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Publication DateAntimicrobial Agents and Chemotherapy, ISSN 0066-4804, 11/2016, Volume 60, Issue 11, pp. 6441 - 6450
For the past several decades, there has been little improvement in the morbidity and mortality associated with Acanthamoeba keratitis and Acanthamoeba...
PATHOGENESIS | VORICONAZOLE | ISETHIONATE | DEBRIDEMENT | KERATITIS | CHLORHEXIDINE | MICROBIOLOGY | PHARMACOLOGY & PHARMACY | PATIENT | GRANULOMATOUS AMEBIC ENCEPHALITIS | CASTELLANII | PROPAMIDINE | Polymyxin B - pharmacology | Biguanides - pharmacology | Acanthamoeba - metabolism | Cefazolin - pharmacology | Infectious Encephalitis - parasitology | Acanthamoeba - drug effects | Lipopeptides - pharmacology | Humans | Amphotericin B - pharmacology | Chlorhexidine - pharmacology | Acanthamoeba Keratitis - drug therapy | Thienamycins - pharmacology | Azoles - pharmacology | Infectious Encephalitis - drug therapy | Antiprotozoal Agents - pharmacology | Natamycin - pharmacology | Acanthamoeba - growth & development | Animals | Acanthamoeba Keratitis - parasitology | Antiprotozoal Agents - chemical synthesis | Echinocandins - pharmacology
PATHOGENESIS | VORICONAZOLE | ISETHIONATE | DEBRIDEMENT | KERATITIS | CHLORHEXIDINE | MICROBIOLOGY | PHARMACOLOGY & PHARMACY | PATIENT | GRANULOMATOUS AMEBIC ENCEPHALITIS | CASTELLANII | PROPAMIDINE | Polymyxin B - pharmacology | Biguanides - pharmacology | Acanthamoeba - metabolism | Cefazolin - pharmacology | Infectious Encephalitis - parasitology | Acanthamoeba - drug effects | Lipopeptides - pharmacology | Humans | Amphotericin B - pharmacology | Chlorhexidine - pharmacology | Acanthamoeba Keratitis - drug therapy | Thienamycins - pharmacology | Azoles - pharmacology | Infectious Encephalitis - drug therapy | Antiprotozoal Agents - pharmacology | Natamycin - pharmacology | Acanthamoeba - growth & development | Animals | Acanthamoeba Keratitis - parasitology | Antiprotozoal Agents - chemical synthesis | Echinocandins - pharmacology
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Loading RightsPlant Disease, ISSN 0191-2917, 09/2018, Volume 102, Issue 9, pp. 1687 - 1695
Anthracnose crown rot of strawberry, caused by Colletotrichum acutatum, is an important disease affecting California nursery and fruit production. Preplant dip...
Antifungal Agents - pharmacology | Colletotrichum - genetics | Colletotrichum - drug effects | Plant Diseases - microbiology | California | Pyrimidines - pharmacology | Plant Diseases - prevention & control | Fungicides, Industrial - pharmacology | Natamycin - pharmacology | Pyrroles - pharmacology | Fragaria - microbiology | Strobilurins - pharmacology | Fruit - microbiology | Dioxoles - pharmacology | Mutation | Drug Resistance, Fungal | Index Medicus
Antifungal Agents - pharmacology | Colletotrichum - genetics | Colletotrichum - drug effects | Plant Diseases - microbiology | California | Pyrimidines - pharmacology | Plant Diseases - prevention & control | Fungicides, Industrial - pharmacology | Natamycin - pharmacology | Pyrroles - pharmacology | Fragaria - microbiology | Strobilurins - pharmacology | Fruit - microbiology | Dioxoles - pharmacology | Mutation | Drug Resistance, Fungal | Index Medicus
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Loading RightsNeuroscience, ISSN 0306-4522, 2014, Volume 277, pp. 885 - 901
Highlights • Neonatal antibiotic treatment leads to an increase in visceral sensitivity in adulthood in rats. • Visceral hypersensitivity develops in the...
