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Publication DateInternational Journal of Pharmaceutics, ISSN 0378-5173, 2008, Volume 348, Issue 1, pp. 137 - 145
The aim of this study was to investigate the cellular uptake of solid lipid nanoparticles (SLN) and cytotoxicity of its paclitaxel delivery system. The...
Fluorescein isothiocyanate | Cytotoxicity | Cellular uptake | Polyethylene glycol monostearate | Solid lipid nanoparticles | Folic acid | SYSTEM | solid lipid nanoparticles | DOXORUBICIN | cellular uptake | DELIVERY | polyethylene glycol monostearate | LINE | PHARMACOLOGY & PHARMACY | ANTICANCER DRUGS | PARTICLE-SIZE | folic acid | fluorescein isothiocyanate | EFFICIENCY | cytotoxicity | Amines - chemistry | Paclitaxel - pharmacology | Nanoparticles - chemistry | Humans | Polyethylene Glycols - chemistry | Paclitaxel - pharmacokinetics | Triglycerides - chemistry | Paclitaxel - chemistry | Lipids - chemistry | Fluorescein-5-isothiocyanate - chemistry | Surface Properties | Inhibitory Concentration 50 | Antineoplastic Agents, Phytogenic - pharmacokinetics | Stearates - chemistry | Cell Survival - drug effects | Glycerides - chemistry | Fatty Acids - chemistry | Folic Acid - chemistry | Antineoplastic Agents, Phytogenic - chemistry | Static Electricity | Stearic Acids - chemistry | Particle Size | Cell Line, Tumor | Cell Proliferation - drug effects | Antineoplastic Agents, Phytogenic - pharmacology | Glycerin | Nanoparticles | Care and treatment | Polyethylene glycol | Fluorescein | Fluorescence | Glycerol | Nanotechnology | Cancer
Fluorescein isothiocyanate | Cytotoxicity | Cellular uptake | Polyethylene glycol monostearate | Solid lipid nanoparticles | Folic acid | SYSTEM | solid lipid nanoparticles | DOXORUBICIN | cellular uptake | DELIVERY | polyethylene glycol monostearate | LINE | PHARMACOLOGY & PHARMACY | ANTICANCER DRUGS | PARTICLE-SIZE | folic acid | fluorescein isothiocyanate | EFFICIENCY | cytotoxicity | Amines - chemistry | Paclitaxel - pharmacology | Nanoparticles - chemistry | Humans | Polyethylene Glycols - chemistry | Paclitaxel - pharmacokinetics | Triglycerides - chemistry | Paclitaxel - chemistry | Lipids - chemistry | Fluorescein-5-isothiocyanate - chemistry | Surface Properties | Inhibitory Concentration 50 | Antineoplastic Agents, Phytogenic - pharmacokinetics | Stearates - chemistry | Cell Survival - drug effects | Glycerides - chemistry | Fatty Acids - chemistry | Folic Acid - chemistry | Antineoplastic Agents, Phytogenic - chemistry | Static Electricity | Stearic Acids - chemistry | Particle Size | Cell Line, Tumor | Cell Proliferation - drug effects | Antineoplastic Agents, Phytogenic - pharmacology | Glycerin | Nanoparticles | Care and treatment | Polyethylene glycol | Fluorescein | Fluorescence | Glycerol | Nanotechnology | Cancer
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Loading RightsACS Nano, ISSN 1936-0851, 04/2015, Volume 9, Issue 4, pp. 3540 - 3557
Recently, a commercial albumin-bound paclitaxel (PTX) nanocarrier (Abraxane) was approved as the first new drug for pancreatic ductal adenocarcinoma in almost...
