ナノファイバー膜とは何ですか?
Nanofibrous Membranes ナノファイバー膜 - A series of functional nanoparticles and nanofibrous membranes was prepared using oil bath heating method, calcination method, and modified tri–axial electrospinning technology. [1] It identifies theoretical gaps related to the physical phenomena which can be responsible for the observed acoustical behaviours of nanofibrous membranes and it presents recommendations to fill these gaps. [2] In this work, a series of the organic polymer template-modulated yttria doped zirconia (YDZ) nanofibrous membranes with lightweight, superior mechanical and thermal stability are developed through a cost-effective, scalable sol-gel electrospinning and subsequent calcination method. [3] Further eye-observation, micro-morphology investigation and tensile tests were applied to evaluate the chemical resistance of nanofibrous membranes in strong acid, strong alkaline, and concentrated salt. [4] These daylight-driven rechargeable micro/nanofibrous membranes can be used in the development of reusable medical protective materials with highly efficient filtration and daylight-driven rechargeable antibacterial efficacy. [5] In the present work, hybrid polyacrylonitrile (PAN) nanofibrous membranes were developed for oily wastewater filtration. [6] As a stable chemical material, polypropylene (PP) micro-nanofibrous membranes are widely used in medical and health care. [7] Methods Different layers of VEGF-A loaded polycaprolactone (PCL) nanofibrous membranes were first synthesized by using layer-by-layer (LBL) self-assembly of electrospinning methods. [8] The surface morphology of the nanofibrous membranes was studied using field emission scanning electron microscopy. [9] In this work, flexible silica dioxide (SiO2) nanofibrous membrane (NFM) was fabricated by an electrospinning technique and MnO2 nanoparticle was successfully loaded on SiO2 (MnO2@SiO2) nanofibrous membranes (NFMs) through liquid phase synthesis. [10] In the current study, we explore the use of an eco-friendly laser-based methodology to fabricate Ag/TiO nanoparticles (NPs) with a highly controlled chemical composition, which serve to decorate the surface of Polyvinylidenefluoride (PVDF) nanofibrous membranes. [11] Micro-CT and histopathological evaluations revealed that nanofibrous membranes with CeO2 NPs further accelerated new bone formation. [12] However, endowing the nanofibrous membranes with antibacterial and angiogenesis functions needs to be explored. [13] Herein, we report a respiration monitoring triboelectric nanogenerator (RM-TENG) with nanofibrous membranes, which can be used as a smart, changeable, self-powered mask filter with high filtration efficiency for monitoring multiple respiratory indices (e. [14] Finally, the development of nanofibrous membranes was prospected with the aim of providing directional guidance for improvement of air purification field. [15] 4% after 240 min of continuous irradiation upon increasing the concentration of Au/Se nanoparticles through the nanofibrous membranes. [16] Methylene blue is degraded under visible light irradiation in the presence of the nanofibrous membranes of PCL containing modified HAP with different contents of Cu ions. [17] Herein, flexible zirconium doped strontium titanate (ZSTO) nanofibrous membranes were fabricated via combining sol-gel and electrospinning methods. [18] The functionalization of nanofibrous