Neurology | microbiota | antibiotic | neonatal | visceral pain | behavior | brain–gut axis | Antibiotic | Microbiota | Neonatal | Visceral pain | Behavior | Brain-gut axis | COLONIC HYPERSENSITIVITY | ABDOMINAL-PAIN | INTESTINAL MICROBIOTA | MAST-CELLS | SPINAL-CORD | NEUROSCIENCES | MATERNAL SEPARATION | brain-gut axis | LACTOBACILLUS-REUTERI INGESTION | IRRITABLE-BOWEL-SYNDROME | PROBIOTIC BIFIDOBACTERIUM-INFANTIS | ESTROUS-CYCLE | Animals, Newborn | Microbiota - physiology | Visceral Pain - physiopathology | Microbiota - drug effects | Anxiety - physiopathology | Gastrointestinal Tract - microbiology | Behavior, Animal - physiology | Gastrointestinal Tract - drug effects | Male | Rats, Sprague-Dawley | Hyperalgesia - physiopathology | Natamycin - pharmacology | Animals | Vancomycin - pharmacology | Neomycin - pharmacology | Cognition - physiology | Female | Anti-Bacterial Agents - pharmacology | Bacitracin - pharmacology | Microbiota (Symbiotic organisms)
Neurology | microbiota | antibiotic | neonatal | visceral pain | behavior | brain–gut axis | Antibiotic | Microbiota | Neonatal | Visceral pain | Behavior | Brain-gut axis | COLONIC HYPERSENSITIVITY | ABDOMINAL-PAIN | INTESTINAL MICROBIOTA | MAST-CELLS | SPINAL-CORD | NEUROSCIENCES | MATERNAL SEPARATION | brain-gut axis | LACTOBACILLUS-REUTERI INGESTION | IRRITABLE-BOWEL-SYNDROME | PROBIOTIC BIFIDOBACTERIUM-INFANTIS | ESTROUS-CYCLE | Animals, Newborn | Microbiota - physiology | Visceral Pain - physiopathology | Microbiota - drug effects | Anxiety - physiopathology | Gastrointestinal Tract - microbiology | Behavior, Animal - physiology | Gastrointestinal Tract - drug effects | Male | Rats, Sprague-Dawley | Hyperalgesia - physiopathology | Natamycin - pharmacology | Animals | Vancomycin - pharmacology | Neomycin - pharmacology | Cognition - physiology | Female | Anti-Bacterial Agents - pharmacology | Bacitracin - pharmacology | Microbiota (Symbiotic organisms)
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Loading RightsMycoses, ISSN 0933-7407, 04/2017, Volume 60, Issue 4, pp. 230 - 233
In this study, we aimed to present the first molecular epidemiological data from Chennai, India, analyse keratitis cases that have been monitored in a...
trauma | Fusarium | RPB2 | keratomycosis | TEF1 | antifungal resistance | COMPLEX | SOUTH-INDIA | ANTIFUNGAL SUSCEPTIBILITY | DERMATOLOGY | MYCOTIC KERATITIS | NORTH-INDIA | MYCOLOGY | NATAMYCIN | Keratitis - microbiology | Lipopeptides - pharmacology | Humans | Middle Aged | Fusarium - drug effects | Male | Keratitis - epidemiology | Natamycin - therapeutic use | Antifungal Agents - therapeutic use | Microbial Sensitivity Tests | Fusariosis - drug therapy | Adult | Female | Genes, Fungal - genetics | Echinocandins - pharmacology | Fusarium - genetics | Antifungal Agents - pharmacology | Drug Resistance, Multiple, Fungal | Fusariosis - epidemiology | Amphotericin B - pharmacology | Hospitals, University | India - epidemiology | Treatment Outcome | Azoles - pharmacology | Natamycin - pharmacology | Administration, Topical | Fusarium - classification | Keratitis - drug therapy | Fusarium - isolation & purification | Fusariosis - microbiology | Natamycin | Keratitis | Multidrug resistance | Data processing | Drug resistance | DNA-directed RNA polymerase | Azoles | Amphotericin B | Translation elongation | Caspofungin | Minimum inhibitory concentration | Species | Elongation
trauma | Fusarium | RPB2 | keratomycosis | TEF1 | antifungal resistance | COMPLEX | SOUTH-INDIA | ANTIFUNGAL SUSCEPTIBILITY | DERMATOLOGY | MYCOTIC KERATITIS | NORTH-INDIA | MYCOLOGY | NATAMYCIN | Keratitis - microbiology | Lipopeptides - pharmacology | Humans | Middle Aged | Fusarium - drug effects | Male | Keratitis - epidemiology | Natamycin - therapeutic use | Antifungal Agents - therapeutic use | Microbial Sensitivity Tests | Fusariosis - drug therapy | Adult | Female | Genes, Fungal - genetics | Echinocandins - pharmacology | Fusarium - genetics | Antifungal Agents - pharmacology | Drug Resistance, Multiple, Fungal | Fusariosis - epidemiology | Amphotericin B - pharmacology | Hospitals, University | India - epidemiology | Treatment Outcome | Azoles - pharmacology | Natamycin - pharmacology | Administration, Topical | Fusarium - classification | Keratitis - drug therapy | Fusarium - isolation & purification | Fusariosis - microbiology | Natamycin | Keratitis | Multidrug resistance | Data processing | Drug resistance | DNA-directed RNA polymerase | Azoles | Amphotericin B | Translation elongation | Caspofungin | Minimum inhibitory concentration | Species | Elongation
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Carbohydrate Polymers, ISSN 0144-8617, 07/2015, Volume 125, pp. 288 - 300
The β-cyclodextrin-acrylamide (CDM-AM) copolymer was prepared from acrylamide and β-CD maleate (CDM) using K S O as initiator. The effects of the CDM-AM...