SUPPORTED MEMBRANES | paclitaxel | PHYSICAL-PROPERTIES | synergy | mesoporous silica nanoparticle | VIVO | NAB-PACLITAXEL | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | MODEL | CYTIDINE DEAMINASE | CHEMISTRY, MULTIDISCIPLINARY | OVERCOME DRUG-RESISTANCE | co-delivery | pancreatic cancer | IN-VITRO | ratiometric | gemcitabine | BILAYERS PROTOCELLS | NANOTECHNOLOGY | Albumins - chemistry | Deoxycytidine - chemistry | Paclitaxel - pharmacology | Pancreatic Neoplasms - metabolism | Nanoparticles - chemistry | Humans | Deoxycytidine - pharmacology | Antineoplastic Agents - therapeutic use | Drug Carriers - chemistry | Pancreatic Neoplasms - drug therapy | Albumins - therapeutic use | Paclitaxel - chemistry | Deoxycytidine - therapeutic use | Female | Antineoplastic Agents - pharmacology | Gene Expression Regulation, Neoplastic - drug effects | Pancreatic Neoplasms - pathology | Silicon Dioxide - chemistry | Antineoplastic Agents - chemistry | Paclitaxel - therapeutic use | Drug Synergism | Albumins - pharmacology | Animals | Cell Transformation, Neoplastic | Cytidine Deaminase - metabolism | Cell Line, Tumor | Mice | Lipid Bilayers - chemistry | Porosity | Deoxycytidine - analogs & derivatives | Index Medicus | Drugs | Effectiveness | Metabolites | Biocompatibility | Lipids | Nanostructure | Tumors | Cancer
SUPPORTED MEMBRANES | paclitaxel | PHYSICAL-PROPERTIES | synergy | mesoporous silica nanoparticle | VIVO | NAB-PACLITAXEL | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | MODEL | CYTIDINE DEAMINASE | CHEMISTRY, MULTIDISCIPLINARY | OVERCOME DRUG-RESISTANCE | co-delivery | pancreatic cancer | IN-VITRO | ratiometric | gemcitabine | BILAYERS PROTOCELLS | NANOTECHNOLOGY | Albumins - chemistry | Deoxycytidine - chemistry | Paclitaxel - pharmacology | Pancreatic Neoplasms - metabolism | Nanoparticles - chemistry | Humans | Deoxycytidine - pharmacology | Antineoplastic Agents - therapeutic use | Drug Carriers - chemistry | Pancreatic Neoplasms - drug therapy | Albumins - therapeutic use | Paclitaxel - chemistry | Deoxycytidine - therapeutic use | Female | Antineoplastic Agents - pharmacology | Gene Expression Regulation, Neoplastic - drug effects | Pancreatic Neoplasms - pathology | Silicon Dioxide - chemistry | Antineoplastic Agents - chemistry | Paclitaxel - therapeutic use | Drug Synergism | Albumins - pharmacology | Animals | Cell Transformation, Neoplastic | Cytidine Deaminase - metabolism | Cell Line, Tumor | Mice | Lipid Bilayers - chemistry | Porosity | Deoxycytidine - analogs & derivatives | Index Medicus | Drugs | Effectiveness | Metabolites | Biocompatibility | Lipids | Nanostructure | Tumors | Cancer
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Loading RightsACS Nano, ISSN 1936-0851, 02/2015, Volume 9, Issue 2, pp. 1367 - 1378
Effective therapeutics against triple negative breast cancer (TNBC), which has no standard-of-care therapy, needs to be developed urgently. Here we...
thermoresponsive | triple negative breast cancer | combination antitumor therapy | INDOCYANINE GREEN | CELLS | SURVIVIN | MATERIALS SCIENCE, MULTIDISCIPLINARY | DOXORUBICIN | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | MICELLES | RELEASE | CHEMISTRY, MULTIDISCIPLINARY | PACLITAXEL | NANOPARTICLES | CO-DELIVERY | INHIBITION | RNA, Small Interfering - genetics | Paclitaxel - pharmacology | Nanoparticles - chemistry | Inhibitor of Apoptosis Proteins - genetics | Humans | Polyethylene Glycols - chemistry | Antineoplastic Agents - therapeutic use | Methacrylates - chemistry | Triple Negative Breast Neoplasms - drug therapy | Drug Carriers - chemistry | RNA, Small Interfering - chemistry | Indocyanine Green - chemistry | Inhibitor of Apoptosis Proteins - deficiency | Paclitaxel - chemistry | Endocytosis | Triple Negative Breast Neoplasms - pathology | Female | Antineoplastic Agents - pharmacology | Drug Carriers - metabolism | Lactic Acid - chemistry | Antineoplastic Agents - chemistry | Paclitaxel - therapeutic use | Animals | Triple Negative Breast Neoplasms - genetics | Intracellular Space - metabolism | Nanomedicine - methods | Polyglycolic Acid - chemistry | Cell Line, Tumor | Drug Carriers - pharmacokinetics | Mice | Mice, Inbred BALB C
thermoresponsive | triple negative breast cancer | combination antitumor therapy | INDOCYANINE GREEN | CELLS | SURVIVIN | MATERIALS SCIENCE, MULTIDISCIPLINARY | DOXORUBICIN | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | MICELLES | RELEASE | CHEMISTRY, MULTIDISCIPLINARY | PACLITAXEL | NANOPARTICLES | CO-DELIVERY | INHIBITION | RNA, Small Interfering - genetics | Paclitaxel - pharmacology | Nanoparticles - chemistry | Inhibitor of Apoptosis Proteins - genetics | Humans | Polyethylene Glycols - chemistry | Antineoplastic Agents - therapeutic use | Methacrylates - chemistry | Triple Negative Breast Neoplasms - drug therapy | Drug Carriers - chemistry | RNA, Small Interfering - chemistry | Indocyanine Green - chemistry | Inhibitor of Apoptosis Proteins - deficiency | Paclitaxel - chemistry | Endocytosis | Triple Negative Breast Neoplasms - pathology | Female | Antineoplastic Agents - pharmacology | Drug Carriers - metabolism | Lactic Acid - chemistry | Antineoplastic Agents - chemistry | Paclitaxel - therapeutic use | Animals | Triple Negative Breast Neoplasms - genetics | Intracellular Space - metabolism | Nanomedicine - methods | Polyglycolic Acid - chemistry | Cell Line, Tumor | Drug Carriers - pharmacokinetics | Mice | Mice, Inbred BALB C
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Loading RightsJournal of Controlled Release, ISSN 0168-3659, 11/2015, Volume 217, pp. 243 - 255
Macrophages are innate immune cells with great phenotypic plasticity, which allows them to regulate an array of physiological processes such as host defense,...