membranes (NFMs) is a prevailing and promising strategy to prepare highly efficient air filters for high-precision filtration. [19] Here we review the principles, performances, advantages and disadvantages of these techniques, with focus on catalytic oxidation, adsorption and the use of nanofibrous membranes. [20] This study explored the use of sandwich-structured antimicrobial agents, analgesics, and human epidermal growth factor (hEGF)-incorporated anti-adhesive poly(lactic-co-glycolic acid) nanofibrous membranes for surgical wounds. [21] 4 µm pore size and prepared Poly (L-lactide-co-DL-lactide) (PDLLA) nanofibrous membranes with an average pore size of 0. [22] The presented review article in detail describes novel strategies for renal failure treatment with the use of various nanomaterials (including carbon nanotubes, nanofibrous membranes), mesenchymal stem cells-derived nanovesicles, and nanomaterial-based adsorbents and membranes that are used in wearable blood purification systems and synthetic kidneys. [23] In this paper, polysulfone (PSF)/cellulose nanocrystal (CNC) nanofibrous membranes were fabricated by electrospinning as hybrid interleaves in CF/EP composites. [24] Finally, the most efficient binary nanostructures were successfully embedded in nanofibrous membranes by colloidal electrospinning and used in water remediation experiments in a flow-through reactor. [25] Based on the dimensions, nanofibrous materials can be categorized into nanofibrous membranes and nanofibrous aerogels. [26] Large porous framework provided a high surface area to effectively immobilize the cross-linked chitosan on nanofibrous membranes. [27]一連の機能性ナノ粒子とナノファイバー膜は、油浴加熱法、煆焼法、および修正された三軸エレクトロスピニング技術を使用して調製されました。 [1] ナノファイバー膜の観察された音響挙動の原因となる可能性のある物理現象に関連する理論上のギャップを特定し、これらのギャップを埋めるための推奨事項を示します。 [2] この作業では、軽量で優れた機械的および熱的安定性を備えた一連の有機ポリマーテンプレート変調イットリアドープジルコニア(YDZ)ナノファイバー膜が、費用効果が高く、スケーラブルなゾルゲルエレクトロスピニングとその後の煆焼法によって開発されます。 [3] 強酸、強アルカリ、および濃縮塩におけるナノファイバー膜の耐薬品性を評価するために、さらなる眼の観察、微細形態の調査、および引張試験が適用されました。 [4] これらの昼光駆動の充電式マイクロ/ナノ繊維膜は、非常に効率的なろ過と昼光駆動の充電式抗菌効果を備えた再利用可能な医療用保護材料の開発に使用できます。 [5] 本研究では、ハイブリッドポリアクリロニトリル(PAN)ナノファイバー膜が油性廃水ろ過用に開発されました。 [6] 安定した化学材料として、ポリプロピレン(PP)マイクロナノ繊維膜は医療や健康管理で広く使用されています。 [7] 方法VEGF-Aをロードしたポリカプロラクトン(PCL)ナノファイバー膜のさまざまな層は、エレクトロスピニング法のレイヤーバイレイヤー(LBL)自己組織化を使用して最初に合成されました。 [8] ナノファイバー膜の表面形態は、電界放出走査型電子顕微鏡を使用して研究された。 [9] この作業では、柔軟な二酸化ケイ素(SiO2)ナノファイバー膜(NFM)がエレクトロスピニング技術によって製造され、MnO2ナノ粒子が液相合成によってSiO2(MnO2 @ SiO2)ナノファイバー膜(NFM)に正常にロードされました。 [10] 現在の研究では、環境に優しいレーザーベースの方法論を使用して、ポリフッ化ビニリデン(PVDF)ナノファイバー膜の表面を装飾するのに役立つ高度に制御された化学組成を持つAg / TiOナノ粒子(NP)を製造する方法を検討します。 [11] マイクロCTおよび組織病理学的評価により、CeO2NPを含むナノファイバー膜が新しい骨形成をさらに加速することが明らかになりました。 [12] ただし、抗菌および血管新生機能をナノファイバー膜に与えることを検討する必要があります。 [13] ここでは、ナノファイバー膜を備えた呼吸モニタリング摩擦電気ナノ発電機(RM-TENG)を報告します。これは、複数の呼吸指標をモニタリングするための高いろ過効率を備えた、スマートで交換可能なセルフパワーマスクフィルターとして使用できます(e。 [14] 最後に、空気浄化分野の改善のための方向性ガイダンスを提供することを目的として、ナノファイバー膜の開発が見込まれました。 [15] ナノファイバー膜を介してAu/Seナノ粒子の濃度を上げると、240分の連続照射後に4%。 [16] メチレンブルーは、Cuイオンの含有量が異なる修飾HAPを含むPCLのナノファイバー膜の存在下で、可視光照射下で分解されます。 [17] ここでは、柔軟なジルコニウムドープチタン酸ストロンチウム(ZSTO)ナノファイバー膜は、ゾルゲル法とエレクトロスピニング法を組み合わせて製造されました。 [18] ナノファイバー膜(NFM)の機能化は、高精度のろ過のための高効率のエアフィルターを準備するための一般的で有望な戦略です。 [19] ここでは、触媒酸化、吸着、およびナノファイバー膜の使用に焦点を当てて、これらの技術の原理、性能、長所と短所を確認します。 [20] この研究では、サンドイッチ構造の抗菌剤、鎮痛剤、およびヒト上皮成長因子(hEGF)を組み込んだ抗接着性ポリ(乳酸-co-グリコール酸)ナノファイバー膜を外科的創傷に使用することを検討しました。 [21] 4 µmのポアサイズと、平均ポアサイズが0のポリ(L-ラクチド-co-DL-ラクチド)(PDLLA)ナノファイバー膜を準備しました。 [22] 提示された総説では、さまざまなナノ材料(カーボンナノチューブ、ナノファイバー膜を含む)、間葉系幹細胞由来のナノベシクル、およびウェアラブル血液浄化システムで使用されるナノ材料ベースの吸着剤と膜を使用した腎不全治療の新しい戦略について詳しく説明しています。と合成腎臓。 [23] この論文では、ポリスルホン(PSF)/セルロースナノクリスタル(CNC)ナノファイバー膜は、CF/EP複合材料のハイブリッドインターリーブとしてエレクトロスピニングによって製造されました。 [24] 最後に、最も効率的なバイナリナノ構造は、コロイドエレクトロスピニングによってナノファイバー膜にうまく埋め込まれ、フロースルーリアクターでの水浄化実験に使用されました。 [25] 寸法に基づいて、ナノファイバー材料は、ナノファイバー膜とナノファイバーエアロゲルに分類することができます。 [26] 大きな多孔質フレームワークは、架橋キトサンをナノファイバー膜に効果的に固定化するための高い表面積を提供しました。 [27]