Isothermal adsorption | Natamycin | Aspergillus niger | Carbendazim | Solubility | Rheological properties | SYSTEM | POLYMER SCIENCE | BEHAVIOR | CHEMISTRY, ORGANIC | DRUG-RELEASE | EPICHLOROHYDRIN POLYMERS | DELIVERY | IN-VITRO | CHEMISTRY, APPLIED | HYDROXYPROPYL-BETA-CYCLODEXTRIN | Antifungal Agents - pharmacology | Polymers - chemical synthesis | Acrylamide - chemistry | Antifungal Agents - chemical synthesis | Natamycin - chemistry | Benzimidazoles - chemistry | Carbamates - chemistry | Natamycin - pharmacology | beta-Cyclodextrins - chemistry | Polymers - pharmacology | Benzimidazoles - pharmacology | Aspergillus niger - drug effects | Carbamates - pharmacology
Isothermal adsorption | Natamycin | Aspergillus niger | Carbendazim | Solubility | Rheological properties | SYSTEM | POLYMER SCIENCE | BEHAVIOR | CHEMISTRY, ORGANIC | DRUG-RELEASE | EPICHLOROHYDRIN POLYMERS | DELIVERY | IN-VITRO | CHEMISTRY, APPLIED | HYDROXYPROPYL-BETA-CYCLODEXTRIN | Antifungal Agents - pharmacology | Polymers - chemical synthesis | Acrylamide - chemistry | Antifungal Agents - chemical synthesis | Natamycin - chemistry | Benzimidazoles - chemistry | Carbamates - chemistry | Natamycin - pharmacology | beta-Cyclodextrins - chemistry | Polymers - pharmacology | Benzimidazoles - pharmacology | Aspergillus niger - drug effects | Carbamates - pharmacology
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Loading RightsInternational Journal of Food Microbiology, ISSN 0168-1605, 12/2016, Volume 238, pp. 15 - 22
Antimicrobial resistance is a relevant theme with respect to both antibacterial and antifungal compounds. In this study we address the possible development of...
Natamycin | Antimicrobial resistance | Food additive | Antifungal compounds | Polyene antibiotics | ANTIFUNGAL DRUG-RESISTANCE | ASPERGILLUS-FUMIGATUS | GERMINATING CONIDIA | FOOD SCIENCE & TECHNOLOGY | MICROBIOLOGY | AMPHOTERICIN-B | PLASMA-MEMBRANE | IN-VITRO | PENICILLIUM-DISCOLOR | ERGOSTEROL | AGENTS | POLYENE MACROLIDE ANTIBIOTICS | Antifungal Agents - pharmacology | Microbial Sensitivity Tests | Fungi - drug effects | Fungi - physiology | Amphotericin B - pharmacology | Food Preservatives - pharmacology | Fusarium - drug effects | Nystatin - pharmacology | Drug Resistance, Fungal | Natamycin - pharmacology | Drug resistance in microorganisms | Food preservatives | Food | Antiparasitic agents | Amphotericin B
Natamycin | Antimicrobial resistance | Food additive | Antifungal compounds | Polyene antibiotics | ANTIFUNGAL DRUG-RESISTANCE | ASPERGILLUS-FUMIGATUS | GERMINATING CONIDIA | FOOD SCIENCE & TECHNOLOGY | MICROBIOLOGY | AMPHOTERICIN-B | PLASMA-MEMBRANE | IN-VITRO | PENICILLIUM-DISCOLOR | ERGOSTEROL | AGENTS | POLYENE MACROLIDE ANTIBIOTICS | Antifungal Agents - pharmacology | Microbial Sensitivity Tests | Fungi - drug effects | Fungi - physiology | Amphotericin B - pharmacology | Food Preservatives - pharmacology | Fusarium - drug effects | Nystatin - pharmacology | Drug Resistance, Fungal | Natamycin - pharmacology | Drug resistance in microorganisms | Food preservatives | Food | Antiparasitic agents | Amphotericin B
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Loading RightsPloS one, 2011, Volume 6, Issue 5, p. e19588
The use of antimycotic drugs in fungal infections is based on the concept that they suppress fungal growth by a direct killing effect. However, amphotericin...
Potassium - metabolism | Monocytes - cytology | NLR Family, Pyrin Domain-Containing 3 Protein | Caspase 1 - metabolism | Immunoblotting | Monocytes - metabolism | Toll-Like Receptors | Inflammasomes - drug effects | Macrolides - pharmacology | Cytoskeletal Proteins - metabolism | Dendritic Cells - drug effects | Nystatin - pharmacology | Dendritic Cells - metabolism | Antifungal Agents - pharmacology | Interleukin-1beta - secretion | Phagocytosis - drug effects | Signal Transduction | Mice, Inbred C57BL | Amphotericin B - pharmacology | Macrophages - cytology | Immunity, Innate | Mice, Knockout | Natamycin - pharmacology | Monocytes - drug effects | Macrophages - metabolism | Animals | Apoptosis Regulatory Proteins | Carrier Proteins - metabolism | CARD Signaling Adaptor Proteins | Macrophages - drug effects | Dendritic Cells - cytology | Mice
Potassium - metabolism | Monocytes - cytology | NLR Family, Pyrin Domain-Containing 3 Protein | Caspase 1 - metabolism | Immunoblotting | Monocytes - metabolism | Toll-Like Receptors | Inflammasomes - drug effects | Macrolides - pharmacology | Cytoskeletal Proteins - metabolism | Dendritic Cells - drug effects | Nystatin - pharmacology | Dendritic Cells - metabolism | Antifungal Agents - pharmacology | Interleukin-1beta - secretion | Phagocytosis - drug effects | Signal Transduction | Mice, Inbred C57BL | Amphotericin B - pharmacology | Macrophages - cytology | Immunity, Innate | Mice, Knockout | Natamycin - pharmacology | Monocytes - drug effects | Macrophages - metabolism | Animals | Apoptosis Regulatory Proteins | Carrier Proteins - metabolism | CARD Signaling Adaptor Proteins | Macrophages - drug effects | Dendritic Cells - cytology | Mice
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Loading RightsPharmaceutical Research, ISSN 0724-8741, 6/2015, Volume 32, Issue 6, pp. 1920 - 1930
Enhancing the penetration ability of the antifungal drug natamycin, known to possess poor penetration ability through the corneal epithelium, by complexing...