Obesity | Theranostic nanoparticles | Intravital imaging | Inflammation | Magnetic resonance imaging | Atherosclerosis | CORE-SHELL NANOPARTICLES | ATHEROSCLEROTIC PLAQUES | CONTRAST AGENTS | DRUG-DELIVERY | PHOSPHOLIPASE A | CHEMISTRY, MULTIDISCIPLINARY | ENDOTHELIAL-CELLS | INTRACELLULAR DELIVERY | PPAR-GAMMA | PHARMACOLOGY & PHARMACY | EXPRESSION | ADIPOSE-TISSUE | Nanoparticles - chemistry | Obesity - immunology | Polyethylene Glycols - chemistry | Thiazolidinediones - chemistry | Thiazolidinediones - administration & dosage | Tamoxifen - administration & dosage | Polystyrenes - chemistry | Cholesterol - chemistry | Paclitaxel - chemistry | Fluorescein-5-isothiocyanate - chemistry | Tamoxifen - chemistry | Anti-Inflammatory Agents - administration & dosage | Paclitaxel - administration & dosage | Cytokines - genetics | Macrophages - immunology | Phospholipases A2 - chemistry | Cell Line | Cholesterol - analogs & derivatives | Atherosclerosis - immunology | Mice, Inbred C57BL | Phosphatidylserines - chemistry | Gadolinium - chemistry | Mice, Knockout | Animals | Anti-Inflammatory Agents - chemistry | Apolipoproteins E - genetics | Macrophages - drug effects | Nanoparticles - administration & dosage | Phosphatidylethanolamines - chemistry | Phagocytosis | Nanoparticles | Drugs | Drug delivery systems | Physiological aspects | Lipids | Macrophages | Vehicles | Fluorescein | Cardiovascular agents
Obesity | Theranostic nanoparticles | Intravital imaging | Inflammation | Magnetic resonance imaging | Atherosclerosis | CORE-SHELL NANOPARTICLES | ATHEROSCLEROTIC PLAQUES | CONTRAST AGENTS | DRUG-DELIVERY | PHOSPHOLIPASE A | CHEMISTRY, MULTIDISCIPLINARY | ENDOTHELIAL-CELLS | INTRACELLULAR DELIVERY | PPAR-GAMMA | PHARMACOLOGY & PHARMACY | EXPRESSION | ADIPOSE-TISSUE | Nanoparticles - chemistry | Obesity - immunology | Polyethylene Glycols - chemistry | Thiazolidinediones - chemistry | Thiazolidinediones - administration & dosage | Tamoxifen - administration & dosage | Polystyrenes - chemistry | Cholesterol - chemistry | Paclitaxel - chemistry | Fluorescein-5-isothiocyanate - chemistry | Tamoxifen - chemistry | Anti-Inflammatory Agents - administration & dosage | Paclitaxel - administration & dosage | Cytokines - genetics | Macrophages - immunology | Phospholipases A2 - chemistry | Cell Line | Cholesterol - analogs & derivatives | Atherosclerosis - immunology | Mice, Inbred C57BL | Phosphatidylserines - chemistry | Gadolinium - chemistry | Mice, Knockout | Animals | Anti-Inflammatory Agents - chemistry | Apolipoproteins E - genetics | Macrophages - drug effects | Nanoparticles - administration & dosage | Phosphatidylethanolamines - chemistry | Phagocytosis | Nanoparticles | Drugs | Drug delivery systems | Physiological aspects | Lipids | Macrophages | Vehicles | Fluorescein | Cardiovascular agents
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Loading RightsChemistry – A European Journal, ISSN 0947-6539, 05/2015, Volume 21, Issue 22, pp. 8182 - 8187
Iminoboronates have been utilized to successfully install azide and alkyne bioorthogonal functions on proteins, which may then be further reacted with their...
