Nanofiber

Example of a cellulose nanofiber network.

Nanofibers are fibers with diameters in the nanometer range (typically, between 1 nm and 1 μm). Nanofibers can be generated from different polymers and hence have different physical properties and application potentials. Examples of natural polymers include collagen, cellulose, silk fibroin, keratin, gelatin and polysaccharides such as chitosan and alginate.[1][2] Examples of synthetic polymers include poly(lactic acid) (PLA), polycaprolactone (PCL),[3] polyurethane (PU), poly(lactic-co-glycolic acid) (PLGA), poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV), and poly(ethylene-co-vinylacetate) (PEVA).[1][2] Polymer chains are connected via covalent bonds.[4] The diameters of nanofibers depend on the type of polymer used and the method of production.[5] All polymer nanofibers are unique for their large surface area-to-volume ratio, high porosity, appreciable mechanical strength, and flexibility in functionalization compared to their microfiber counterparts.[1][2][6]

There exist many different methods to make nanofibers, including drawing, electrospinning, self-assembly, template synthesis, and thermal-induced phase separation. Electrospinning is the most commonly used method to generate nanofibers because of the straightforward setup, the ability to mass-produce continuous nanofibers from various polymers, and the capability to generate ultrathin fibers with controllable diameters, compositions, and orientations.[6] This flexibility allows for controlling the shape and arrangement of the fibers so that different structures (i.e. hollow, flat and ribbon shaped) can be fabricated depending on intended application purposes.

Nanofibers have many possible technological and commercial applications. They are used in tissue engineering,[1][2][7] drug delivery,[8][9][10] seed coating material,[11][12][13] cancer diagnosis,[14][15][16] lithium-air battery,[17][18][19] optical sensors,[20][21][22] air filtration,[23][24][25] redox-flow batteries [26] and composite materials.[27]

History of nanofiber production

Nanofibers were first produced via electrospinning more than four centuries ago.[28][29] Beginning with the development of the electrospinning method, English physicist William Gilbert (1544-1603) first documented the electrostatic attraction between liquids by preparing an experiment in which he observed a spherical water drop on a dry surface warp into a cone shape when it was held below an electrically charged amber.[30] This deformation later came to be known as the Taylor cone.[31] In 1882, English physicist Lord Rayleigh (1842-1919) analyzed the unstable states of liquid droplets that were electrically charged, and noted that the liquid was ejected in tiny jets when equilibrium was established between the surface tension and electrostatic force.[32] In 1887, British physicist Charles Vernon Boys (1855-1944) published a manuscript about nanofiber development and production.[33] In 1900, American inventor John Francis Cooley (1861-1903) filed the first modern electrospinning patent.[34]

Anton Formhals was the first person to attempt nanofiber production between 1934 and 1944 and publish the first patent describing the experimental production of nanofibers.[29] In 1966, Harold Simons published a patent for a device that could produce thin and light nanofiber fabrics with diverse motifs.[35]

Only at the end of the 20th century have the words electrospinning and nanofiber become common language among scientists and researchers.[28][29] Electrospinning continues to be developed today.

Synthesis methods

Many chemical and mechanical techniques for preparing nanofibers exist.

Electrospinning

Diagram of a general set-up of electrospinning.
Taylor cone from which jet of polymer solution is ejected.

Electrospinning is the most commonly used method to fabricate nanofibers.[36][6] [37][38][39][40] The instruments necessary for electrospinning include a high voltage supplier, a capillary tube with a pipette or needle with a small diameter, and a metal collecting screen. One electrode is placed into the polymer solution and the other electrode is attached to the collector. An electric field is applied to the end of the capillary tube that contains the polymer solution held by its surface tension and forms a charge on the surface of the liquid. As the intensity of the electric field increases, the hemispherical surface of the fluid at the tip of the capillary tube elongates to form a conical shape known as the Taylor cone. A critical value is attained upon further increase in the electric field in which the repulsive electrostatic force overcomes the surface tension and the charged jet of fluid is ejected from the tip of the Taylor cone. The discharged polymer solution jet is unstable and elongates as a result, allowing the jet to become very long and thin. Charged polymer fibers solidifies with solvent evaporation.[6][41] Randomly-oriented nanofibers are collected on the collector. Nanofibers can also be collected in a highly aligned fashion by using specialized collectors such as the rotating drum,[42] metal frame,[43] or a two-parallel plates system.[44] Parameters such as jet stream movement and polymer concentration have to be controlled to produce nanofibers with uniform diameters and morphologies.[45]

The electrospinning technique transforms many types of polymers into nanofibers. An electrospun nanofiber network resembles the extracellular matrix (ECM) well.[6][46][47] This resemblance is a major advantage of electrospinning because it opens up the possibility of mimicking the ECM with regards to fiber diameters, high porosity, and mechanical properties. Electrospinning is being further developed for mass production of one-by-one continuous nanofibers.[46]

Thermal-induced phase separation

Thermal-induced phase separation separates a homogenous polymer solution into a multi-phase system via thermodynamic changes.[1][7][48] The procedure involves five steps: polymer dissolution, liquid-liquid or liquid-solid phase separation, polymer gelation, extraction of solvent from the gel with water, and freezing and freeze-drying under vacuum.[1][7] Thermal-induced phase separation method is widely used to generate scaffolds for tissue regeneration.[48]

The homogenous polymer solution in the first step is thermodynamically unstable and tends to separate into polymer-rich and polymer-lean phases under appropriate temperature. Eventually after solvent removal, the polymer-rich phase solidifies to form the matrix and the polymer-lean phase develops into pores.[citation needed] Next, two types of phase separation can be carried out on the polymer solution depending on the desired pattern. Liquid-liquid separation is usually used to form bicontinuous phase structures while solid-liquid phase separation is used to form crystal structures. The gelation step plays a crucial role in controlling the porous morphology of the nanofibrous matrices. Gelation is influenced by temperature, polymer concentration, and solvent properties.[48] Temperature regulates the structure of the fiber network: low gelation temperature results in formation of nanoscale fiber networks while high gelation temperature leads to the formation of a platelet-like structure.[1] Polymer concentration affects fiber properties: an increase in polymer concentration decreases porosity and increases mechanical properties such as tensile strength. Solvent properties influence morphology of the scaffolds. After gelation, gel is placed in distilled water for solvent exchange. Afterwards, the gel is removed from the water and goes through freezing and freeze-drying. It is then stored in a desiccator until characterization.

Drawing

The drawing method makes long single strands of nanofibers one at a time. The pulling process is accompanied by solidification that converts the dissolved spinning material into a solid fiber.[46][49] A cooling step is necessary in the case of melt spinning and evaporation of solvent in the case of dry spinning. A limitation, however, is that only a viscoelastic material that can undergo extensive deformations while possessing sufficient cohesion to survive the stresses developed during pulling can be made into nanofibers through this process.[46][50]

Template synthesis

The template synthesis method uses a nanoporous membrane template composed of cylindrical pores of uniform diameter to make fibrils (solid nanofiber) and tubules (hollow nanofiber).[51][52] This method can be used to prepare fibrils and tubules of many types of materials, including metals, semiconductors and electronically conductive polymers.[51][52] The uniform pores allow for control of the dimensions of the fibers so nanofibers with very small diameters can be produced through this method. However, a drawback of this method is that it cannot make continuous nanofibers one at a time.