Biochemistry, general | Biomedical Engineering | Biomedicine | Pharmacy | cell penetrating peptide | Medical Law | solubility | drug delivery | Pharmacology/Toxicology | antifungal activity | corneal tissue | EPIDEMIOLOGIC FEATURES | MANAGEMENT | CORNEAL ULCERS | TRANSDERMAL DELIVERY | SOUTH-INDIA | MICROBIAL KERATITIS | CHEMISTRY, MULTIDISCIPLINARY | CONTACT-LENS MATERIALS | TAT PEPTIDE | NANOPARTICLES | IN-VITRO UPTAKE | PHARMACOLOGY & PHARMACY | Keratitis - microbiology | Humans | Antifungal Agents - chemistry | Natamycin - chemistry | Drug Carriers | Eye Infections, Fungal - metabolism | Antifungal Agents - metabolism | Epithelium, Corneal - drug effects | Cell-Penetrating Peptides - chemistry | Antifungal Agents - pharmacology | Fungi - drug effects | Solubility | Technology, Pharmaceutical - methods | Chemistry, Pharmaceutical | Eye Infections, Fungal - microbiology | Natamycin - pharmacology | Particle Size | Natamycin - administration & dosage | Eye Infections, Fungal - drug therapy | Epithelium, Corneal - microbiology | Keratitis - metabolism | Epithelium, Corneal - metabolism | Natamycin - metabolism | HeLa Cells | Antifungal Agents - administration & dosage | Keratitis - drug therapy | Nanotechnology | Cell-Penetrating Peptides - metabolism | Drugs | Drug delivery systems | Care and treatment | Keratitis | Peptides | Analysis | Antifungal agents | Vehicles | Pharmacology | Fungal infections
Biochemistry, general | Biomedical Engineering | Biomedicine | Pharmacy | cell penetrating peptide | Medical Law | solubility | drug delivery | Pharmacology/Toxicology | antifungal activity | corneal tissue | EPIDEMIOLOGIC FEATURES | MANAGEMENT | CORNEAL ULCERS | TRANSDERMAL DELIVERY | SOUTH-INDIA | MICROBIAL KERATITIS | CHEMISTRY, MULTIDISCIPLINARY | CONTACT-LENS MATERIALS | TAT PEPTIDE | NANOPARTICLES | IN-VITRO UPTAKE | PHARMACOLOGY & PHARMACY | Keratitis - microbiology | Humans | Antifungal Agents - chemistry | Natamycin - chemistry | Drug Carriers | Eye Infections, Fungal - metabolism | Antifungal Agents - metabolism | Epithelium, Corneal - drug effects | Cell-Penetrating Peptides - chemistry | Antifungal Agents - pharmacology | Fungi - drug effects | Solubility | Technology, Pharmaceutical - methods | Chemistry, Pharmaceutical | Eye Infections, Fungal - microbiology | Natamycin - pharmacology | Particle Size | Natamycin - administration & dosage | Eye Infections, Fungal - drug therapy | Epithelium, Corneal - microbiology | Keratitis - metabolism | Epithelium, Corneal - metabolism | Natamycin - metabolism | HeLa Cells | Antifungal Agents - administration & dosage | Keratitis - drug therapy | Nanotechnology | Cell-Penetrating Peptides - metabolism | Drugs | Drug delivery systems | Care and treatment | Keratitis | Peptides | Analysis | Antifungal agents | Vehicles | Pharmacology | Fungal infections
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Loading RightsInvestigative Ophthalmology and Visual Science, ISSN 0146-0404, 07/2012, Volume 53, Issue 8, pp. 4450 - 4457
PURPOSE. Fusarium is a major cause of microbial keratitis, and its ability to form biofilms was suggested as a contributing factor in recent outbreaks. We...