cycloaddition | protein modifications | drug design | conjugation | boronic acids | FOLATE RECEPTOR | BONDS | CHEMISTRY | SYSTEMS | CANCER | CHEMISTRY, MULTIDISCIPLINARY | DELIVERY | Cell Line | Paclitaxel - pharmacology | Muramidase - chemistry | Humans | Folic Acid - chemistry | Models, Molecular | Antineoplastic Agents, Phytogenic - chemistry | Polyethylene Glycols - chemistry | Alkynes - chemistry | Boronic Acids - chemistry | Azides - chemistry | Neoplasms - drug therapy | Paclitaxel - chemistry | Animals | Insulin - chemistry | Imines - chemistry | Cell Line, Tumor | Proteins - chemistry | Antineoplastic Agents, Phytogenic - pharmacology | Lysine - chemistry | Proteins | Drugstores | Lysine | Polyols | Pharmacy | Fructose | Acids | Polyethylene glycol | Drugs | Conjugates | Strategy | Folic acid
cycloaddition | protein modifications | drug design | conjugation | boronic acids | FOLATE RECEPTOR | BONDS | CHEMISTRY | SYSTEMS | CANCER | CHEMISTRY, MULTIDISCIPLINARY | DELIVERY | Cell Line | Paclitaxel - pharmacology | Muramidase - chemistry | Humans | Folic Acid - chemistry | Models, Molecular | Antineoplastic Agents, Phytogenic - chemistry | Polyethylene Glycols - chemistry | Alkynes - chemistry | Boronic Acids - chemistry | Azides - chemistry | Neoplasms - drug therapy | Paclitaxel - chemistry | Animals | Insulin - chemistry | Imines - chemistry | Cell Line, Tumor | Proteins - chemistry | Antineoplastic Agents, Phytogenic - pharmacology | Lysine - chemistry | Proteins | Drugstores | Lysine | Polyols | Pharmacy | Fructose | Acids | Polyethylene glycol | Drugs | Conjugates | Strategy | Folic acid
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Loading RightsCarbohydrate Polymers, ISSN 0144-8617, 06/2015, Volume 123, pp. 313 - 323
Multiple-drug combination therapy is becoming more common in the treatment of advanced cancers because this approach can decrease side effects and delay or...
Tanespimycin | Combined therapy | Poly(lactic-co-glycolic acid) | Docetaxel | Synergic effect | POLYMER SCIENCE | SELF-ASSEMBLED NANOPARTICLES | CHEMISTRY, ORGANIC | ANTICANCER DRUG | MICELLES | FORMULATION | CANCER | PACLITAXEL | PHASE-II TRIAL | CO-DELIVERY | 17-ALLYLAMINO-17-DEMETHOXYGELDANAMYCIN | CHEMISTRY, APPLIED | PLGA NANOPARTICLES | Taxoids - toxicity | Benzoquinones - administration & dosage | Nanoparticles - chemistry | Humans | Body Weight - drug effects | Transplantation, Heterologous | Benzoquinones - chemistry | Antineoplastic Agents - administration & dosage | Drug Carriers - chemistry | Antineoplastic Agents - toxicity | Lactams, Macrocyclic - chemistry | Water - chemistry | Benzoquinones - toxicity | Lactams, Macrocyclic - administration & dosage | Oils - chemistry | Taxoids - chemistry | Cell Survival - drug effects | Lactic Acid - chemistry | Emulsions - chemistry | Hyaluronic Acid - chemistry | Antineoplastic Agents - chemistry | Lactams, Macrocyclic - toxicity | Particle Size | Microscopy, Confocal | Taxoids - administration & dosage | Animals | Carcinoma, Squamous Cell - drug therapy | Mice, Nude | Polyglycolic Acid - chemistry | Cell Line, Tumor | Mice | Antimitotic agents | Drugstores | Antineoplastic agents | Hyaluronic acid | Pharmacy
Tanespimycin | Combined therapy | Poly(lactic-co-glycolic acid) | Docetaxel | Synergic effect | POLYMER SCIENCE | SELF-ASSEMBLED NANOPARTICLES | CHEMISTRY, ORGANIC | ANTICANCER DRUG | MICELLES | FORMULATION | CANCER | PACLITAXEL | PHASE-II TRIAL | CO-DELIVERY | 17-ALLYLAMINO-17-DEMETHOXYGELDANAMYCIN | CHEMISTRY, APPLIED | PLGA NANOPARTICLES | Taxoids - toxicity | Benzoquinones - administration & dosage | Nanoparticles - chemistry | Humans | Body Weight - drug effects | Transplantation, Heterologous | Benzoquinones - chemistry | Antineoplastic Agents - administration & dosage | Drug Carriers - chemistry | Antineoplastic Agents - toxicity | Lactams, Macrocyclic - chemistry | Water - chemistry | Benzoquinones - toxicity | Lactams, Macrocyclic - administration & dosage | Oils - chemistry | Taxoids - chemistry | Cell Survival - drug effects | Lactic Acid - chemistry | Emulsions - chemistry | Hyaluronic Acid - chemistry | Antineoplastic Agents - chemistry | Lactams, Macrocyclic - toxicity | Particle Size | Microscopy, Confocal | Taxoids - administration & dosage | Animals | Carcinoma, Squamous Cell - drug therapy | Mice, Nude | Polyglycolic Acid - chemistry | Cell Line, Tumor | Mice | Antimitotic agents | Drugstores | Antineoplastic agents | Hyaluronic acid | Pharmacy
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Loading RightsInternational Journal of Pharmaceutics, ISSN 0378-5173, 06/2016, Volume 506, Issue 1-2, pp. 93 - 101
The purpose of this study was to develop HM30181 mesylate salt (HM30181M)-loaded microcapsules as a novel P-glycoprotein inhibitor for enhancing the oral...