Self-assembly

The self-assembly technique is used to generate peptide nanofibers and peptide amphiphiles. The method was inspired by the natural folding process of amino acid residues to form proteins with unique three-dimensional structures.[53] The self-assembly process of peptide nanofibers involves various driving forces such as hydrophobic interactions, electrostatic forces, hydrogen bonding and van der Waals forces and is influenced by external conditions such as ionic strength and pH.[54]

Polymer materials

Collagen fibers in a cross-sectional area of dense connective tissue.

Due to their high porosity and large surface area-to-volume ratio, nanofibers are widely used to construct scaffolds for biological applications.[1][2] Major examples of natural polymers used in scaffold production are collagen, cellulose, silk fibroin, keratin, gelatin and polysaccharides such as chitosan and alginate. Collagen is a natural extracellular component of many connective tissues. Its fibrillary structure, which varies in diameter from 50-500 nm, is important for cell recognition, attachment, proliferation and differentiation.[2] Using type I collagen nanofibers produced via electrospinning, Shih et al. found that the engineered collagen scaffold showed an increase in cell adhesion and decrease in cell migration with increasing fiber diameter.[55] Using silk scaffolds as a guide for growth for bone tissue regeneration, Kim et al. observed complete bone union after 8 weeks and complete healing of defects after 12 weeks whereas the control in which the bone did not have the scaffold displayed limited mending of defects in the same time period.[56] Similarly, keratin, gelatin, chitosan and alginate demonstrate excellent biocompatibility and bioactivity in scaffolds.[2]

However, cellular recognition of natural polymers can easily initiate an immune response.[2][47] Consequently, synthetic polymers such as poly(lactic acid) (PLA), polycaprolactone (PCL), polyurethane (PU), poly(lactic-co-glycolic acid) (PLGA), poly(L-lactide) (PLLA), and poly(ethylene-co-vinylacetate) (PEVA) have been developed as alternatives for integration into scaffolds. Being biodegradable and biocompatible, these synthetic polymers can be used to form matrices with a fiber diameter within the nanometer range. Out of these synthetic polymers, PCL has generated considerable enthusiasm among researchers.[57] PCL is a type of biodegradable polyester that can be prepared via ring-opening polymerization of ε-caprolactone using catalysts. It shows low toxicity, low cost and slow degradation. PCL can be combined with other materials such as gelatin, collagen, chitosan, and calcium phosphate to improve the differentiation and proliferation capacity (2, 17).[2][57] PLLA is another popular synthetic polymer. PLLA is well known for its superior mechanical properties, biodegradability and biocompatibility. It shows efficient cell migration ability due to its high spatial interconnectivity, high porosity and controlled alignment.[58] A blend of PLLA and PLGA scaffold matrix has shown proper biomimetic structure, good mechanical strength and favorable bioactivity.

Applications

Tissue engineering

Bone matrix composed of collagen fibrils. Nanofiber scaffolds are able to mimic such structure.

In tissue engineering, a highly porous artificial extracellular matrix is needed to support and guide cell growth and tissue regeneration.[1][2][59][60] Natural and synthetic biodegradable polymers have been used to create such scaffolds.[1][2]

Simon, in a 1988 NIH SBIR grant report, showed that electrospinning could be used to produce nano- and submicron-scale polystyrene and polycarbonate fibrous mats specifically intended for use as in vitro cell substrates. This early use of electrospun fibrous lattices for cell culture and tissue engineering showed that Human Foreskin Fibroblasts (HFF), transformed Human Carcinoma (HEp-2), and Mink Lung Epithelium (MLE) would adhere to and proliferate upon the fibers.[61][62]

Nanofiber scaffolds are used in bone tissue engineering to mimic the natural extracellular matrix of the bones.[7] The bone tissue is arranged either in a compact or trabecular pattern and composed of organized structures that vary in length from the centimeter range all the way to the nanometer scale. Nonmineralized organic component (i.e. type 1 collagen), mineralized inorganic component (i.e. hydroxyapatite), and many other noncollagenous matrix proteins (i.e. glycoproteins and proteoglycans) make up the nanocomposite structure of the bone ECM.[59] The organic collagen fibers and the inorganic mineral salts provide flexibility and toughness, respectively, to ECM.

Although the bone is a dynamic tissue that can self-heal upon minor injuries, it cannot regenerate after experiencing large defects such as bone tumor resections and severe nonunion fractures because it lacks the appropriate template.[1][7] Currently, the standard treatment is autografting which involves obtaining the donor bone from a non-significant and easily accessible site (i.e. iliac crest) in the patient own body and transplanting it into the defective site. Transplantation of autologous bone has the best clinical outcome because it integrates reliably with the host bone and can avoid complications with the immune system.[63] But its use is limited by its short supply and donor site morbidity associated with the harvest procedure.[59] Furthermore, autografted bones are avascular and hence are dependent on diffusion for nutrients, which affects their viability in the host.[63] The grafts can also be resorbed before osteogenesis is complete due to high remodeling rates in the body.[59][63] Another strategy for treating severe bone damage is allografting which transplants bones harvested from a human cadaver. However, allografts introduce the risk of disease and infection in the host.[63]

Bone tissue engineering presents a versatile response to treat bone injuries and deformations. Nanofibers produced via electrospinning mimics the architecture and characteristics of natural extracellular matrix particularly well. These scaffolds can be used to deliver bioactive agents that promote tissue regeneration.[2] These bioactive materials should ideally be osteoinductive, osteoconductive, and osseointegratable.[59] Bone substitute materials intended to replace autologous or allogeneic bone consist of bioactive ceramics, bioactive glasses, and biological and synthetic polymers. The basis of bone tissue engineering is that the materials will be resorbed and replaced over time by the body’s own newly regenerated biological tissue.[60]

Tissue engineering is not only limited to the bone: a large amount of research is devoted to cartilage,[64] ligament,[65] skeletal muscle,[66] skin,[67] blood vessel,[68] and neural tissue engineering[69] as well.

Drug delivery

Drugs and biopolymers can be loaded onto nanofibers via simple adsorption, nanoparticles adsorption, and multilayer assembly.

Successful delivery of therapeutics to the intended target largely depends on the choice of the drug carrier. The criteria for an ideal drug carrier include maximum effect upon delivery of the drug to the target organ, evasion of the immune system of the body in the process of reaching the organ, retention of the therapeutic molecules from preparatory stages to the final delivery of the drug, and proper release of the drug for exertion of the intended therapeutic effect.[8] Nanofibers are under study as a possible drug carrier candidate.[9][10][70] Natural polymers such as gelatin and alginate make for good fabrication biomaterials for carrier nanofibers because of their biocompatibility and biodegradability that result in no harm to the tissue of the host and no toxic accumulation in the human body, respectively. Due to their cylindrical morphology, nanofibers possess a high surface area-to-volume ratio. As a result, the fibers possess high drug-loading capacity and may release therapeutic molecules over a large surface area.[8][47] Whereas surface area to volume ratio can only be controlled by adjusting the radius for spherical vesicles, nanofibers have more degrees of freedom in controlling the ratio by varying both the length and the cross-sectional radius. This adjustability is important for their application in drug delivery system in which the functional parameters need to be precisely controlled.[8]

Preliminary studies indicate that antibiotics and anticancer drugs may be encapsulated in electrospun nanofibers by adding the drug into the polymer solution prior to electrospinning.[71][72] Surface-loaded nanofiber scaffolds are useful as adhesion barriers between internal organs and tissues post-surgery.[73][74] Adhesion occurs during the healing process and can bring on complications such as chronic pain and reoperation failure.[73][74][75]

Cancer diagnosis

Although pathologic examination is the current standard method for molecular characterization in testing for the presence of biomarkers in tumors, these single-sample analyses fail to account for the diverse genomic nature of tumors.[14] Considering the invasive nature, psychological stress, and the financial burden resulting from repeated tumor biopsies in patients, biomarkers that could be judged through minimally invasive procedures, such as blood draws, constitute an opportunity for progression in precision medicine.