CONTACT-LENS | SUSCEPTIBILITY | CANDIDA-ALBICANS BIOFILMS | OPHTHALMOLOGY | MICROBIAL KERATITIS | SINGAPORE | DIVERSITY | SPECTRUM | MODEL | FUNGAL KERATITIS | Corneal Ulcer - epidemiology | Virulence | Biofilms - growth & development | Fusarium - drug effects | Microbial Sensitivity Tests | Fusarium - physiology | Disease Outbreaks | Voriconazole | Corneal Ulcer - microbiology | Eye Infections, Fungal - epidemiology | Drug Resistance, Fungal | Disease Models, Animal | Antifungal Agents - pharmacology | Fusariosis - epidemiology | Mice, Inbred C57BL | Amphotericin B - pharmacology | Pyrimidines - pharmacology | Eye Infections, Fungal - microbiology | Natamycin - pharmacology | Triazoles - pharmacology | Microscopy, Confocal | Animals | Epithelium, Corneal - microbiology | Mice | Fusariosis - microbiology
CONTACT-LENS | SUSCEPTIBILITY | CANDIDA-ALBICANS BIOFILMS | OPHTHALMOLOGY | MICROBIAL KERATITIS | SINGAPORE | DIVERSITY | SPECTRUM | MODEL | FUNGAL KERATITIS | Corneal Ulcer - epidemiology | Virulence | Biofilms - growth & development | Fusarium - drug effects | Microbial Sensitivity Tests | Fusarium - physiology | Disease Outbreaks | Voriconazole | Corneal Ulcer - microbiology | Eye Infections, Fungal - epidemiology | Drug Resistance, Fungal | Disease Models, Animal | Antifungal Agents - pharmacology | Fusariosis - epidemiology | Mice, Inbred C57BL | Amphotericin B - pharmacology | Pyrimidines - pharmacology | Eye Infections, Fungal - microbiology | Natamycin - pharmacology | Triazoles - pharmacology | Microscopy, Confocal | Animals | Epithelium, Corneal - microbiology | Mice | Fusariosis - microbiology
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Loading RightsOrganic Letters, ISSN 1523-7060, 04/2006, Volume 8, Issue 9, pp. 1807 - 1809
New derivatives of Amphotericin B (AmB) were synthesized through a double reductive alkylation of the mycosamine. These derivatives of AmB displayed superior...
MEMBRANE | RESISTANCE | CHEMISTRY, ORGANIC | CONJUGATE | AGENTS | AMPHOTERICIN-B | DERIVATIVES | Polyenes - chemistry | Saccharomyces cerevisiae - genetics | Saccharomyces cerevisiae - drug effects | Antifungal Agents - chemical synthesis | Antifungal Agents - chemistry | Natamycin - chemistry | Alkylation | Candida albicans - genetics | Candida albicans - drug effects | Macrolides - chemistry | Macrolides - pharmacology | Nystatin - pharmacology | Molecular Structure | Nystatin - chemistry | Antifungal Agents - pharmacology | Polyenes - chemical synthesis | Hexosamines - chemistry | Polyenes - pharmacology | Amphotericin B - pharmacology | Natamycin - pharmacology | Drug Resistance, Microbial | Macrolides - chemical synthesis | Hexosamines - pharmacology | Amphotericin B - chemical synthesis | Amphotericin B - analogs & derivatives
MEMBRANE | RESISTANCE | CHEMISTRY, ORGANIC | CONJUGATE | AGENTS | AMPHOTERICIN-B | DERIVATIVES | Polyenes - chemistry | Saccharomyces cerevisiae - genetics | Saccharomyces cerevisiae - drug effects | Antifungal Agents - chemical synthesis | Antifungal Agents - chemistry | Natamycin - chemistry | Alkylation | Candida albicans - genetics | Candida albicans - drug effects | Macrolides - chemistry | Macrolides - pharmacology | Nystatin - pharmacology | Molecular Structure | Nystatin - chemistry | Antifungal Agents - pharmacology | Polyenes - chemical synthesis | Hexosamines - chemistry | Polyenes - pharmacology | Amphotericin B - pharmacology | Natamycin - pharmacology | Drug Resistance, Microbial | Macrolides - chemical synthesis | Hexosamines - pharmacology | Amphotericin B - chemical synthesis | Amphotericin B - analogs & derivatives
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Loading RightsJournal of Cell Science, ISSN 0021-9533, 10/2005, Volume 118, Issue 20, pp. 4833 - 4848
The process of regulated exocytosis is defined by the Ca2+- triggered fusion of two apposed membranes, enabling the release of vesicular contents. This fusion...