high specific surface 高比表面積
Here, facile access to mesoporous structured silica nanofibrous membranes (MPSNMs) with superior flexibility, high specific surface area, and large mesopore volume is provided, that is, using phase separation-driven electrospinning technique and subsequent calcination processing. [1] Among various techniques for the membrane fabrication, electrospinning with advantages of ease in mass production and potential incorporation of other functional materials on the nanoscale surface has gained widespread interest for the preparation of novel nanofibrous membranes with selective wettability, rational pore structure and high specific surface area. [2] Nanofibrous membranes have a high specific surface area and large porosity, which are beneficial for being used as adsorbents to remove heavy metal ions from water. [3]ここでは、優れた柔軟性、高い比表面積、および大きなメソ細孔容積を備えたメソポーラス構造化シリカナノファイバー膜(MPSNM)への容易なアクセスが提供されます。つまり、相分離駆動エレクトロスピニング技術とその後の焼成処理が使用されます。 [1] 膜製造のさまざまな技術の中で、大量生産が容易で、ナノスケール表面に他の機能性材料を組み込む可能性があるという利点を備えたエレクトロスピニングは、選択的湿潤性、合理的な細孔構造、および高い比表面積を備えた新規ナノファイバー膜の調製に広く関心を集めています。 。 [2] nan [3]
large specific surface 大きな比表面積
The chlorinated P(AN-VAPH) nanofibrous membranes showed intriguing features of unique 3D morphological structures with large specific surface area, good mechanical performance, rechargeable chlorination capacity (>5000 ppm), long-term durability, and desirable biocidal activity against both bacteria and viruses (>99. [1] Electrospun nanofibrous membranes (ENFMs) have many superior advantages, such as large specific surface area, high porosity, easy modification, good flexibility, and easy separation for recycling, which are consider as excellent adsorbents. [2] Used of electrostatic fiber character such as high porosity, large specific surface area, the nanofibrous membranes were manufactured by electrospinning technique with polyvinyl alcohol acting as substrates and bromocresol purple acting as indicator. [3]塩素化P(AN-VAPH)ナノファイバー膜は、比表面積が大きく、優れた機械的性能、再充電可能な塩素処理能力(> 5000 ppm)、長期耐久性、および細菌とウイルス(>99。 [1] エレクトロスピニングされたナノファイバー膜(ENFM)には、比表面積が大きく、多孔性が高く、改質が容易で、柔軟性が高く、リサイクルのための分離が容易であるなど、多くの優れた利点があり、優れた吸着剤と見なされています。 [2] nan [3]
specific surface area 比表面積
Porous nanofibrous membranes have ultrahigh specific surface areas and could be broadly employed in protein purification, enzyme immobilization, and biosensors with enhanced selectivity, sensitivity, and efficiency. [1] After the surface coating of the PANI shell, the optimized PANI@CNT-CNC/PVA-PAA nanofibrous membranes exhibit a large porosity, an enhanced specific surface area, a superior tensile strength of ~54. [2]多孔質ナノファイバー膜は比表面積が非常に高く、タンパク質精製、酵素固定化、および選択性、感度、効率が向上したバイオセンサーに幅広く使用できます。 [1] nan [2]
Electrospun Nanofibrous Membranes 電界紡糸ナノファイバー膜