Liquid biopsy is an option that is becoming increasingly popular as an alternative to solid tumor biopsy.[14][15] This is simply a blood draw that contains circulating tumor cells (CTCs) which are shed into the bloodstream from solid tumors. Patients with metastatic cancer are more likely to have detectable CTCs in the bloodstream but CTCs also exist in patients with localized diseases. It has been found that the number of CTCs present in the bloodstream of patients with metastatic prostate and colorectal cancer is prognostic of the overall survival of tumors.[16][76] CTCs also have been demonstrated to inform prognosis in earlier stages of the disease.[77]

CTC capture and release mechanism of third generation Thermoresponsive Chip.

Recently, Ke et al. developed a NanoVelcro chip that captures the CTCs from the blood samples.[15] When blood is passed through the chip, the nanofibers coated with protein antibodies bind to the proteins expressed on the surface of cancer cells and act like Velcro to trap CTCs for analysis. The NanoVelcro CTC assays underwent three generations of development. The first generation NanoVelcro Chip was created for CTC enumeration for cancer prognosis, staging, and dynamic monitoring.[78] The second generation NanoVelcro-LCM was developed for single-cell CTC isolation.[79][80] The individually isolated CTCs can be subjected to single-CTC genotyping. The third generation Thermoresponsive Chip allowed for CTC purification.[15][81] The nanofiber polymer brushes undergo temperature-dependent conformational changes to capture and release CTCs.

Lithium-air battery

Among many advanced electrochemical energy storage devices, rechargeable lithium-air batteries are of particular interest due to their considerable energy storing capacities and high power densities.[17][18] As the battery is being used, lithium ions combine with oxygen from the air to form particles of lithium oxides, which attach to carbon fibers on the electrode. During recharging, the lithium oxides separate again into lithium and oxygen which is released back into the atmosphere. This conversion sequence is highly inefficient because there is significant voltage difference of more than 1.2 volts between the output voltage and the charging voltage of the battery meaning that approximately 30% of the electrical energy is lost as heat when the battery is charging.[17] Also the large volume changes resulting from continuous conversion of oxygen between its gaseous and solid state puts stress on the electrode and limits its lifetime.

Schematic of a lithium-air battery. For the nanofiber-based lithium-air battery, the cathode would be made up of carbon nanofibers.

The performance of these batteries depends on the characteristics of the material that makes up the cathode. Carbon materials have been widely used as cathodes because of their excellent electrical conductivities, large surface areas, and chemical stability.[19][82] Especially relevant for lithium-air batteries, carbon materials act as substrates for supporting metal oxides. Binder-free electrospun carbon nanofibers are particularly good potential candidates to be used in electrodes in lithium-oxygen batteries because they have no binders, have open macroporous structures, have carbons that support and catalyze the oxygen reduction reactions, and have versatility.[83]

Zhu et al. developed a novel cathode that can store lithium and oxygen in the electrode they named nanolithia which is a matrix of carbon nanofibers periodically embedded with cobalt oxide.[84] These cobalt oxides provide stability to the normally unstable superoxide-containing nanolithia. In this design, oxygen is stored as LiO2 and does not convert between gaseous and solid forms during charging and discharging. When the battery is discharging, lithium ions in nanolithia and react with superoxide oxygen the matrix to form Li2O2, and Li2O. The oxygen remains in its solid state as it transitions among these forms. The chemical reactions of these transitions provide electrical energy. During charging, the transitions occur in reverse.

Optical sensors

Polymer optical fibers have generated increasing interest in recent years.[20][21] Because of low cost, ease of handling, long wavelength transparency, great flexibility, and biocompatibility, polymer optical fibers show great potential for short-distance networking, optical sensing and power delivery.[22][85]

Electrospun nanofibers are particularly well-suitable for optical sensors because sensor sensitivity increases with increasing surface area per unit mass. Optical sensing works by detecting ions and molecules of interest via fluorescence quenching mechanism. Wang et al. successfully developed nanofibrous thin film optical sensors for metal ion (Fe3+ and Hg2+) and 2,4-dinitrotoluene (DNT) detection using the electrospinning technique.[20]

Quantum dots show useful optical and electrical properties, including high optical gain and photochemical stability. A variety of quantum dots have been successfully incorporated into polymer nanofibers.[86] Meng et al. showed that quantum dot-doped polymer nanofiber sensor for humidity detection shows fast response, high sensitivity, and long-term stability while requiring low power consumption.[87]

Kelly et al. developed a sensor that warns first responders when the carbon filters in their respirators have become saturated with toxic fume particles.[23] The respirators typically contain activated charcoal that traps airborne toxins. As the filters become saturated, chemicals begin to pass through and render the respirators useless. In order to easily determine when the filter is spent, Kelly and his team developed a mask equipped with a sensor composed of carbon nanofibers assembled into repeating structures called photonic crystals that reflect specific wavelengths of light. The sensors exhibit an iridescent color that changes when the fibers absorb toxins.

Air filtration

Paints and protective coatings on furniture contain volatile organic compounds such as toluene and formaldehyde.

Electrospun nanofibers are useful for removing volatile organic compounds (VOC) from the atmosphere. Scholten et al. showed that adsorption and desorption of VOC by electrospun nanofibrous membrane were faster than the rates of conventional activated carbon.[24]

Airborne contamination in the personnel cabins of mining equipment is of concern to the mining workers, mining companies, and government agencies such as the Mine Safety and Health Administration (MSHA). Recent work with mining equipment manufacturers and the MSHA has shown that nanofiber filter media can reduce cabin dust concentration to a greater extent compared to standard cellulose filter media.[25]

Nanofibers can be used in masks to protect people from viruses, bacteria, smog, dust, allergens and other particles. Filtration efficiency is at about 99.9% and the principle of filtration is mechanical. Particles in the air are bigger than pores in nanofiber web, but oxygen particles are small enough to pass through.

Oil-water separation

Nanofibers have the capabilities in oil–water separation, most particularly in sorption process when the material in use has the oleophilic and hydrophobic surfaces. These characteristic enable the nanofibers to be used as a tool to combat either oily waste- water from domestic household and industrial activities, or oily seawater due to the oil run down to the ocean from oil transportation activities and oil tank cleaning on a vessel.[37]

Sportswear textile

Sportswear textile with nanofiber membrane inside is based on the modern nanofiber technology where the core of the membrane consists of fibers with a diameter 1000× thinner than human hair. This extremely dense "sieve" with more than 2,5 billion of pores per square centimeter works much more efficiently with vapor removal and brings better level of water resistance. In the language of numbers, the nanofiber textile brings the following parameters:

·       RET 1.0 vapor permeability and 10,000 mm water column (version preferring breathability)

·       RET 4.8 vapor permeability and 30,000 mm water column (version preferring water resistance)

Nanofiber apparel and shoe membranes consist of polyurethane so its production is not harmful to nature. Membranes to sportswear made from nanofiber are recyclable.

