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This reprint includes research articles on various applications of electrospun nanofibers. Nanofibers have potential to be used in tissue engineering, energy harvesting, sensors, separators, water filtration, air filtration, and other applications as well. This Special Issue has received 11 interesting research articles, which covers such application areas.
Technology: general issues --- nanofibers --- fibroblast --- cell culture --- cell adhesion --- cell viability --- biobased polyester --- silver nanoclusters --- sericin --- cellulose acetate --- electrospinning --- Antibacterial Nanofibers --- polybutylene succinate --- filter membrane --- electrospun fiber --- graphene oxide --- protein adsorption --- nanofiber --- hollow ball --- alginate --- tissue engineering --- 3D structure --- nanofiber fabric --- protein --- affinity adsorption --- selective separation --- poly(homocysteine thiolactone) --- sensing --- catalysis --- nanonet --- polyacrylonitrile --- surfactant --- meltblown --- nanofiber/nanonet --- hybrid nanofiber --- cytotoxicity --- folic acid --- in vitro study --- drug release --- polyimide --- solid state batteries --- composite polymer electrolyte --- photo polymerization --- fireproof --- cellulose nanofiber --- silver nanoparticle --- orange essential oil --- antibacterial activity --- polymer composites --- nanoparticle --- polymer blends --- medical applications --- n/a
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This reprint includes research articles on various applications of electrospun nanofibers. Nanofibers have potential to be used in tissue engineering, energy harvesting, sensors, separators, water filtration, air filtration, and other applications as well. This Special Issue has received 11 interesting research articles, which covers such application areas.
nanofibers --- fibroblast --- cell culture --- cell adhesion --- cell viability --- biobased polyester --- silver nanoclusters --- sericin --- cellulose acetate --- electrospinning --- Antibacterial Nanofibers --- polybutylene succinate --- filter membrane --- electrospun fiber --- graphene oxide --- protein adsorption --- nanofiber --- hollow ball --- alginate --- tissue engineering --- 3D structure --- nanofiber fabric --- protein --- affinity adsorption --- selective separation --- poly(homocysteine thiolactone) --- sensing --- catalysis --- nanonet --- polyacrylonitrile --- surfactant --- meltblown --- nanofiber/nanonet --- hybrid nanofiber --- cytotoxicity --- folic acid --- in vitro study --- drug release --- polyimide --- solid state batteries --- composite polymer electrolyte --- photo polymerization --- fireproof --- cellulose nanofiber --- silver nanoparticle --- orange essential oil --- antibacterial activity --- polymer composites --- nanoparticle --- polymer blends --- medical applications --- n/a
Choose an application
This reprint includes research articles on various applications of electrospun nanofibers. Nanofibers have potential to be used in tissue engineering, energy harvesting, sensors, separators, water filtration, air filtration, and other applications as well. This Special Issue has received 11 interesting research articles, which covers such application areas.