To the best of our knowledge, this is the first successful demonstration of the synergistic combination of intrinsically microporous polyimides and MOFs in the form of electrospun nanofibrous membranes and their application for VOC removal. [1] In this study, we have developed poly(lactic acid) (PLA) electrospun nanofibrous membranes (EFMs) surface coated by cellulose nanofibrils (CNF) and/or silk peptide (SP). [2] In this study, a new strategy is proposed for effective and rapid detection of fingerprints based on electrospun nanofibrous membranes and quantum dots (QDs). [3] nanoparticles, polymeric nanomaterials, 2D nanosheets, or electrospun nanofibrous membranes, nanocomposites for desalination or water-treatment applications, is an emerging concept that has rapidly grown in interest as a method for improving the water quality. [4] Three-dimensional (3D) composite polyvinylidene fluoride (PVDF)/polyacrylonitrile (PAN) electrospun nanofibrous membranes combining both thick and thin nanofibers have been fabricated by the method of multi-jet electrospinning with sheath gas to realize high-efficiency air filtration under a low pressure drop. [5] The investigation of the light scattering properties for electrospun nanofibrous membranes is paramount for color yield-regulating of colorful nanofiber mats. [6] Electrospun nanofibrous membranes (ENFMs) have many superior advantages, such as large specific surface area, high porosity, easy modification, good flexibility, and easy separation for recycling, which are consider as excellent adsorbents. [7] Among various membranes, electrospun nanofibrous membranes offer unique properties, such as high and tunable porosity, high surface area, tunability in the composition and structure, functionalization ability and good mechanical behaviour, to be used in water purification compared to conventional membranes. [8] Electrospun nanofibrous membranes (ENM) possess many advantages over commonly utilized water purification systems. [9] In line with the primary aim of high throughput production of PU electrospun nanofibrous membranes (ENMs) with different fiber sizes and proper morphologies, the needle-free electrospinning technique was employed. [10] Different Multilayer electrospun nanofibrous membranes were synthesized to study the effects of potentially important steps and parameters including hot-pressing and chitosan / poly (vinyl alcohol) (CTS/PVA) solutions on the membranes performance in Cu(II) ions removal. [11] This paper reviews the recent updates on sustainability of electrospun nanofibrous membranes, prerequisite of nanofibrous membranes, manufacturing techniques, merits and limitations of nanofibrous membrane and solutions to overcome the issue faced by electrospun nanofibrous membrane. [12] Ceramic electrospun nanofibrous membranes (ENMs) are ideal candidates for ultrafiltration applications in harsh environments. [13] This review presents a brief overview of electrospinning techniques, different structures of electrospun nanofibrous membranes, unique characteristics and functions of the fabricated membranes, and summarization of the outdoor and indoor applications in PM filtration. [14] Among several types of carbohydrate polymers blend PVA hydrogel membranes used for biomedical applications in particular wound dressings; electrospun nanofibrous membranes have gained increased interest because of their extraordinary features e. [15] Robust hydrophobic and superhydrophobic mixed matrix electrospun nanofibrous membranes (MM-ENMs) have been prepared from low- and high- molecular weight polyvinylidene fluoride with either multi-walled