See also

References

  1. ^ a b c d e f g h i j k Vasita R, Katti DS (2006). "Nanofibers and their applications in tissue engineering". International Journal of Nanomedicine. 1 (1): 15–30. doi:10.2147/nano.2006.1.1.15. PMC 2426767. PMID 17722259.
  2. ^ a b c d e f g h i j k l Khajavi R, Abbasipour M, Bahador A (2016). "Electrospun biodegradable nanofibers scaffolds for bone tissue engineering". J Appl Polym Sci. 133 (3): n/a. doi:10.1002/app.42883.
  3. ^ Sivan, Manikandan; Madheswaran, Divyabharathi; Valtera, Jan; Kostakova, Eva Kuzelova; Lukas, David (2022-01-01). "Alternating current electrospinning: The impacts of various high-voltage signal shapes and frequencies on the spinnability and productivity of polycaprolactone nanofibers". Materials & Design. 213: 110308. doi:10.1016/j.matdes.2021.110308. ISSN 0264-1275. S2CID 245075252.
  4. ^ Teraoka I (2002). Polymer Solutions: An Introduction to Physical Properties. John Wiley & Sons, Inc. ISBN 978-0-471-22451-8.
  5. ^ Reneker D, Chun I (1996). "Nanometre diameter fibres of polymer produced by electrospinning". Nanotechnology. 7 (3): 216–223. Bibcode:1996Nanot...7..216R. doi:10.1088/0957-4484/7/3/009. S2CID 4498522.
  6. ^ a b c d e Li D, Xia Y (2004). "Electrospinning of nanofibers: reinventing the wheel?". Adv Mater. 16 (14): 1151–1170. Bibcode:2004AdM....16.1151L. doi:10.1002/adma.200400719. S2CID 137659394.
  7. ^ a b c d e Ma PX, Zhang R (July 1999). "Synthetic nano-scale fibrous extracellular matrix". Journal of Biomedical Materials Research. 46 (1): 60–72. doi:10.1002/(sici)1097-4636(199907)46:1<60::aid-jbm7>3.0.co;2-h. hdl:2027.42/34415. PMID 10357136.
  8. ^ a b c d Sharifi F, Sooriyarachchi AC, Altural H, Montazami R, Rylander MN, Hashemi N (2016). "Fiber based approaches as medicine delivery systems". ACS Biomater Sci Eng. 2 (9): 1411–1431. doi:10.1021/acsbiomaterials.6b00281. PMID 33440580.
  9. ^ a b Ahn SY, Mun CH, Lee SH (2015). "Microfluidic spinning of fibrous alginate carrier having highly enhanced drug loading capability and delayed release profile". RSC Adv. 5 (20): 15172–15181. Bibcode:2015RSCAd...515172A. doi:10.1039/C4RA11438H.
  10. ^ a b Garg T, Rath G, Goyal AK (April 2015). "Biomaterials-based nanofiber scaffold: targeted and controlled carrier for cell and drug delivery". Journal of Drug Targeting. 23 (3): 202–21. doi:10.3109/1061186X.2014.992899. PMID 25539071. S2CID 8398004.
  11. ^ Farias BV, Pirzada T, Mathew R, Sit TL, Opperman C, Khan SA (2019-12-16). "Electrospun Polymer Nanofibers as Seed Coatings for Crop Protection". ACS Sustainable Chemistry & Engineering. 7 (24): 19848–19856. doi:10.1021/acssuschemeng.9b05200. S2CID 209709462.
  12. ^ Xu T, Ma C, Aytac Z, Hu X, Ng KW, White JC, Demokritou P (2020-06-29). "Enhancing Agrichemical Delivery and Seedling Development with Biodegradable, Tunable, Biopolymer-Based Nanofiber Seed Coatings". ACS Sustainable Chemistry & Engineering. 8 (25): 9537–9548. doi:10.1021/acssuschemeng.0c02696. S2CID 219914870.
  13. ^ De Gregorio PR, Michavila G, Ricciardi Muller L, de Souza Borges C, Pomares MF, Saccol de Sá EL, et al. (2017-05-04). "Beneficial rhizobacteria immobilized in nanofibers for potential application as soybean seed bioinoculants". PLOS ONE. 12 (5): e0176930. Bibcode:2017PLoSO..1276930D. doi:10.1371/journal.pone.0176930. PMC 5417607. PMID 28472087.
  14. ^ a b c Chen JF, Zhu Y, Lu YT, Hodara E, Hou S, Agopian VG, et al. (2016). "Clinical Applications of NanoVelcro Rare-Cell Assays for Detection and Characterization of Circulating Tumor Cells". Theranostics. 6 (9): 1425–39. doi:10.7150/thno.15359. PMC 4924510. PMID 27375790.
  15. ^ a b c d Ke Z, Lin M, Chen JF, Choi JS, Zhang Y, Fong A, et al. (January 2015). "Programming thermoresponsiveness of NanoVelcro substrates enables effective purification of circulating tumor cells in lung cancer patients". ACS Nano. 9 (1): 62–70. doi:10.1021/nn5056282. PMC 4310634. PMID 25495128.
  16. ^ a b Cristofanilli M, Hayes DF, Budd GT, Ellis MJ, Stopeck A, Reuben JM, et al. (March 2005). "Circulating tumor cells: a novel prognostic factor for newly diagnosed metastatic breast cancer". Journal of Clinical Oncology. 23 (7): 1420–30. doi:10.1200/JCO.2005.08.140. PMID 15735118.
  17. ^ a b c Zhang B, Kang F, Tarascon JM, Kim JK (2016). "Recent advances in electrospun carbon nanofibers and their application in electrochemical energy storage". Prog Mater Sci. 76: 319–380. doi:10.1016/j.pmatsci.2015.08.002.
  18. ^ a b "Lithium-air batteries: their time has come". The Economist. Aug 6, 2016.
  19. ^ a b Yang X, He P, Xia Y (2009). "Preparation of mesocellular carbon foam and its application for lithium/oxygen battery". Electrochem Commun. 11 (6): 1127–1130. doi:10.1016/j.elecom.2009.03.029.
  20. ^ a b c Wang X, Drew C, Lee SH, Senecal KJ, Kumar J, Samuelson LA (2002). "Electrospun nanofibrous membranes for highly sensitive optical sensors". Nano Lett. 2 (11): 1273–1275. Bibcode:2002NanoL...2.1273W. CiteSeerX 10.1.1.459.8052. doi:10.1021/nl020216u.
  21. ^ a b Yang Q, Jiang X, Gu F, Ma Z, Zhang J, Tong L (2008). "Polymer micro or nanofibers for optical device applications". J Appl Polym Sci. 110 (2): 1080–1084. doi:10.1002/app.28716.
  22. ^ a b Zubia J, Arrue J (2001). "Plastic optical fibers: an introduction to their technological processes and applications". Optical Fiber Technology. 7 (2): 101–140. Bibcode:2001OptFT...7..101Z. doi:10.1006/ofte.2000.0355.
  23. ^ a b Kelly TL, Gao T, Sailor MJ (April 2011). "Carbon and carbon/silicon composites templated in rugate filters for the adsorption and detection of organic vapors". Advanced Materials. 23 (15): 1776–81. doi:10.1002/adma.201190052. PMID 21374740.
  24. ^ a b Scholten E, Bromberg L, Rutledge GC, Hatton TA (October 2011). "Electrospun polyurethane fibers for absorption of volatile organic compounds from air". ACS Applied Materials & Interfaces. 3 (10): 3902–9. doi:10.1021/am200748y. hdl:1721.1/81271. PMID 21888418. S2CID 7486858.
  25. ^ a b Graham K, Ouyang M, Raether T, Grafe T, McDonald B, Knauf P (2002). "Polymeric nanofibers in air filtration applications". Fifteenth Annual Technical Conference & Expo of the American Filtration & Separations Society.
  26. ^ "A bibliometric review of flow batteries' progress and challenges". Journal of Electrochemical Science and Engineering. 2022.
  27. ^ Maccaferri, Emanuele; Mazzocchetti, Laura; Benelli, Tiziana; Brugo, Tommaso Maria; Zucchelli, Andrea; Giorgini, Loris (2022-01-12). "Self-Assembled NBR/Nomex Nanofibers as Lightweight Rubbery Nonwovens for Hindering Delamination in Epoxy CFRPs". ACS Applied Materials & Interfaces. 14 (1): 1885–1899. doi:10.1021/acsami.1c17643. ISSN 1944-8244. PMC 8763375. PMID 34939406.
  28. ^ a b Nascimento ML, Araújo ES, Cordeiro ER, de Oliveira AH, de Oliveira HP (2015). "A Literature Investigation about Electrospinning and Nanofibers: Historical Trends, Current Status and Future Challenges". Recent Patents on Nanotechnology. 9 (2): 76–85. doi:10.2174/187221050902150819151532. PMID 27009122.