Technology: general issues --- nanofibers --- fibroblast --- cell culture --- cell adhesion --- cell viability --- biobased polyester --- silver nanoclusters --- sericin --- cellulose acetate --- electrospinning --- Antibacterial Nanofibers --- polybutylene succinate --- filter membrane --- electrospun fiber --- graphene oxide --- protein adsorption --- nanofiber --- hollow ball --- alginate --- tissue engineering --- 3D structure --- nanofiber fabric --- protein --- affinity adsorption --- selective separation --- poly(homocysteine thiolactone) --- sensing --- catalysis --- nanonet --- polyacrylonitrile --- surfactant --- meltblown --- nanofiber/nanonet --- hybrid nanofiber --- cytotoxicity --- folic acid --- in vitro study --- drug release --- polyimide --- solid state batteries --- composite polymer electrolyte --- photo polymerization --- fireproof --- cellulose nanofiber --- silver nanoparticle --- orange essential oil --- antibacterial activity --- polymer composites --- nanoparticle --- polymer blends --- medical applications --- nanofibers --- fibroblast --- cell culture --- cell adhesion --- cell viability --- biobased polyester --- silver nanoclusters --- sericin --- cellulose acetate --- electrospinning --- Antibacterial Nanofibers --- polybutylene succinate --- filter membrane --- electrospun fiber --- graphene oxide --- protein adsorption --- nanofiber --- hollow ball --- alginate --- tissue engineering --- 3D structure --- nanofiber fabric --- protein --- affinity adsorption --- selective separation --- poly(homocysteine thiolactone) --- sensing --- catalysis --- nanonet --- polyacrylonitrile --- surfactant --- meltblown --- nanofiber/nanonet --- hybrid nanofiber --- cytotoxicity --- folic acid --- in vitro study --- drug release --- polyimide --- solid state batteries --- composite polymer electrolyte --- photo polymerization --- fireproof --- cellulose nanofiber --- silver nanoparticle --- orange essential oil --- antibacterial activity --- polymer composites --- nanoparticle --- polymer blends --- medical applications
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Bacillus thuringiensis (Bt)-based products are the most successful microbial insecticides to date. This entomopathogenic bacterium produces different kinds of proteins whose specific toxicity has been shown against a wide range of insect orders, nematodes, mites, protozoa, and human cancer cells. Some of these proteins are accumulated in parasporal crystals during the sporulation phase (Cry and Cyt proteins), whereas other proteins are secreted in the vegetative phase of growth (Vip and Sip toxins). Currently, insecticidal proteins belonging to different groups (Cry and Vip3 proteins) are widely used to control insect pests and vectors both in formulated sprays and in transgenic crops (the so-called Bt crops). Despite the extensive use of these proteins in insect pest control, especially Cry and Vip3, their mode of action is not completely understood. The aim of this Special Issue was to gather information that could summarize (in the form of review papers) or expand (research papers) the knowledge of the structure and function of Bt proteins, as well as shed light on their mode of action, especially regarding the insect receptors. This subject has generated great interest, and this interest has been materialized into the 18 papers of important scientific value in the field (5 reviews and 13 research papers) that have been compiled in this issue.