carbon nanotubes or graphene oxide nanofillers (0. [16] These compositions were incorporated into electrospun nanofibrous membranes of polycaprolactone (PCL). [17] This study aimed to fabricate core-shell electrospun nanofibrous membranes displaying simultaneous cell proliferation and antibacterial activity. [18] In this work, fish oil-gelatin core-shell electrospun nanofibrous membranes (ENMs) were explored as edible films for the encapsulation of hydrophobic fish oil and hydrophilic vitamin C (VC). [19] To address the challenge of the airborne transmission of SARS-CoV-2, photosensitized electrospun nanofibrous membranes were fabricated to effectively capture and inactivate coronavirus aerosols. [20] Electrospun nanofibrous membranes (NFMs) have attracted considerable attention as a potential physical barrier for reducing postoperative adhesion. [21] This paper reports the synthesis and characterization of novel ultrafiltration (UF) electrospun nanofibrous membranes (ENMs) incorporated with iron oxide (Fe3O4) nanoparticles (NPs) for effective oily solution treatment. [22] Electrospun nanofibrous membranes (ENMs) are cutting edge membrane technology that offer substantial high flux and high rejection rates compared to conventional membranes. [23] Here, we present a strategy to create a Pb2+ removal and contamination degree detecting system by combining electrospun nanofibrous membranes (NMs) with a flow-through system. [24] Research related to electrospun nanofibrous membranes and their archetypical variants, templated nanoengineered scaffolds, and self-assembling systems are discussed. [25] The efficiency of the proposed model is assessed using experimental data of PVDF electrospun nanofibrous membranes. [26] Electrospun nanofibrous membranes enjoy numerous factors which benefit them to be used as potential candidates in biosensing platforms. [27] In this work, green electrospun nanofibrous membranes based on chitosan (Cs)/polyvinyl alcohol (PVA) composite with a very high carbon monoxide adsorption capacity (much higher than the values one may expect from activated carbon and zeolite adsorbents, and also higher than that of the metal-organic framework) are developed. [28] Among them, electrospun nanofibrous membranes due to their intrinsic properties like high surface area‐to‐volume ratio, porosity and structural similarity with the skin extracellular matrix have been regarded as highly promising for wound dressings applications. [29]私たちの知る限りでは、これは、エレクトロスピニングされたナノファイバー膜の形での本質的にミクロポーラスなポリイミドとMOFの相乗的な組み合わせと、VOC除去へのそれらの応用の最初の成功したデモンストレーションです。 [1] この研究では、セルロースナノフィブリル(CNF)および/またはシルクペプチド(SP)で表面コーティングされたポリ(乳酸)(PLA)エレクトロスピニングナノファイバー膜(EFM)を開発しました。 [2] nan [3] nan [4] nan [5] nan [6] エレクトロスピニングされたナノファイバー膜(ENFM)には、比表面積が大きく、多孔性が高く、改質が容易で、柔軟性が高く、リサイクルのための分離が容易であるなど、多くの優れた利点があり、優れた吸着剤と見なされています。 [7] nan [8] nan [9] nan [10] nan [11] nan [12] nan [13] nan [14] nan [15] nan [16] nan [17] nan [18] nan [19] nan [20] nan [21] nan [22] nan [23] nan [24] nan [25] nan [26] nan [27] nan [28] nan [29]
Composite Nanofibrous Membranes 複合ナノファイバー膜