  29. ^ a b c Tucker N, Stanger JJ, Staiger MP, Razzaq H, Hofman K (2012). "The history of the science and technology of electrospinning from 1600 to 1995" (PDF). J Eng Fibers Fabr. 7: 63–73.
  30. ^ Gilbert W (1600). "De magnete, magneticisque corporibus, et de magno magnete tellure". {{cite journal}}: Cite journal requires |journal= (help)
  31. ^ Taylor G (1964). "Disintegration of water drops in an electric field". Proceedings of the Royal Society A. 280 (1382): 383–39 7. Bibcode:1964RSPSA.280..383T. doi:10.1098/rspa.1964.0151. S2CID 15067908.
  32. ^ Strutt J (1882). "On the equilibrium of liquid conducting masses charged with electricity London, Edinburgh, and Dublin". Philos. Mag. 14 (87): 184–186. doi:10.1080/14786448208628425.
  33. ^ Boys C (1887). "On the production, properties, and some suggested uses of the finest threads". Philos. Mag. 23 (145): 489–499. doi:10.1080/14786448708628043.
  34. ^ Cooley J. "Improved methods of and apparatus for electrically separating the relatively volatile liquid component from the component of relatively fixed substances of composite fluids". Espacenet.
  35. ^ Harold S. "Process and apparatus for producing patterned non-woven fabrics". Espacenet.
  36. ^ Lolla D, Gorse J, Kisielowski C, Miao J, Taylor PL, Chase GG, Reneker DH (January 2016). "Polyvinylidene fluoride molecules in nanofibers, imaged at atomic scale by aberration corrected electron microscopy". Nanoscale. 8 (1): 120–8. Bibcode:2015Nanos...8..120L. doi:10.1039/C5NR01619C. PMID 26369731. S2CID 205976678.
  37. ^ a b Sarbatly R, Krishnaiah D, Kamin Z (May 2016). "A review of polymer nanofibres by electrospinning and their application in oil-water separation for cleaning up marine oil spills". Marine Pollution Bulletin. 106 (1–2): 8–16. Bibcode:2016MarPB.106....8S. doi:10.1016/j.marpolbul.2016.03.037. PMID 27016959.
  38. ^ Sivan M, Madheswaran D, Asadian M, Cools P, Thukkaram M, Van Der Voort P, Morent R, De Geyter N, Lukas D (2020-10-15). "Plasma treatment effects on bulk properties of polycaprolactone nanofibrous mats fabricated by uncommon AC electrospinning: A comparative study". Surface and Coatings Technology. 399: 126203. doi:10.1016/j.surfcoat.2020.126203. ISSN 0257-8972. S2CID 224924026.
  39. ^ Madheswaran, Divyabharathi; Sivan, Manikandan; Valtera, Jan; Kostakova, Eva Kuzelova; Egghe, Tim; Asadian, Mahtab; Novotny, Vit; Nguyen, Nhung H. A.; Sevcu, Alena; Morent, Rino; Geyter, Nathalie De (2022). "Composite yarns with antibacterial nanofibrous sheaths produced by collectorless alternating-current electrospinning for suture applications". Journal of Applied Polymer Science. 139 (13): 51851. doi:10.1002/app.51851. ISSN 1097-4628. S2CID 243969095.
  40. ^ Manikandan, S.; Divyabharathi, M.; Tomas, K.; Pavel, P.; David, L. (2019-01-01). "Production of poly (ε-caprolactone) Antimicrobial Nanofibers by Needleless Alternating Current Electrospinning". Materials Today: Proceedings. 6th International Conference on Recent Advances in Materials, Minerals & Environment (RAMM) 2018, RAMM 2018, 27–29 November 2018, Penang, Malaysia. 17: 1100–1104. doi:10.1016/j.matpr.2019.06.526. ISSN 2214-7853. S2CID 202207593.
  41. ^ Garg K, Bowlin GL (March 2011). "Electrospinning jets and nanofibrous structures". Biomicrofluidics. 5 (1): 13403. doi:10.1063/1.3567097. PMC 3082340. PMID 21522493.
  42. ^ Kim KW, Lee KH, Khil MS, Ho YS, Kim HY (2004). "The effect of molecular weight and the linear velocity of drum surface on the properties of electrospun poly(ethylene terephthalate) nonwovens". Fibers Polym. 5 (2): 122–127. doi:10.1007/BF02902925. S2CID 137021572.
  43. ^ Dersch R, Liu T, Schaper AK, Greiner A, Wendorff JH (2003). "Electrospun nanofibers: internal structure and intrinsic orientation". Polym Chem. 41 (4): 545–553. Bibcode:2003JPoSA..41..545D. doi:10.1002/pola.10609.
  44. ^ Beachley V, Wen X (April 2009). "Effect of electrospinning parameters on the nanofiber diameter and length". Materials Science & Engineering. C, Materials for Biological Applications. 29 (3): 663–668. doi:10.1016/j.msec.2008.10.037. PMC 3065832. PMID 21461344.
  45. ^ Leach MK, Feng ZQ, Tuck SJ, Corey JM (January 2011). "Electrospinning fundamentals: optimizing solution and apparatus parameters". Journal of Visualized Experiments. 47 (47): 2494. doi:10.3791/2494. PMC 3182658. PMID 21304466.
  46. ^ a b c d Huang ZM, Zhang YZ, Kotaki M, Ramakrishna S (2003). "A review on polymer nanofibers by electrospinning and their applications in nanocomposites". Compos Sci Technol. 63 (15): 2223–2253. doi:10.1016/S0266-3538(03)00178-7. S2CID 4511766.
  47. ^ a b c Cheng J, Jun Y, Qin J, Lee SH (January 2017). "Electrospinning versus microfluidic spinning of functional fibers for biomedical applications". Biomaterials. 114: 121–143. doi:10.1016/j.biomaterials.2016.10.040. PMID 27880892.
  48. ^ a b c Ma, P. (2004). "Scaffolds for tissue fabrication". Materials Today. 7 (5): 30–40. doi:10.1016/S1369-7021(04)00233-0.
  49. ^ Ramakrishna S, et al. (2005). An Introduction to Electrospinning and Nanofibers. World Scientific. ISBN 978-981-256-415-3.
  50. ^ Ondarcuhu T, Joachim C (1998). "Drawing a single nanofiber over hundreds of microns". Europhys Lett. 42 (2): 215–220. Bibcode:1998EL.....42..215O. doi:10.1209/epl/i1998-00233-9. S2CID 250737386.
  51. ^ a b Martin C (1995). "Template synthesis of electronically conductive polymer nanostructures". Acc Chem Res. 28 (2): 61–68. doi:10.1021/ar00050a002.
  52. ^ a b Martin CR (December 1994). "Nanomaterials: a membrane-based synthetic approach". Science. 266 (5193): 1961–6. Bibcode:1994Sci...266.1961M. doi:10.1126/science.266.5193.1961. PMID 17836514. S2CID 45456343.
  53. ^ Malkar NB, Lauer-Fields JL, Juska D, Fields GB (2003). "Characterization of peptide-amphiphiles possessing cellular activation sequences". Biomacromolecules. 4 (3): 518–28. doi:10.1021/bm0256597. PMID 12741765.
  54. ^ Zhang C, Xue X, Luo Q, Li Y, Yang K, Zhuang X, et al. (November 2014). "Self-assembled Peptide nanofibers designed as biological enzymes for catalyzing ester hydrolysis". ACS Nano. 8 (11): 11715–23. doi:10.1021/nn5051344. PMID 25375351.
  55. ^ Shih YR, Chen CN, Tsai SW, Wang YJ, Lee OK (November 2006). "Growth of mesenchymal stem cells on electrospun type I collagen nanofibers". Stem Cells. 24 (11): 2391–7. doi:10.1634/stemcells.2006-0253. PMID 17071856.
  56. ^ Kim KH, Jeong L, Park HN, Shin SY, Park WH, Lee SC, et al. (November 2005). "Biological efficacy of silk fibroin nanofiber membranes for guided bone regeneration". Journal of Biotechnology. 120 (3): 327–39. doi:10.1016/j.jbiotec.2005.06.033. PMID 16150508.
  57. ^ a b Azimi B, Nourpanah P, Rabiee M, Arbab S (2014). "Poly (ε-caprolactone) fiber: an overview". J Eng Fibers Fabr. 9 (3): 74–90.
  58. ^ Hejazi F, Mirzadeh H (September 2016). "Novel 3D scaffold with enhanced physical and cell response properties for bone tissue regeneration, fabricated by patterned electrospinning/electrospraying". Journal of Materials Science. Materials in Medicine. 27 (9): 143. doi:10.1007/s10856-016-5748-8. PMID 27550014. S2CID 23987237.