HM30181 mesylate salt | Bioavailability | Microcapsule | Paclitaxel | Solubility | P-glycoprotein inhibitor | CANCER-CELLS | DRUG-DELIVERY SYSTEM | SOLID DISPERSION | RATS | DOCETAXEL | NANOPARTICLES | ENHANCED STABILITY | PHYSICOCHEMICAL CHARACTERIZATION | BETA-CYCLODEXTRIN | PHARMACOLOGY & PHARMACY | Paclitaxel - metabolism | Paclitaxel - pharmacology | Capsules - pharmacology | Lactose - analogs & derivatives | Capsules - metabolism | Methylcellulose - analogs & derivatives | Biological Availability | Male | Drug Carriers - chemistry | Benzopyrans - chemistry | Isoquinolines - chemistry | Paclitaxel - chemistry | Tetrazoles - chemistry | ATP Binding Cassette Transporter, Sub-Family B - antagonists & inhibitors | Powders - pharmacology | Administration, Oral | Silicon Dioxide - chemistry | Phosphoric Acids - chemistry | Rats | Capsules - chemistry | Mesylates - chemistry | Rats, Sprague-Dawley | Powders - chemistry | Methylcellulose - chemistry | Animals | Lactose - chemistry | Polymers - chemistry | Antimitotic agents | Drugstores | Antineoplastic agents | Pharmacy | Phosphates | Phosphoric acid | Powders | Polymers | Silica
HM30181 mesylate salt | Bioavailability | Microcapsule | Paclitaxel | Solubility | P-glycoprotein inhibitor | CANCER-CELLS | DRUG-DELIVERY SYSTEM | SOLID DISPERSION | RATS | DOCETAXEL | NANOPARTICLES | ENHANCED STABILITY | PHYSICOCHEMICAL CHARACTERIZATION | BETA-CYCLODEXTRIN | PHARMACOLOGY & PHARMACY | Paclitaxel - metabolism | Paclitaxel - pharmacology | Capsules - pharmacology | Lactose - analogs & derivatives | Capsules - metabolism | Methylcellulose - analogs & derivatives | Biological Availability | Male | Drug Carriers - chemistry | Benzopyrans - chemistry | Isoquinolines - chemistry | Paclitaxel - chemistry | Tetrazoles - chemistry | ATP Binding Cassette Transporter, Sub-Family B - antagonists & inhibitors | Powders - pharmacology | Administration, Oral | Silicon Dioxide - chemistry | Phosphoric Acids - chemistry | Rats | Capsules - chemistry | Mesylates - chemistry | Rats, Sprague-Dawley | Powders - chemistry | Methylcellulose - chemistry | Animals | Lactose - chemistry | Polymers - chemistry | Antimitotic agents | Drugstores | Antineoplastic agents | Pharmacy | Phosphates | Phosphoric acid | Powders | Polymers | Silica
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Loading RightsThe Journal of Organic Chemistry, ISSN 0022-3263, 07/2013, Volume 78, Issue 13, pp. 6358 - 6383
Over the last three decades, my engagement in “fluorine chemistry” has evolved substantially because of the multidisciplinary nature of the research programs....
MEDICINAL CHEMISTRY | BETA-AMINO ACIDS | LACTAM-SYNTHON-METHOD | TARGETING DRUG-DELIVERY | ASYMMETRIC-SYNTHESIS | NEW-GENERATION TAXOIDS | ANTICANCER AGENTS | CHEMISTRY, ORGANIC | ANGIOTENSIN-CONVERTING ENZYME | CARBON NANOTUBES | BOUND PACLITAXEL CONFORMATION | Hydrocarbons, Fluorinated - chemistry | Chemistry | Biology
MEDICINAL CHEMISTRY | BETA-AMINO ACIDS | LACTAM-SYNTHON-METHOD | TARGETING DRUG-DELIVERY | ASYMMETRIC-SYNTHESIS | NEW-GENERATION TAXOIDS | ANTICANCER AGENTS | CHEMISTRY, ORGANIC | ANGIOTENSIN-CONVERTING ENZYME | CARBON NANOTUBES | BOUND PACLITAXEL CONFORMATION | Hydrocarbons, Fluorinated - chemistry | Chemistry | Biology
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Loading RightsInternational Journal of Pharmaceutics, ISSN 0378-5173, 07/2016, Volume 509, Issue 1-2, pp. 208 - 218
Nanoscale Zr-based metal organic frameworks (MOFs) UiO-66 and UiO-67 were studied as potential anticancer drug delivery vehicles. Two model drugs were used,...