The composite nanofibrous membranes were employed as a low-cost adsorbent for efficient removal of organic dye (employed as a model) from water in batch and fixed bed adsorption. [1] In this work, the polyacrylonitrile monolayer/composite nanofibrous membranes were successfully fabricated at different processing parameters. [2] Using the electrospinning technique, composite nanofibrous membranes were developed on a dense PVA layer from a solution of poly(vinyl alcohol) (PVA)/chitosan (CS)/zeolite-A. [3] To maximize the merits of each component, PMIA/PSA composite nanofibrous membranes with different mass blending ratios are prepared to determine the optimal balance. [4] In this study, polyacrylonitrile/polyurethane (PAN/PU) composite nanofibrous membranes with an antibacterial agent AgTiO2 were prepared by an electrospinning method. [5] Phenolphthalein polyethersulfone (PES-C)/silica (SiO2) composite nanofibrous membranes were prepared via solution blowing. [6]複合ナノファイバー膜は、バッチおよび固定床吸着で水から有機染料(モデルとして採用)を効率的に除去するための低コストの吸着剤として使用されました。 [1] この作業では、ポリアクリロニトリル単層/複合ナノファイバー膜がさまざまな処理パラメーターで正常に製造されました。 [2] nan [3] nan [4] nan [5] nan [6]
Chitosan Nanofibrous Membranes キトサンナノファイバー膜
Chitosan nanofibrous membranes are quite popular in the field of tissue regeneration because of their structural and chemical similarity to the natural ECM. [1] The chitosan nanofibrous membranes were fabricated on an aluminum foil-covered collector of the electrospinning system. [2] The as-crosslinked electrospun chitosan nanofibrous membranes possess enhanced wet stability, improved mechanical property and good biocompatibility, which are necessary for wound healing application. [3] Chitosan nanofibrous membranes are prepared via an electrospinning technique and explored as potential wound healing patches. [4]キトサンナノファイバー膜は、天然のECMと構造的および化学的類似性があるため、組織再生の分野で非常に人気があります。 [1] キトサンナノファイバー膜は、エレクトロスピニングシステムのアルミホイルで覆われたコレクター上に製造されました。 [2] nan [3] nan [4]
Resultant Nanofibrous Membranes
The resultant nanofibrous membranes showed a proportional increase in antibacterial efficacy with the rise in AgNPs loading against both Gram-positive S. [1] Our approach can endow the resultant nanofibrous membranes with powerful biocidal activity (6 log CFU reduction against E. [2]得られたナノファイバー膜は、両方のグラム陽性菌に対するAgNPの負荷の増加に伴い、抗菌効果の比例した増加を示しました。 [1] nan [2]
Pva Nanofibrous Membranes
We report a simple routine where the zirconium-based UiO-66-NH2 metal-organic frameworks (MOFs) are nucleated as a layer on the surface of PVA nanofibrous membranes (UiO-66-NH2@PVA NFMs). [1] In the present work, PVA nanofibrous membranes were fabricated using roller electrospinning techniques. [2]ジルコニウムベースのUiO-66-NH2金属有機フレームワーク(MOF)がPVAナノファイバー膜(UiO-66-NH2 @ PVA NFM)の表面の層として核形成される単純なルーチンを報告します。 [1] nan [2]
Loaded Nanofibrous Membranes
The paclitaxel-loaded nanofibrous membranes provided sustained drug release and site-specific treatment by directly targeting and changing the tumor microenvironment, resulting in low systemic toxicity and a significant improvement in the therapeutic effect and safety compared with conventional chemotherapy. [1] In this work, emulsion electrospinning was used for the preparation of tramadol-loaded nanofibrous membranes based on poly(ε-caprolactone). [2]パクリタキセルをロードしたナノファイバー膜は、腫瘍の微小環境を直接標的にして変化させることにより、持続的な薬物放出と部位特異的治療を提供し、従来の化学療法と比較して、全身毒性が低く、治療効果と安全性が大幅に向上しました。 [1] nan [2]
Pvdf Nanofibrous Membranes
Here we report a one-step approach to simultaneously manipulate both the surface roughness and surface chemistry of PVDF nanofibrous membranes for enhanced direct-contact membrane distillation (DCMD) performances. [1] By tailoring the parameters for electrospinning, PAA-g-PVDF nanofibrous membranes with interpenetrated nanofibers and microsphere structure were formed, and the membrane surface was endowed with high roughness on the micrometer scale. [2]Fabricated Nanofibrous Membranes ナノファイバー膜の作製