Secretory vesicles | Exocytosis | Vitamin E | Negative curvature | Polyene antibiotics | Sterol | SYNAPTIC VESICLES | sterol | vitamin E | negative curvature | CELL BIOLOGY | CALCIUM-TRIGGERED EXOCYTOSIS | INTRINSIC CURVATURE | secretory vesicles | BIOLOGICAL PROPERTIES | exocytosis | polyene antibiotics | SEA-URCHIN EGG | LIPID-COMPOSITION | STRUCTURAL TRANSITIONS | PHOSPHOLIPID-BILAYERS | Lysophosphatidylcholines - pharmacology | Calcium - pharmacology | Calcium - metabolism | Cholesterol - deficiency | Secretory Vesicles | Filipin - pharmacology | Sea Urchins | Cholesterol - metabolism | beta-Cyclodextrins - pharmacology | Natamycin - pharmacology | Dose-Response Relationship, Drug | Animals | Cholesterol Oxidase - metabolism | Kinetics | Membrane Fusion - physiology | Membrane Fusion - drug effects
Secretory vesicles | Exocytosis | Vitamin E | Negative curvature | Polyene antibiotics | Sterol | SYNAPTIC VESICLES | sterol | vitamin E | negative curvature | CELL BIOLOGY | CALCIUM-TRIGGERED EXOCYTOSIS | INTRINSIC CURVATURE | secretory vesicles | BIOLOGICAL PROPERTIES | exocytosis | polyene antibiotics | SEA-URCHIN EGG | LIPID-COMPOSITION | STRUCTURAL TRANSITIONS | PHOSPHOLIPID-BILAYERS | Lysophosphatidylcholines - pharmacology | Calcium - pharmacology | Calcium - metabolism | Cholesterol - deficiency | Secretory Vesicles | Filipin - pharmacology | Sea Urchins | Cholesterol - metabolism | beta-Cyclodextrins - pharmacology | Natamycin - pharmacology | Dose-Response Relationship, Drug | Animals | Cholesterol Oxidase - metabolism | Kinetics | Membrane Fusion - physiology | Membrane Fusion - drug effects
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Loading RightsFood Microbiology, ISSN 0740-0020, 12/2013, Volume 36, Issue 2, pp. 176 - 181
The present study evaluated the use of nisin, natamycin and/or their combination as antimicrobial treatments to improve the shelf-life of Galotyri cheese....
Shelf-life | Natamycin | Nisin | Antimicrobials | Galotyri | LISTERIA-MONOCYTOGENES | BIOTECHNOLOGY & APPLIED MICROBIOLOGY | FOOD SCIENCE & TECHNOLOGY | MICROBIOLOGY | ACID-CURD CHEESE | Antifungal Agents - pharmacology | Cheese - microbiology | Nisin - pharmacology | Fungi - drug effects | Food Preservation - methods | Food Storage | Food Preservatives - pharmacology | Fungi - growth & development | Natamycin - pharmacology | Microbiology | Cheese | Food
Shelf-life | Natamycin | Nisin | Antimicrobials | Galotyri | LISTERIA-MONOCYTOGENES | BIOTECHNOLOGY & APPLIED MICROBIOLOGY | FOOD SCIENCE & TECHNOLOGY | MICROBIOLOGY | ACID-CURD CHEESE | Antifungal Agents - pharmacology | Cheese - microbiology | Nisin - pharmacology | Fungi - drug effects | Food Preservation - methods | Food Storage | Food Preservatives - pharmacology | Fungi - growth & development | Natamycin - pharmacology | Microbiology | Cheese | Food
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Loading RightsInternational Journal of Antimicrobial Agents, ISSN 0924-8579, 2006, Volume 28, Issue 2, pp. 104 - 109
The growth inhibitory effects on of several natural tetraene macrolides and their derivatives were studied and compared with that of amphotericin B. All...
Polyene amides | Trypanosoma | Pimaricin | Trypanosoma cruzi | INFECTIOUS DISEASES | ASSAY | trypanosoma | CHAGAS-DISEASE | MICROBIOLOGY | AMPHOTERICIN-B | EXPRESSING BETA-GALACTOSIDASE | CHEMOTHERAPY | IN-VITRO | LOW TOXICITY | pimaricin | PHARMACOLOGY & PHARMACY | B METHYL-ESTER | polyene amides | DIASTATICUS VAR.-108 | DERIVATIVES | Monosaccharides - toxicity | Parasitic Sensitivity Tests | Macrolides - toxicity | Trypanocidal Agents - toxicity | Male | Natamycin - toxicity | Amphotericin B - toxicity | Polyenes - metabolism | Streptomyces - metabolism | Macrolides - pharmacology | Amphotericin B - chemistry | Cell Line | Trypanocidal Agents - metabolism | Streptomyces - genetics | Polyenes - pharmacology | Amphotericin B - pharmacology | Macrolides - metabolism | Natamycin - pharmacology | Animals | Trypanosoma cruzi - growth & development | Trypanocidal Agents - pharmacology | Fibroblasts - drug effects | Chagas Disease - drug therapy | Natamycin - metabolism | Trypanosoma cruzi - drug effects | Macrophages - drug effects | Monosaccharides - pharmacology | Mice | Polyenes - toxicity | Monosaccharides - metabolism | Amphotericin B | Amides | Antiparasitic agents
Polyene amides | Trypanosoma | Pimaricin | Trypanosoma cruzi | INFECTIOUS DISEASES | ASSAY | trypanosoma | CHAGAS-DISEASE | MICROBIOLOGY | AMPHOTERICIN-B | EXPRESSING BETA-GALACTOSIDASE | CHEMOTHERAPY | IN-VITRO | LOW TOXICITY | pimaricin | PHARMACOLOGY & PHARMACY | B METHYL-ESTER | polyene amides | DIASTATICUS VAR.-108 | DERIVATIVES | Monosaccharides - toxicity | Parasitic Sensitivity Tests | Macrolides - toxicity | Trypanocidal Agents - toxicity | Male | Natamycin - toxicity | Amphotericin B - toxicity | Polyenes - metabolism | Streptomyces - metabolism | Macrolides - pharmacology | Amphotericin B - chemistry | Cell Line | Trypanocidal Agents - metabolism | Streptomyces - genetics | Polyenes - pharmacology | Amphotericin B - pharmacology | Macrolides - metabolism | Natamycin - pharmacology | Animals | Trypanosoma cruzi - growth & development | Trypanocidal Agents - pharmacology | Fibroblasts - drug effects | Chagas Disease - drug therapy | Natamycin - metabolism | Trypanosoma cruzi - drug effects | Macrophages - drug effects | Monosaccharides - pharmacology | Mice | Polyenes - toxicity | Monosaccharides - metabolism | Amphotericin B | Amides | Antiparasitic agents
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Loading RightsAntimicrobial Agents and Chemotherapy, ISSN 0066-4804, 06/2010, Volume 54, Issue 6, pp. 2618 - 2625
Classifications Services AAC Citing Articles Google Scholar PubMed Related Content Social Bookmarking CiteULike Delicious Digg Facebook Google+ Mendeley Reddit...