Polymer | Drug delivery | SEM | UiO-67 | ADF-STEM | Metal-organic frameworks/UiO-66 | MICROSPHERES | STABILITY | ENCAPSULATION | RELEASE | DELIVERY | NANOPARTICLES | IN-VITRO | METAL-ORGANIC FRAMEWORKS | CISPLATIN | DEGRADATION | PHARMACOLOGY & PHARMACY | Nanoparticles - chemistry | Humans | Coated Materials, Biocompatible - chemistry | Delayed-Action Preparations - chemistry | Polyethylene Glycols - chemistry | Caproates - chemistry | Antineoplastic Agents - administration & dosage | Antineoplastic Agents - chemistry | Drug Carriers - chemistry | Cisplatin - administration & dosage | Delayed-Action Preparations - administration & dosage | Particle Size | Paclitaxel - chemistry | Cisplatin - chemistry | Zirconium - chemistry | Cell Line, Tumor | Hydrophobic and Hydrophilic Interactions | Polymers - chemistry | Vitamin E - chemistry | Paclitaxel - administration & dosage | Drug Delivery Systems - methods | Lactones - chemistry | Antimitotic agents | Drugs | Drug delivery systems | Analysis | Catalysis | Antineoplastic agents | Vehicles | Squamous cell carcinoma | Gliomas | Polyethylene glycol | Polymer industry | Polyols | Index Medicus
Polymer | Drug delivery | SEM | UiO-67 | ADF-STEM | Metal-organic frameworks/UiO-66 | MICROSPHERES | STABILITY | ENCAPSULATION | RELEASE | DELIVERY | NANOPARTICLES | IN-VITRO | METAL-ORGANIC FRAMEWORKS | CISPLATIN | DEGRADATION | PHARMACOLOGY & PHARMACY | Nanoparticles - chemistry | Humans | Coated Materials, Biocompatible - chemistry | Delayed-Action Preparations - chemistry | Polyethylene Glycols - chemistry | Caproates - chemistry | Antineoplastic Agents - administration & dosage | Antineoplastic Agents - chemistry | Drug Carriers - chemistry | Cisplatin - administration & dosage | Delayed-Action Preparations - administration & dosage | Particle Size | Paclitaxel - chemistry | Cisplatin - chemistry | Zirconium - chemistry | Cell Line, Tumor | Hydrophobic and Hydrophilic Interactions | Polymers - chemistry | Vitamin E - chemistry | Paclitaxel - administration & dosage | Drug Delivery Systems - methods | Lactones - chemistry | Antimitotic agents | Drugs | Drug delivery systems | Analysis | Catalysis | Antineoplastic agents | Vehicles | Squamous cell carcinoma | Gliomas | Polyethylene glycol | Polymer industry | Polyols | Index Medicus
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Loading RightsJournal of Controlled Release, ISSN 0168-3659, 2009, Volume 133, Issue 1, pp. 11 - 17
The purpose of this study was to develop Cremophor EL-free nanoparticles loaded with Paclitaxel (PTX), intended to be intravenously administered, able to...
PLGA | PEGylated nanoparticle | Anti-tumoral activity | Paclitaxel | CELLS | PHOSPHORYLATION | CREMOPHOR-EL | DRUG-RELEASE | CHEMISTRY, MULTIDISCIPLINARY | CELLULAR UPTAKE | CANCER-THERAPY | DELIVERY | PHARMACOKINETICS | TAXOL | PHARMACOLOGY & PHARMACY | PARTICLE-SIZE | Paclitaxel - pharmacology | Nanoparticles - chemistry | Apoptosis - drug effects | Humans | Ethylene Oxide - chemistry | Male | Polyethylene Glycols - chemistry | Drug Carriers - chemistry | Paclitaxel - chemistry | Flow Cytometry | Glycerol - pharmacology | Antineoplastic Agents, Phytogenic - therapeutic use | Drug Evaluation, Preclinical | Glycerol - analogs & derivatives | Lactones - chemistry | Cell Survival - drug effects | Lactic Acid - chemistry | Antineoplastic Agents, Phytogenic - chemistry | Mice, Inbred Strains | Paclitaxel - therapeutic use | Neoplasms - drug therapy | Surface-Active Agents - pharmacology | Particle Size | Animals | Polyglycolic Acid - chemistry | Survival Analysis | Excipients - pharmacology | Mice | HeLa Cells | Antineoplastic Agents, Phytogenic - pharmacology | Neoplasms - pathology | Drugs | Nanoparticles | Chemotherapy | Drug delivery systems | Nanotechnology | Cervical cancer | Cancer | Vehicles
PLGA | PEGylated nanoparticle | Anti-tumoral activity | Paclitaxel | CELLS | PHOSPHORYLATION | CREMOPHOR-EL | DRUG-RELEASE | CHEMISTRY, MULTIDISCIPLINARY | CELLULAR UPTAKE | CANCER-THERAPY | DELIVERY | PHARMACOKINETICS | TAXOL | PHARMACOLOGY & PHARMACY | PARTICLE-SIZE | Paclitaxel - pharmacology | Nanoparticles - chemistry | Apoptosis - drug effects | Humans | Ethylene Oxide - chemistry | Male | Polyethylene Glycols - chemistry | Drug Carriers - chemistry | Paclitaxel - chemistry | Flow Cytometry | Glycerol - pharmacology | Antineoplastic Agents, Phytogenic - therapeutic use | Drug Evaluation, Preclinical | Glycerol - analogs & derivatives | Lactones - chemistry | Cell Survival - drug effects | Lactic Acid - chemistry | Antineoplastic Agents, Phytogenic - chemistry | Mice, Inbred Strains | Paclitaxel - therapeutic use | Neoplasms - drug therapy | Surface-Active Agents - pharmacology | Particle Size | Animals | Polyglycolic Acid - chemistry | Survival Analysis | Excipients - pharmacology | Mice | HeLa Cells | Antineoplastic Agents, Phytogenic - pharmacology | Neoplasms - pathology | Drugs | Nanoparticles | Chemotherapy | Drug delivery systems | Nanotechnology | Cervical cancer | Cancer | Vehicles
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Loading RightsJournal of the American Chemical Society, ISSN 0002-7863, 06/2018, Volume 140, Issue 24, pp. 7373 - 7376
Reactive oxygen species (ROS) and glutathione (GSH) dual responsive nanoparticulate drug delivery systems (nano-DDSs) hold great promise to improve the...