These fabricated nanofibrous membranes’ attached inserts have advantages such as low cost, ready availability, easy fabrication, tunable porosity, autoclavability, and biomaterial-based nanofibrous membranes. [1] Additionally, the contact angles of the fabricated nanofibrous membranes showed marked decrease from 86. [2]これらの製造されたナノファイバー膜の取り付けられたインサートには、低コスト、すぐに利用できる、簡単な製造、調整可能な多孔性、オートクラバビリティ、および生体材料ベースのナノファイバー膜などの利点があります。 [1] さらに、製造されたナノファイバー膜の接触角は、86から著しく減少した。 [2]
Pan Nanofibrous Membranes パンナノファイバーメンブレン
These excellent properties endow the ZnO/PANI/PAN nanofibrous membranes with great potential in treating oily wastewater. [1] This finding was consistent with predictions derived from a Weibull analysis for the mechanical reliability of PAN nanofibrous membranes. [2]これらの優れた特性は、ZnO / PANI/PANナノファイバー膜に油性廃水の処理に大きな可能性をもたらします。 [1] この発見は、PANナノファイバー膜の機械的信頼性に関するワイブル分析から導き出された予測と一致していました。 [2]
Porou Nanofibrous Membranes Porou ナノファイバー膜
673 in a cyclohexane–water–solid system) onto porous nanofibrous membranes, which were able to achieve continuous separation of oil–water mixtures. [1] Porous nanofibrous membranes have ultrahigh specific surface areas and could be broadly employed in protein purification, enzyme immobilization, and biosensors with enhanced selectivity, sensitivity, and efficiency. [2]シクロヘキサン-水-固体システムで673)を多孔質ナノファイバー膜に付着させ、油-水混合物の連続分離を実現しました。 [1] 多孔質ナノファイバー膜は比表面積が非常に高く、タンパク質精製、酵素固定化、および選択性、感度、効率が向上したバイオセンサーに幅広く使用できます。 [2]
Novel Nanofibrous Membranes 新規ナノファイバー膜
Therefore, it is crucial to develop novel nanofibrous membranes with enhanced mechanical strength and thermal stability. [1] Among various techniques for the membrane fabrication, electrospinning with advantages of ease in mass production and potential incorporation of other functional materials on the nanoscale surface has gained widespread interest for the preparation of novel nanofibrous membranes with selective wettability, rational pore structure and high specific surface area. [2]したがって、機械的強度と熱安定性が強化された新しいナノファイバー膜を開発することが重要です。 [1] 膜製造のさまざまな技術の中で、大量生産が容易で、ナノスケール表面に他の機能性材料を組み込む可能性があるという利点を備えたエレクトロスピニングは、選択的湿潤性、合理的な細孔構造、および高い比表面積を備えた新規ナノファイバー膜の調製に広く関心を集めています。 。 [2]
Polymeric Nanofibrous Membranes 高分子ナノファイバー膜
Electrospinning is an economy and highly reproducible procedure for the fabrication of polymeric nanofibrous membranes. [1] Polymeric nanofibrous membranes (NFMs) with both high whiteness and high thermal and ultraviolet (UV) stability are highly desired as reflectors for ultraviolet light-emitting diodes (UV-LEDs) devices. [2]エレクトロスピニングは、高分子ナノファイバー膜を製造するための経済的で再現性の高い手順です。 [1] 紫外線発光ダイオード(UV-LED)デバイスの反射体として、高い白色度と高い熱および紫外線(UV)安定性の両方を備えた高分子ナノファイバー膜(NFM)が強く望まれています。 [2]
nanofibrous membranes containing
The highest and fastest dye removal occurs for the nanofibrous membranes containing 2 wt % nanofiller, where about 80% of the cationic dye is removed after 15 min. [1] In this study, polyvinyl alcohol (PVA) nanofibrous membranes containing silver nanoparticles (Ag NPs) were successfully fabricated by the combination of electrospinning and a green reduction approach. [2] In this study, mineralized electrospun polylactic acid (PLLA) nanofibrous membranes containing different amounts of strontium (Sr) were fabricated by an electrodeposition method for potential use in bone regeneration applications. [3]最高かつ最速の染料除去は、2 wt%のナノフィラーを含むナノファイバー膜で発生し、15分後にカチオン染料の約80%が除去されます。 [1] nan [2] nan [3]