Research & information: general --- Bacillus thuringiensis --- Plutella xylostella --- Cry1Ac resistance --- trypsin-like midgut protease --- protoxin activation --- Spodoptera spp., Helicoverpa armigera --- Mamestra brassicae --- Anticarsia gemmatalis --- Ostrinia furnacalis --- Cry2Ab toxin --- Bombyx mori --- ATP-binding cassette subfamily a member 2 (ABCA2) --- genome editing --- transcription activator-like effector-nucleases (TALENs) --- HEK293T cell --- functional receptor --- Vip3Aa --- lysosome --- mitochondria --- apoptosis --- Sf9 cells --- Cry1Ab --- oligomer formation --- Sf21 cell line --- Ostrinia nubilalis --- Lobesia botrana --- Leptinotarsa decemlineata --- bioassay --- Cyt2Aa2 toxin --- protein-lipid binding --- erythrocyte membrane --- AFM --- QCM-D --- Asian corn borer --- ABCC2 --- CRISPR/Cas9 --- Cry1Fa --- resistance --- chitin-binding protein --- adhesion --- peritrophic matrix --- Vip3A --- Spodoptera litura --- site-directed mutagenesis --- Cry --- Cyt --- parasporins --- S-layer proteins --- Vip --- Sip --- membrane receptors --- insecticidal activity --- anticancer activity --- Aedes aegypti --- minor proteins --- synergy --- mosquito control --- Bti --- Spodoptera frugiperda --- cadherin --- mode of action of Cry toxin --- insecticidal proteins --- insect resistance --- tobacco budworm --- Bacillus thuringiensis proteins --- coleopteran pests --- structure --- mode of action --- 3D-structure --- biological control --- antimicrobial peptide --- gut microbiota --- vegetative insecticidal proteins --- pyramids --- 3D-Cry toxins --- in vitro evolution --- rational design --- toxin enhancement --- Bacillus thuringiensis --- Plutella xylostella --- Cry1Ac resistance --- trypsin-like midgut protease --- protoxin activation --- Spodoptera spp., Helicoverpa armigera --- Mamestra brassicae --- Anticarsia gemmatalis --- Ostrinia furnacalis --- Cry2Ab toxin --- Bombyx mori --- ATP-binding cassette subfamily a member 2 (ABCA2) --- genome editing --- transcription activator-like effector-nucleases (TALENs) --- HEK293T cell --- functional receptor --- Vip3Aa --- lysosome --- mitochondria --- apoptosis --- Sf9 cells --- Cry1Ab --- oligomer formation --- Sf21 cell line --- Ostrinia nubilalis --- Lobesia botrana --- Leptinotarsa decemlineata --- bioassay --- Cyt2Aa2 toxin --- protein-lipid binding --- erythrocyte membrane --- AFM --- QCM-D --- Asian corn borer --- ABCC2 --- CRISPR/Cas9 --- Cry1Fa --- resistance --- chitin-binding protein --- adhesion --- peritrophic matrix --- Vip3A --- Spodoptera litura --- site-directed mutagenesis --- Cry --- Cyt --- parasporins --- S-layer proteins --- Vip --- Sip --- membrane receptors --- insecticidal activity --- anticancer activity --- Aedes aegypti --- minor proteins --- synergy --- mosquito control --- Bti --- Spodoptera frugiperda --- cadherin --- mode of action of Cry toxin --- insecticidal proteins --- insect resistance --- tobacco budworm --- Bacillus thuringiensis proteins --- coleopteran pests --- structure --- mode of action --- 3D-structure --- biological control --- antimicrobial peptide --- gut microbiota --- vegetative insecticidal proteins --- pyramids --- 3D-Cry toxins --- in vitro evolution --- rational design --- toxin enhancement
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Bacillus thuringiensis (Bt)-based products are the most successful microbial insecticides to date. This entomopathogenic bacterium produces different kinds of proteins whose specific toxicity has been shown against a wide range of insect orders, nematodes, mites, protozoa, and human cancer cells. Some of these proteins are accumulated in parasporal crystals during the sporulation phase (Cry and Cyt proteins), whereas other proteins are secreted in the vegetative phase of growth (Vip and Sip toxins). Currently, insecticidal proteins belonging to different groups (Cry and Vip3 proteins) are widely used to control insect pests and vectors both in formulated sprays and in transgenic crops (the so-called Bt crops). Despite the extensive use of these proteins in insect pest control, especially Cry and Vip3, their mode of action is not completely understood. The aim of this Special Issue was to gather information that could summarize (in the form of review papers) or expand (research papers) the knowledge of the structure and function of Bt proteins, as well as shed light on their mode of action, especially regarding the insect receptors. This subject has generated great interest, and this interest has been materialized into the 18 papers of important scientific value in the field (5 reviews and 13 research papers) that have been compiled in this issue.