POLYMERIC NANOPARTICLES | GENE DELIVERY | PRODRUG | DRUG-DELIVERY | SYNERGISTIC THERAPY | NANOMEDICINE | ALPHA-LIPOIC ACID | BIOMEDICAL APPLICATIONS | CHEMISTRY, MULTIDISCIPLINARY | CANCER-THERAPY | CHEMOTHERAPY | Paclitaxel - pharmacology | Cricetulus | Nanoparticles - chemistry | Humans | Sulfides - chemistry | Drug Carriers - toxicity | Male | Sulfides - chemical synthesis | Antineoplastic Agents - therapeutic use | Drug Carriers - chemistry | Hydrogen Peroxide - chemistry | Paclitaxel - chemistry | Sulfides - toxicity | Biodegradable Plastics - toxicity | Biodegradable Plastics - chemical synthesis | Antineoplastic Agents - pharmacology | Prostatic Neoplasms - drug therapy | CHO Cells | Polymers - chemical synthesis | Drug Carriers - chemical synthesis | Antineoplastic Agents - chemistry | Nanoparticles - toxicity | Paclitaxel - therapeutic use | Xenograft Model Antitumor Assays | Animals | Green Chemistry Technology - methods | Polymers - toxicity | Cell Line, Tumor | Drug Liberation | Polymers - chemistry | Glutathione - chemistry | Mice | Biodegradable Plastics - chemistry | Index Medicus
POLYMERIC NANOPARTICLES | GENE DELIVERY | PRODRUG | DRUG-DELIVERY | SYNERGISTIC THERAPY | NANOMEDICINE | ALPHA-LIPOIC ACID | BIOMEDICAL APPLICATIONS | CHEMISTRY, MULTIDISCIPLINARY | CANCER-THERAPY | CHEMOTHERAPY | Paclitaxel - pharmacology | Cricetulus | Nanoparticles - chemistry | Humans | Sulfides - chemistry | Drug Carriers - toxicity | Male | Sulfides - chemical synthesis | Antineoplastic Agents - therapeutic use | Drug Carriers - chemistry | Hydrogen Peroxide - chemistry | Paclitaxel - chemistry | Sulfides - toxicity | Biodegradable Plastics - toxicity | Biodegradable Plastics - chemical synthesis | Antineoplastic Agents - pharmacology | Prostatic Neoplasms - drug therapy | CHO Cells | Polymers - chemical synthesis | Drug Carriers - chemical synthesis | Antineoplastic Agents - chemistry | Nanoparticles - toxicity | Paclitaxel - therapeutic use | Xenograft Model Antitumor Assays | Animals | Green Chemistry Technology - methods | Polymers - toxicity | Cell Line, Tumor | Drug Liberation | Polymers - chemistry | Glutathione - chemistry | Mice | Biodegradable Plastics - chemistry | Index Medicus
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Loading RightsJournal of Controlled Release, ISSN 0168-3659, 02/2012, Volume 157, Issue 3, pp. 455 - 460
Mucosal surfaces are protected by a highly viscoelastic and adhesive mucus layer that traps most foreign particles, including conventional drug and gene...