  59. ^ a b c d e Burg KJ, Porter S, Kellam JF (December 2000). "Biomaterial developments for bone tissue engineering". Biomaterials. 21 (23): 2347–59. doi:10.1016/s0142-9612(00)00102-2. PMID 11055282.
  60. ^ a b Sun B, Long YZ, Zhang HD, Li MM, Duvail JL, Jiang XY, Yin HL (2014). "Advances in three-dimensional nanofibrous macrostructures via electrospinning". Prog Polym Sci. 39 (5): 862–890. doi:10.1016/j.progpolymsci.2013.06.002.
  61. ^ Simon, Eric M. (1988). "NIH PHASE I FINAL REPORT: FIBROUS SUBSTRATES FOR CELL CULTURE (R3RR03544A) (PDF Download Available)". ResearchGate. Retrieved 2017-05-22.
  62. ^ Sukumar UK, Packirisamy G (2019-10-08). "Fabrication of Nanofibrous Scaffold Grafted with Gelatin Functionalized Polystyrene Microspheres for Manifesting Nanomechanical Cues of Stretch Stimulated Fibroblast". ACS Applied Bio Materials. 2 (12): 5323–5339. doi:10.1021/acsabm.9b00580. PMID 35021533. S2CID 208733153.
  63. ^ a b c d Betz RR (May 2002). "Limitations of autograft and allograft: new synthetic solutions". Orthopedics. 25 (5 Suppl): s561-70. doi:10.3928/0147-7447-20020502-04. PMID 12038843.
  64. ^ Tuli R, Li WJ, Tuan RS (2003). "Current state of cartilage tissue engineering". Arthritis Research & Therapy. 5 (5): 235–8. doi:10.1186/ar991. PMC 193737. PMID 12932283.
  65. ^ Lin VS, Lee MC, O'Neal S, McKean J, Sung KL (October 1999). "Ligament tissue engineering using synthetic biodegradable fiber scaffolds". Tissue Engineering. 5 (5): 443–52. doi:10.1089/ten.1999.5.443. PMID 10586100.
  66. ^ Riboldi SA, Sampaolesi M, Neuenschwander P, Cossu G, Mantero S (August 2005). "Electrospun degradable polyesterurethane membranes: potential scaffolds for skeletal muscle tissue engineering". Biomaterials. 26 (22): 4606–15. doi:10.1016/j.biomaterials.2004.11.035. PMID 15722130.
  67. ^ Matthews JA, Wnek GE, Simpson DG, Bowlin GL (2002). "Electrospinning of collagen nanofibers". Biomacromolecules. 3 (2): 232–8. doi:10.1021/bm015533u. PMID 11888306.
  68. ^ Mo XM, Xu CY, Kotaki M, Ramakrishna S (May 2004). "Electrospun P(LLA-CL) nanofiber: a biomimetic extracellular matrix for smooth muscle cell and endothelial cell proliferation". Biomaterials. 25 (10): 1883–90. doi:10.1016/j.biomaterials.2003.08.042. PMID 14738852.
  69. ^ Yang F, Xu CY, Kotaki M, Wang S, Ramakrishna S (2004). "Characterization of neural stem cells on electrospun poly(L-lactic acid) nanofibrous scaffold". Journal of Biomaterials Science. Polymer Edition. 15 (12): 1483–97. doi:10.1163/1568562042459733. PMID 15696794. S2CID 2990409.
  70. ^ Fogaça R, Ouimet MA, Catalani LH, Uhrich KE (2013). Bioactive-based poly(anhydride-esters) and blends for controlled drug delivery. American Chemical Society. ISBN 9780841227996.
  71. ^ Hu X, Liu S, Zhou G, Huang Y, Xie Z, Jing X (July 2014). "Electrospinning of polymeric nanofibers for drug delivery applications". Journal of Controlled Release. 185: 12–21. doi:10.1016/j.jconrel.2014.04.018. PMID 24768792.
  72. ^ Yoo HS, Kim TG, Park TG (October 2009). "Surface-functionalized electrospun nanofibers for tissue engineering and drug delivery". Advanced Drug Delivery Reviews. 61 (12): 1033–42. doi:10.1016/j.addr.2009.07.007. PMID 19643152.
  73. ^ a b Zong X, Li S, Chen E, Garlick B, Kim KS, Fang D, et al. (November 2004). "Prevention of postsurgery-induced abdominal adhesions by electrospun bioabsorbable nanofibrous poly(lactide-co-glycolide)-based membranes". Annals of Surgery. 240 (5): 910–5. doi:10.1097/01.sla.0000143302.48223.7e. PMC 1356499. PMID 15492575.
  74. ^ a b Kumbar SG, Nair LS, Bhattacharyya S, Laurencin CT (2006). "Polymeric nanofibers as novel carriers for the delivery of therapeutic molecules". Journal of Nanoscience and Nanotechnology. 6 (9–10): 2591–607. doi:10.1166/jnn.2006.462. PMID 17048469.
  75. ^ Ignatova M, Rashkov I, Manolova N (April 2013). "Drug-loaded electrospun materials in wound-dressing applications and in local cancer treatment". Expert Opinion on Drug Delivery. 10 (4): 469–83. doi:10.1517/17425247.2013.758103. PMID 23289491. S2CID 24627745.
  76. ^ Cohen SJ, Punt CJ, Iannotti N, Saidman BH, Sabbath KD, Gabrail NY, et al. (July 2008). "Relationship of circulating tumor cells to tumor response, progression-free survival, and overall survival in patients with metastatic colorectal cancer". Journal of Clinical Oncology. 26 (19): 3213–21. doi:10.1200/JCO.2007.15.8923. PMID 18591556.
  77. ^ Rack B, Schindlbeck C, Jückstock J, Andergassen U, Hepp P, Zwingers T, et al. (May 2014). "Circulating tumor cells predict survival in early average-to-high risk breast cancer patients". Journal of the National Cancer Institute. 106 (5): 1–11. doi:10.1093/jnci/dju066. PMC 4112925. PMID 24832787.
  78. ^ Lu YT, Zhao L, Shen Q, Garcia MA, Wu D, Hou S, et al. (December 2013). "NanoVelcro Chip for CTC enumeration in prostate cancer patients". Methods. 64 (2): 144–52. doi:10.1016/j.ymeth.2013.06.019. PMC 3834112. PMID 23816790.
  79. ^ Jiang R, Lu YT, Ho H, Li B, Chen JF, Lin M, et al. (December 2015). "A comparison of isolated circulating tumor cells and tissue biopsies using whole-genome sequencing in prostate cancer". Oncotarget. 6 (42): 44781–93. doi:10.18632/oncotarget.6330. PMC 4792591. PMID 26575023.
  80. ^ Zhao L, Lu YT, Li F, Wu K, Hou S, Yu J, et al. (June 2013). "High-purity prostate circulating tumor cell isolation by a polymer nanofiber-embedded microchip for whole exome sequencing". Advanced Materials. 25 (21): 2897–902. Bibcode:2013AdM....25.2897Z. doi:10.1002/adma.201205237. PMC 3875622. PMID 23529932.
  81. ^ Hou S, Zhao H, Zhao L, Shen Q, Wei KS, Suh DY, et al. (March 2013). "Capture and stimulated release of circulating tumor cells on polymer-grafted silicon nanostructures". Advanced Materials. 25 (11): 1547–51. Bibcode:2013AdM....25.1547H. doi:10.1002/adma.201203185. PMC 3786692. PMID 23255101.
  82. ^ Mitchell RR, Gallant BM, Thompson CV, Shao-Horn Y (2011). "All-carbon-nanofiber electrodes for high-energy rechargeable LiO2 batteries". Energy Environ Sci. 4 (8): 2952–2958. doi:10.1039/c1ee01496j. S2CID 96799565.
  83. ^ Singhal R, Kalra V (2016). "Binder-free hierarchically-porous carbon nanofibers decorated with cobalt nanoparticles as efficient cathodes for lithium-oxygen batteries". RSC Adv. 6 (105): 103072–103080. Bibcode:2016RSCAd...6j3072S. doi:10.1039/C6RA16874D.
  84. ^ Zhu Z, Kushima A, Yin Z, Qi L, Amine K, Lu J, Li J (2016). "Anion-redox nanolithia cathodes for Li-ion batteries". Nature Energy. 1 (8): 16111. Bibcode:2016NatEn...116111Z. doi:10.1038/nenergy.2016.111. S2CID 366009.
  85. ^ Peters K (2011). "Polymer optical fiber sensors—a review". Smart Mater Struct. 20 (1): 013002. Bibcode:2011SMaS...20a3002P. doi:10.1088/0964-1726/20/1/013002. S2CID 52238312.
  86. ^ Liu H, Edel JB, Bellan LM, Craighead HG (April 2006). "Electrospun polymer nanofibers as subwavelength optical waveguides incorporating quantum dots". Small. 2 (4): 495–9. doi:10.1002/smll.200500432. PMID 17193073.
  87. ^ Meng C, Xiao Y, Wang P, Zhang L, Liu Y, Tong L (September 2011). "Quantum-dot-doped polymer nanofibers for optical sensing". Advanced Materials. 23 (33): 3770–4. doi:10.1002/adma.201101392. PMID 21766349. S2CID 6264401.