Research & information: general --- Bacillus thuringiensis --- Plutella xylostella --- Cry1Ac resistance --- trypsin-like midgut protease --- protoxin activation --- Spodoptera spp., Helicoverpa armigera --- Mamestra brassicae --- Anticarsia gemmatalis --- Ostrinia furnacalis --- Cry2Ab toxin --- Bombyx mori --- ATP-binding cassette subfamily a member 2 (ABCA2) --- genome editing --- transcription activator-like effector-nucleases (TALENs) --- HEK293T cell --- functional receptor --- Vip3Aa --- lysosome --- mitochondria --- apoptosis --- Sf9 cells --- Cry1Ab --- oligomer formation --- Sf21 cell line --- Ostrinia nubilalis --- Lobesia botrana --- Leptinotarsa decemlineata --- bioassay --- Cyt2Aa2 toxin --- protein-lipid binding --- erythrocyte membrane --- AFM --- QCM-D --- Asian corn borer --- ABCC2 --- CRISPR/Cas9 --- Cry1Fa --- resistance --- chitin-binding protein --- adhesion --- peritrophic matrix --- Vip3A --- Spodoptera litura --- site-directed mutagenesis --- Cry --- Cyt --- parasporins --- S-layer proteins --- Vip --- Sip --- membrane receptors --- insecticidal activity --- anticancer activity --- Aedes aegypti --- minor proteins --- synergy --- mosquito control --- Bti --- Spodoptera frugiperda --- cadherin --- mode of action of Cry toxin --- insecticidal proteins --- insect resistance --- tobacco budworm --- Bacillus thuringiensis proteins --- coleopteran pests --- structure --- mode of action --- 3D-structure --- biological control --- antimicrobial peptide --- gut microbiota --- vegetative insecticidal proteins --- pyramids --- 3D-Cry toxins --- in vitro evolution --- rational design --- toxin enhancement --- n/a
Choose an application
Bacillus thuringiensis (Bt)-based products are the most successful microbial insecticides to date. This entomopathogenic bacterium produces different kinds of proteins whose specific toxicity has been shown against a wide range of insect orders, nematodes, mites, protozoa, and human cancer cells. Some of these proteins are accumulated in parasporal crystals during the sporulation phase (Cry and Cyt proteins), whereas other proteins are secreted in the vegetative phase of growth (Vip and Sip toxins). Currently, insecticidal proteins belonging to different groups (Cry and Vip3 proteins) are widely used to control insect pests and vectors both in formulated sprays and in transgenic crops (the so-called Bt crops). Despite the extensive use of these proteins in insect pest control, especially Cry and Vip3, their mode of action is not completely understood. The aim of this Special Issue was to gather information that could summarize (in the form of review papers) or expand (research papers) the knowledge of the structure and function of Bt proteins, as well as shed light on their mode of action, especially regarding the insect receptors. This subject has generated great interest, and this interest has been materialized into the 18 papers of important scientific value in the field (5 reviews and 13 research papers) that have been compiled in this issue.
Bacillus thuringiensis --- Plutella xylostella --- Cry1Ac resistance --- trypsin-like midgut protease --- protoxin activation --- Spodoptera spp., Helicoverpa armigera --- Mamestra brassicae --- Anticarsia gemmatalis --- Ostrinia furnacalis --- Cry2Ab toxin --- Bombyx mori --- ATP-binding cassette subfamily a member 2 (ABCA2) --- genome editing --- transcription activator-like effector-nucleases (TALENs) --- HEK293T cell --- functional receptor --- Vip3Aa --- lysosome --- mitochondria --- apoptosis --- Sf9 cells --- Cry1Ab --- oligomer formation --- Sf21 cell line --- Ostrinia nubilalis --- Lobesia botrana --- Leptinotarsa decemlineata --- bioassay --- Cyt2Aa2 toxin --- protein-lipid binding --- erythrocyte membrane --- AFM --- QCM-D --- Asian corn borer --- ABCC2 --- CRISPR/Cas9 --- Cry1Fa --- resistance --- chitin-binding protein --- adhesion --- peritrophic matrix --- Vip3A --- Spodoptera litura --- site-directed mutagenesis --- Cry --- Cyt --- parasporins --- S-layer proteins --- Vip --- Sip --- membrane receptors --- insecticidal activity --- anticancer activity --- Aedes aegypti --- minor proteins --- synergy --- mosquito control --- Bti --- Spodoptera frugiperda --- cadherin --- mode of action of Cry toxin --- insecticidal proteins --- insect resistance --- tobacco budworm --- Bacillus thuringiensis proteins --- coleopteran pests --- structure --- mode of action --- 3D-structure --- biological control --- antimicrobial peptide --- gut microbiota --- vegetative insecticidal proteins --- pyramids --- 3D-Cry toxins --- in vitro evolution --- rational design --- toxin enhancement --- n/a
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