nanofibrous membranes showed 示されているナノファイバー膜
The chlorinated P(AN-VAPH) nanofibrous membranes showed intriguing features of unique 3D morphological structures with large specific surface area, good mechanical performance, rechargeable chlorination capacity (>5000 ppm), long-term durability, and desirable biocidal activity against both bacteria and viruses (>99. [1] Additionally, the contact angles of the fabricated nanofibrous membranes showed marked decrease from 86. [2] The resultant nanofibrous membranes showed a proportional increase in antibacterial efficacy with the rise in AgNPs loading against both Gram-positive S. [3]塩素化P(AN-VAPH)ナノファイバー膜は、比表面積が大きく、優れた機械的性能、再充電可能な塩素処理能力(> 5000 ppm)、長期耐久性、および細菌とウイルス(>99。 [1] さらに、製造されたナノファイバー膜の接触角は、86から著しく減少した。 [2] 得られたナノファイバー膜は、両方のグラム陽性菌に対するAgNPの負荷の増加に伴い、抗菌効果の比例した増加を示しました。 [3]
nanofibrous membranes vium
Herein, a poly(methacrylatoethyl trimethyl ammonium chloride-co-methyl methacrylate) copolymer was synthesized, and then blended with polyethersulfone for the fabrication of nanofibrous membranes via electrospinning for the use of fast and massive removal of dyes and bacteria. [1] We prepared polyacrylonitrile (PAN) nanofibrous membranes via electrospinning and investigated the effects of the oven-drying and thermal-pressing conditions on their porosity and tensile strength. [2]ここでは、ポリ(メタクリラトエチルトリメチルアンモニウムクロリド-co-メチルメタクリレート)コポリマーを合成し、次にエレクトロスピニングを介してナノファイバー膜を製造するためにポリエーテルスルホンとブレンドして、染料および細菌の迅速かつ大量の除去を使用した。 [1] nan [2]
nanofibrous membranes exhibit
As a result, the nanofibrous membranes exhibits enhanced electrolyte uptake performance (~870%, with an electrolyte contact angel of 0°) and robust thermal dimensional stability (stable at 160°C for 1. [1] After the surface coating of the PANI shell, the optimized PANI@CNT-CNC/PVA-PAA nanofibrous membranes exhibit a large porosity, an enhanced specific surface area, a superior tensile strength of ~54. [2]その結果、ナノファイバー膜は、強化された電解質取り込み性能(〜870%、電解質接触角0°)と堅牢な熱寸法安定性(160°Cで1分間安定)を示します。 [1] nan [2]
nanofibrous membranes modified
In this work, the silk fibroin/cellulose blend nanofibrous membranes modified with sodium-3-sulfobenzoate (S-SCBNM) were fabricated by electrospinning technique for lysozyme adsorption. [1] In this work, we fabricate the silk-derived nanofibrous membranes modified with 3,3′,4,4′-benzophenone tetracarboxylic dianhydride (BDSNM) that could yield reactive oxygen species (ROS) driven under UV light irradiation. [2]この作業では、リゾチーム吸着のためのエレクトロスピニング技術によって、ナトリウム-3-スルホ安息香酸(S-SCBNM)で修飾されたシルクフィブロイン/セルロースブレンドナノファイバー膜を製造しました。 [1] nan [2]
nanofibrous membranes provided 提供されるナノファイバー膜
The paclitaxel-loaded nanofibrous membranes provided sustained drug release and site-specific treatment by directly targeting and changing the tumor microenvironment, resulting in low systemic toxicity and a significant improvement in the therapeutic effect and safety compared with conventional chemotherapy. [1] Hybrid PCL meshes/PLGA nanofibrous membranes provided a sustainable release of metronidazole, lidocaine, and estradiol for 4, 25, and 30 days, respectively, in vitro. [2]パクリタキセルをロードしたナノファイバー膜は、腫瘍の微小環境を直接標的にして変化させることにより、持続的な薬物放出と部位特異的治療を提供し、従来の化学療法と比較して、全身毒性が低く、治療効果と安全性が大幅に向上しました。 [1] ハイブリッドPCLメッシュ/PLGAナノファイバー膜は、メトロニダゾール、リドカイン、およびエストラジオールをそれぞれin vitroで4、25、および30日間持続的に放出しました。 [2]