Read other articles:

Centre William RappardInformasi umumGaya arsitekturKlasikLokasiJenewa, SwissKoordinat46°13′27″N 06°08′58″E / 46.22417°N 6.14944°E / 46.22417; 6.14944Koordinat: 46°13′27″N 06°08′58″E / 46.22417°N 6.14944°E / 46.22417; 6.14944Mulai dibangun1923Rampung1926Desain dan konstruksiArsitekGeorge Épitaux Centre William Rappard di Rue de Lausanne 154, Jenewa, Swiss, dibangun antara 1923 dan 1926 untuk dijadikan markas International...

 

Halaman ini berisi artikel tentang seri televisi Korea Selatan. Untuk konsepsi kuno tentang waktu dan kesempatan, lihat Kairos. KairosPoster promosiHangul카이로스 GenrePerjalanan waktu Fantasi Cerita seruPembuatMBC Production Plan (Kwon Seong-chang)Ditulis olehLee Soo-hyunSutradaraPark Seung-wooPemeranShin Sung-rokLee Se-youngAhn Bo-hyunNam Gyu-riKang Seung-yoonPenggubah lagu temaJang Young-kyuNegara asalKorea SelatanBahasa asliKoreaJmlh. episode16ProduksiProduserSon Ok-hyun Ju Bang-okPen...

 

Artikel ini bukan mengenai Kabupaten Simalungun. Artikel ini mengandung Surat Batak. Tanpa dukungan perenderan yang baik, Anda mungkin akan melihat tanda tanya, kotak, atau simbol lain. Batak Simalungun Halak Simalungun ᯃᯟᯃ᯳ᯅᯖᯃ᯳ᯙᯫᯕᯟᯮᯝᯮᯉᯮ᯳ Bungaran Saragih Radjamin Purba Djabanten Damanik Djaidin Purba Laurimba Saragih Marim Purba Maruli Wagner Damanik Adrian Pangarapan Damanik Ahmad Taufan Damanik Jopinus Ramli Saragih Anicetus Bongsu Antonius Sinaga Yoseph...

Pipit-api Lagonosticta Red-billed firefinch (Lagonosticta senegala)TaksonomiKerajaanAnimaliaFilumChordataKelasAvesOrdoPasseriformesFamiliEstrildidaeGenusLagonosticta Cabanis, 1851 Species11, see textlbs Pipit-api membentuk genus, Lagonosticta, burung Afrika pemakan biji kecil dalam keluarga Estrildidae . Genus ini diperkenalkan oleh ahli burung Jerman Jean Cabanis pada tahun 1851.[1] Jenis spesies ini kemudian ditetapkan sebagai pipit-api Afrika.[2] Nama tersebut menggabungkan...

 

Untuk film, lihat The Boy in the Striped Pyjamas (film). Anak Lelaki Berpiama Garis-garis Sampul edisi IndonesiaPengarangJohn BoyneNegaraIrlandiaBahasaInggrisGenreFiksi sejarahPenerbitDavid Fickling BooksTanggal terbit6 Januari 2006Jenis mediaPrint (hard cover & paper back)Halaman216ISBNISBN 0-385-60940-XOCLC62132588Desimal Dewey823.914 22LCCCS 2006/45764Diikuti olehAll the Broken Places  Anak Lelaki Berpiama Garis-garis adalah sebuah novel karya John Boyne. Berce...

