanodiamonds (NDs) was studied. Through an ND/poly(vinyl alcohol) (ND/PVA) model system, it is demonstrated that 155% improvement of Young's modulus, 89% increase in tensile strength, and 336% elevation in energy to break are achieved by the addition of only 2 wt% ND. Fourier transform infrared spectroscopy results suggest the existence of molecular interactions between NDs and PVA matrix, which contributes to the effective load transfer from the polymer matrix to the fillers. However, higher level of ND addition (>2 wt%) aggravates the agglomeration of nanofillers in PVA matrix and offsets the reinforcing effect, as ND agglomerates may act as flaws in composite nanofibers. Furthermore, NDs have optimizing effect on the morphology of ND/PVA nanofibers through increasing the conductivity of the electrospinning solution. Therefore, ND nanofillers possess the potential to improve the mechanical performance of water‐soluble polymer‐based nanofiber membranes. POLYM. COMPOS., 34:1735–1744, 2013. © 2013 Society of Plastics Engineers     

4-Vinylbenzene Boronic Acid–Hydroxy Apatite/Polyvinyl Alcohol Based Nanofiber Scaffold Synthesized by UV-Activated Reactive Electrospinning

In this study, we prepared photo-crosslinked modified HAP (hydroxy apatite)/polyvinyl alcohol (PVA) composite nanofiber scaffold for cell growth applications. HAP was synthesized and then modified with 4-vinylbenzene boronic acid (VBBA) to obtain 4-VBBA-HAP. By means of the simultaneous UV electrospinning technique 4-VBBA-HAP/PVA composite was obtained. The structure and morphology of electrospun membranes were investigated by scanning electron microscopy) and Fourier transform infrared spectroscopy technique. Nanofibers were treated with collagen solution via the spraying method. For the cell culture applications ECV304 and SAOS cells were seeded on the chosen electrospun fibrous scaffolds.