ACHOLEPLASMA-LAIDLAWII CELLS | MEMBRANE-FUSION | MULTIPLE FUNCTIONS | LECITHIN LIPOSOMES | COMPLEX-FORMATION | GERMINATING CONIDIA | PENICILLIUM-DISCOLOR | ANTIBIOTIC-STEROL INTERACTIONS | MICROBIOLOGY | PHARMACOLOGY & PHARMACY | PLASMA-MEMBRANE | SACCHAROMYCES-CEREVISIAE | Antifungal Agents - pharmacology | Permeability - drug effects | DNA, Fungal - genetics | Ergosterol - metabolism | Oxidoreductases - metabolism | Oxidoreductases - genetics | Saccharomyces cerevisiae - genetics | Molecular Sequence Data | Saccharomyces cerevisiae - drug effects | DNA Primers - genetics | Filipin - pharmacology | Saccharomyces cerevisiae Proteins - genetics | Vacuoles - drug effects | Natamycin - pharmacology | Saccharomyces cerevisiae - metabolism | Base Sequence | Gene Deletion | Saccharomyces cerevisiae Proteins - metabolism | Vacuoles - metabolism | Genes, Fungal | Nystatin - pharmacology | Membrane Fusion - drug effects | Mechanisms of Action | Physiological Effects
ACHOLEPLASMA-LAIDLAWII CELLS | MEMBRANE-FUSION | MULTIPLE FUNCTIONS | LECITHIN LIPOSOMES | COMPLEX-FORMATION | GERMINATING CONIDIA | PENICILLIUM-DISCOLOR | ANTIBIOTIC-STEROL INTERACTIONS | MICROBIOLOGY | PHARMACOLOGY & PHARMACY | PLASMA-MEMBRANE | SACCHAROMYCES-CEREVISIAE | Antifungal Agents - pharmacology | Permeability - drug effects | DNA, Fungal - genetics | Ergosterol - metabolism | Oxidoreductases - metabolism | Oxidoreductases - genetics | Saccharomyces cerevisiae - genetics | Molecular Sequence Data | Saccharomyces cerevisiae - drug effects | DNA Primers - genetics | Filipin - pharmacology | Saccharomyces cerevisiae Proteins - genetics | Vacuoles - drug effects | Natamycin - pharmacology | Saccharomyces cerevisiae - metabolism | Base Sequence | Gene Deletion | Saccharomyces cerevisiae Proteins - metabolism | Vacuoles - metabolism | Genes, Fungal | Nystatin - pharmacology | Membrane Fusion - drug effects | Mechanisms of Action | Physiological Effects
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Loading RightsJournal of Biological Chemistry, ISSN 0021-9258, 03/2008, Volume 283, Issue 10, pp. 6393 - 6401
Natamycin is a polyene antibiotic that is commonly used as an antifungal agent because of its broad spectrum of activity and the lack of development of...