 

County in Florida, United States County in FloridaColumbia CountyCountyColumbia County Courthouse in Lake CityLocation within the U.S. state of FloridaFlorida's location within the U.S.Coordinates: 30°14′N 82°38′W / 30.23°N 82.63°W / 30.23; -82.63Country United StatesState FloridaFoundedFebruary 4, 1832Named forChristopher ColumbusSeatLake CityLargest cityLake CityArea • Total801 sq mi (2,070 km2) • Land798 ...

Dil Ek MandirPosterSutradaraC. V. SridharCeritaC. V. SridharPemeranRajendra KumarMeena KumariRaaj KumarPenata musikShankar JaikishanSinematograferA. VincentPenyuntingN. M ShankarTanggal rilis 8 Maret 1963 (1963-03-08) [1]NegaraIndiaBahasaHindiPendapatankotor₹1,1 crore (setara dengan ₹650 crore atau US$91 juta pada tahun 2023) [2]Dil Ek Mandir (terj. har. 'Jantung adalah sebuah kuil') adalah sebuah film drama percintaan berbahasa Hindi...

 

Kimba the White Lionジャングル大帝(Janguru Taitei) MangaPengarangOsamu TezukaPenerbitGakudoshaKobunshaKodanshaPenerbit bahasa InggrisJP Jippi English Comics (dwibahasa)[1]MajalahManga ShōnenDemografiShōnenTerbitNovember 1950 – April 1954Volume3 Seri animeSutradaraEiichi YamamotoMusikIsao TomitaToriro Miki (theme song)StudioMushi ProductionPelisensiNA Right Stuf Inc.SaluranasliFuji TVSaluran bahasa InggrisAU ABCUK Cartoon NetworkUS NBCTayang 6 Oktober 1965 – 28 September 1...

 

Синелобый амазон Научная классификация Домен:ЭукариотыЦарство:ЖивотныеПодцарство:ЭуметазоиБез ранга:Двусторонне-симметричныеБез ранга:ВторичноротыеТип:ХордовыеПодтип:ПозвоночныеИнфратип:ЧелюстноротыеНадкласс:ЧетвероногиеКлада:АмниотыКлада:ЗавропсидыКласс:Пт�...

Railway station in Sydney, New South Wales, Australia Kings CrossStation entrance, August 2017General informationLocationDarlinghurst Road, Kings CrossCoordinates33°52′29″S 151°13′21″E / 33.87468°S 151.22242°E / -33.87468; 151.22242Owned byTransport Asset Holding EntityOperated bySydney TrainsLine(s)Eastern SuburbsDistance3.41 kilometres from CentralPlatforms2 (1 island)Tracks2ConnectionsBusConstructionStructure typeUndergroundAccessibleYesOther information...

 

Questa voce sull'argomento tennisti è solo un abbozzo. Contribuisci a migliorarla secondo le convenzioni di Wikipedia. Treat Huey Treat Conrad Huey allo US Open 2016 Nazionalità  Filippine Altezza 178 cm Peso 82 kg Tennis Specialità Doppio Termine carriera agosto 2023[1] Carriera Singolare1 Vittorie/sconfitte 9-7 (56,25%) Titoli vinti 0 Miglior ranking 689º (30 novembre 2009) Doppio1 Vittorie/sconfitte 192-173 (52.6%) Titoli vinti 8 Miglior ranking 18º (11 luglio 2016)...

 

Emirati professional football club This article needs additional citations for verification. Please help improve this article by adding citations to reliable sources. Unsourced material may be challenged and removed.Find sources: Emirates Club – news · newspapers · books · scholar · JSTOR (July 2021) (Learn how and when to remove this message) Football clubEmirates Clubنادي الإماراتFull nameEmirates Cultural and Sports ClubNickname(s)The Fa...

Media Organization Dubai Media Incorporated (DMI)TypeTelevision, Radio, Print & Online MediaCountryUnited Arab EmiratesAvailabilityMiddle East and North AfricaOwnerDubaiKey peopleMaktoum bin Mohammed bin Rashid Al Maktoum(Chairman)Ahmad Abdalla Al Shaikh(Board Member & Managing Director)Former namesDubai Department of MediaOfficial websitedmi.gov.ae (EN)dmi.gov.ae (AR) Dubai Media Incorporated (DMI) is the official media organization of the government of Dubai. It was established in 2...

 

Early shopping center - 1957 Detroit Lincoln Park Shopping CenterVacant stores overlooking empty parking lots at the Lincoln Park Shopping Center, December 2014LocationAllen Park and Lincoln Park, Michigan, United StatesCoordinates42°15′27″N 83°11′37″W / 42.2575°N 83.1937°W / 42.2575; -83.1937AddressSouthfield Road and Dix HighwayOpening date1956; 68 years ago (1956)Closing dateJanuary 6, 2019; 5 years ago (2019-01-06)No....

 

Украинцы в Австралииукр. Українці в Австралії Численность в Австралии — около 38 791 человек. Расселение  Австралия Язык украинский, английский Религия в большинстве случаев — христиане: греко-католики православные  Медиафайлы на Викискладе Почтовая марка, посвящен...

2016年美國總統選舉 ← 2012 2016年11月8日 2020 → 538個選舉人團席位獲勝需270票民意調查投票率55.7%[1][2] ▲ 0.8 %   获提名人 唐納·川普 希拉莉·克林頓 政党 共和黨 民主党 家鄉州 紐約州 紐約州 竞选搭档 迈克·彭斯 蒂姆·凱恩 选举人票 304[3][4][註 1] 227[5] 胜出州/省 30 + 緬-2 20 + DC 民選得票 62,984,828[6] 65,853,514[6]...

 

2020年夏季奥林匹克运动会波兰代表團波兰国旗IOC編碼POLNOC波蘭奧林匹克委員會網站olimpijski.pl(英文)(波兰文)2020年夏季奥林匹克运动会(東京)2021年7月23日至8月8日(受2019冠状病毒病疫情影响推迟,但仍保留原定名称)運動員206參賽項目24个大项旗手开幕式:帕维尔·科热尼奥夫斯基(游泳)和马娅·沃什乔夫斯卡(自行车)[1]闭幕式:卡罗利娜·纳亚(皮划艇)&#...

 

1985 single by Jimmy Barnes DaylightSingle by Jimmy Barnesfrom the album Bodyswerve B-side Paradise Resurrection Shuffle (live) (Limited edition side two only) ReleasedJanuary 1985StudioRhinoceros StudiosLabelMushroomSongwriter(s)Jimmy BarnesProducer(s)Jimmy Barnes, Mark OpitzJimmy Barnes singles chronology Promise Me You'll Call (1984) Daylight (1985) I'd Die to Be with You Tonight (1985) Alternative coverLimited edition cover Daylight is a song by Australian rock musician, Jimmy Barnes. Rel...

Bilateral relationsAntigua and Barbuda-United States relations Antigua and Barbuda United States The US delivers coronavirus vaccines to Antigua and Barbuda as part of the COVAX program in 2021 Relations between Antigua and Barbuda and the United States have been friendly since Antigua and Barbuda's independence from the United Kingdom in 1981. The United States has supported the government of Antigua and Barbuda's effort to expand its economic base and to improve its citizens' standard of li...

 

1996 Republican Party presidential primaries ← 1992 January 29 to June 4, 1996 2000 →   Candidate Bob Dole Pat Buchanan Steve Forbes Home state Kansas Virginia New Jersey Delegate count 1,437 101 51 Contests won 46 4 2 Popular vote 9,024,742 3,184,943 1,751,187 Percentage 58.8% 20.8% 11.4% Gold denotes a state won by Pat Buchanan. Green denotes a state won by Steve Forbes. Purple denotes a state won by Bob Dole. Gray denotes a territory that did...