International (English) | Antifungal Agents - pharmacology | Ergosterol - genetics | Filipin - chemistry | Ergosterol - chemistry | Ergosterol - metabolism | Saccharomyces cerevisiae - genetics | Antifungal Agents - chemistry | Cell Membrane - genetics | Filipin - pharmacology | Natamycin - chemistry | Cell Membrane Permeability - genetics | Saccharomyces cerevisiae - chemistry | Natamycin - pharmacology | Cell Membrane - chemistry | Models, Biological | Cell Membrane Permeability - drug effects | Calorimetry | Nystatin - pharmacology | Cell Membrane - metabolism | Mutation | Nystatin - chemistry | Saccharomyces cerevisiae - growth & development | ACHOLEPLASMA-LAIDLAWII CELLS | YEAST | LECITHIN LIPOSOMES | CANDIDA-ALBICANS | OXIDATIVE DAMAGE | BIOCHEMISTRY & MOLECULAR BIOLOGY | ANTIBIOTIC-STEROL INTERACTIONS | INTRACELLULAR PH | AMPHOTERICIN-B | SACCHAROMYCES-CEREVISIAE | POLYENE MACROLIDE ANTIBIOTICS
International (English) | Antifungal Agents - pharmacology | Ergosterol - genetics | Filipin - chemistry | Ergosterol - chemistry | Ergosterol - metabolism | Saccharomyces cerevisiae - genetics | Antifungal Agents - chemistry | Cell Membrane - genetics | Filipin - pharmacology | Natamycin - chemistry | Cell Membrane Permeability - genetics | Saccharomyces cerevisiae - chemistry | Natamycin - pharmacology | Cell Membrane - chemistry | Models, Biological | Cell Membrane Permeability - drug effects | Calorimetry | Nystatin - pharmacology | Cell Membrane - metabolism | Mutation | Nystatin - chemistry | Saccharomyces cerevisiae - growth & development | ACHOLEPLASMA-LAIDLAWII CELLS | YEAST | LECITHIN LIPOSOMES | CANDIDA-ALBICANS | OXIDATIVE DAMAGE | BIOCHEMISTRY & MOLECULAR BIOLOGY | ANTIBIOTIC-STEROL INTERACTIONS | INTRACELLULAR PH | AMPHOTERICIN-B | SACCHAROMYCES-CEREVISIAE | POLYENE MACROLIDE ANTIBIOTICS
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Loading RightsJournal of Dairy Science, ISSN 0022-0302, 11/2012, Volume 95, Issue 11, pp. 6282 - 6292
The objective of this work was to evaluate the effectiveness of antimicrobial edible coatings to wrap cheeses, throughout 60 d of storage, as an alternative to...
cheese shelf life | whey protein isolate | antimicrobial compound | edible coating | Antimicrobial compound | Edible coating | Cheese shelf life | Whey protein isolate | AGRICULTURE, DAIRY & ANIMAL SCIENCE | FILMS | FOOD SCIENCE & TECHNOLOGY | NATAMYCIN | Cheese - analysis | Milk Proteins - metabolism | Food Quality | Fats - analysis | Anti-Infective Agents - pharmacology | Food Preservation - methods | Cheese - standards | Water - analysis | Spectroscopy, Fourier Transform Infrared | Natamycin - pharmacology | Cheese - microbiology | Oligosaccharides - pharmacology | Salts - analysis | Whey Proteins | Food Preservation - standards | Lactic Acid - pharmacology | Hydrogen-Ion Concentration
cheese shelf life | whey protein isolate | antimicrobial compound | edible coating | Antimicrobial compound | Edible coating | Cheese shelf life | Whey protein isolate | AGRICULTURE, DAIRY & ANIMAL SCIENCE | FILMS | FOOD SCIENCE & TECHNOLOGY | NATAMYCIN | Cheese - analysis | Milk Proteins - metabolism | Food Quality | Fats - analysis | Anti-Infective Agents - pharmacology | Food Preservation - methods | Cheese - standards | Water - analysis | Spectroscopy, Fourier Transform Infrared | Natamycin - pharmacology | Cheese - microbiology | Oligosaccharides - pharmacology | Salts - analysis | Whey Proteins | Food Preservation - standards | Lactic Acid - pharmacology | Hydrogen-Ion Concentration
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Loading RightsCornea, ISSN 0277-3740, 05/2015, Volume 34, Issue 5, pp. 576 - 579
PURPOSE:To compare the in vitro activity of topical amphotericin B (AMB), natamycin, voriconazole, and fluconazole against human corneal isolates of Candida...
Candida albicans | fluconazole | voriconazole | non-albicans Candida | natamycin | amphotericin B | infectious keratitis | DIAGNOSIS | INFECTIONS | MANAGEMENT | HUMAN AQUEOUS-HUMOR | PENETRATION | FUNGAL KERATITIS | OPHTHALMOLOGY | TOPICAL AMPHOTERICIN-B | EPIDEMIOLOGY | Antifungal Agents - pharmacology | Fluconazole - pharmacology | Voriconazole - pharmacology | Humans | Amphotericin B - pharmacology | Candidiasis - microbiology | Candida - isolation & purification | Eye Infections, Fungal - microbiology | Natamycin - pharmacology | Microbial Sensitivity Tests | Candida albicans - drug effects | Candida albicans - isolation & purification | Corneal Ulcer - microbiology | Candida - drug effects
Candida albicans | fluconazole | voriconazole | non-albicans Candida | natamycin | amphotericin B | infectious keratitis | DIAGNOSIS | INFECTIONS | MANAGEMENT | HUMAN AQUEOUS-HUMOR | PENETRATION | FUNGAL KERATITIS | OPHTHALMOLOGY | TOPICAL AMPHOTERICIN-B | EPIDEMIOLOGY | Antifungal Agents - pharmacology | Fluconazole - pharmacology | Voriconazole - pharmacology | Humans | Amphotericin B - pharmacology | Candidiasis - microbiology | Candida - isolation & purification | Eye Infections, Fungal - microbiology | Natamycin - pharmacology | Microbial Sensitivity Tests | Candida albicans - drug effects | Candida albicans - isolation & purification | Corneal Ulcer - microbiology | Candida - drug effects
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