Drug delivery | PEG | Mucin | Vitamin E TPGS | VITAMIN-E-TPGS | PACLITAXEL TAXOL(R) | BARRIER | CONTROLLED-RELEASE | POLY(VINYL ALCOHOL) | MICROPARTICLES | CHEMISTRY, MULTIDISCIPLINARY | DELIVERY | NANOPARTICLES | TRACKING | PHARMACOLOGY & PHARMACY | FABRICATION | Paclitaxel - chemistry | Lactic Acid - chemistry | Nanoparticles - chemistry | Humans | Polyglycolic Acid - chemistry | Antineoplastic Agents, Phytogenic - chemistry | Polyethylene Glycols - chemistry | Surface-Active Agents - chemistry | Vitamin E - chemistry | Cervix Mucus - chemistry | Chemistry, Pharmaceutical | Drug Carriers - chemistry | Drugs | Ethylene glycol | Drug delivery systems | Polyethylene | Surface active agents | Glycols | Nucleic acids | Vehicles | drug delivery | mucin
Drug delivery | PEG | Mucin | Vitamin E TPGS | VITAMIN-E-TPGS | PACLITAXEL TAXOL(R) | BARRIER | CONTROLLED-RELEASE | POLY(VINYL ALCOHOL) | MICROPARTICLES | CHEMISTRY, MULTIDISCIPLINARY | DELIVERY | NANOPARTICLES | TRACKING | PHARMACOLOGY & PHARMACY | FABRICATION | Paclitaxel - chemistry | Lactic Acid - chemistry | Nanoparticles - chemistry | Humans | Polyglycolic Acid - chemistry | Antineoplastic Agents, Phytogenic - chemistry | Polyethylene Glycols - chemistry | Surface-Active Agents - chemistry | Vitamin E - chemistry | Cervix Mucus - chemistry | Chemistry, Pharmaceutical | Drug Carriers - chemistry | Drugs | Ethylene glycol | Drug delivery systems | Polyethylene | Surface active agents | Glycols | Nucleic acids | Vehicles | drug delivery | mucin
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Loading RightsAngewandte Chemie International Edition, ISSN 1433-7851, 03/2012, Volume 51, Issue 12, pp. 2864 - 2869
Demand and deliver: Micelles reversibly crosslinked by boronate esters (see scheme) show in vitro and in vivo stability, and thus minimize premature drug...
boronate | controlled release | FRET | micelles | nanocarriers | NANOPARTICLES | PACLITAXEL DELIVERY | RELEASE | CHEMISTRY, MULTIDISCIPLINARY | Nanoparticles - chemistry | Humans | Catechols - chemistry | Boronic Acids - chemistry | Drug Carriers - chemistry | Neoplasms - drug therapy | Paclitaxel - chemistry | Micelles | Glucose - chemistry | Cell Line, Tumor | Fluorescence Resonance Energy Transfer | Mannitol - chemistry | Paclitaxel - administration & dosage | Hydrogen-Ion Concentration
boronate | controlled release | FRET | micelles | nanocarriers | NANOPARTICLES | PACLITAXEL DELIVERY | RELEASE | CHEMISTRY, MULTIDISCIPLINARY | Nanoparticles - chemistry | Humans | Catechols - chemistry | Boronic Acids - chemistry | Drug Carriers - chemistry | Neoplasms - drug therapy | Paclitaxel - chemistry | Micelles | Glucose - chemistry | Cell Line, Tumor | Fluorescence Resonance Energy Transfer | Mannitol - chemistry | Paclitaxel - administration & dosage | Hydrogen-Ion Concentration
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Loading RightsACS Applied Materials & Interfaces, ISSN 1944-8244, 09/2015, Volume 7, Issue 35, pp. 19843 - 19852
The application of nanomaterials in intelligent drug delivery is developing rapidly for treatment of cancers. In this paper, we fabricated a new kind of...
dual-drug loading | biodegradable | acute toxicity | surface modification | intravital fluorescence imaging | nanohydrogels | multi stimuli-responsive | THERAPEUTICS | MATERIALS SCIENCE, MULTIDISCIPLINARY | CONTROLLED-RELEASE | NANOSCIENCE & NANOTECHNOLOGY | CANCER | PACLITAXEL | NANOPARTICLES | THERAPY | CISPLATIN | GENE-TRANSFER | NANOGELS | dual-drug loading multi stimuli-responsive | LIPOSOMES | Paclitaxel - metabolism | Paclitaxel - pharmacology | Glutathione - metabolism | Humans | Polyethylene Glycols - chemistry | Doxorubicin - chemistry | Drug Carriers - chemistry | Antineoplastic Agents - metabolism | Paclitaxel - chemistry | Antineoplastic Agents - pharmacology | Doxorubicin - metabolism | Peptide Hydrolases - metabolism | Biodegradation, Environmental | Cell Survival - drug effects | Drug Carriers - metabolism | Oxidation-Reduction | Folic Acid - chemistry | Polymethacrylic Acids - chemistry | Antineoplastic Agents - chemistry | Mice, Inbred ICR | Animals | Drug Liberation | Nanostructures - chemistry | Glutathione - chemistry | Mice | HeLa Cells | Doxorubicin - pharmacology | Hydrogels - chemistry | Hydrogen-Ion Concentration | Index Medicus
dual-drug loading | biodegradable | acute toxicity | surface modification | intravital fluorescence imaging | nanohydrogels | multi stimuli-responsive | THERAPEUTICS | MATERIALS SCIENCE, MULTIDISCIPLINARY | CONTROLLED-RELEASE | NANOSCIENCE & NANOTECHNOLOGY | CANCER | PACLITAXEL | NANOPARTICLES | THERAPY | CISPLATIN | GENE-TRANSFER | NANOGELS | dual-drug loading multi stimuli-responsive | LIPOSOMES | Paclitaxel - metabolism | Paclitaxel - pharmacology | Glutathione - metabolism | Humans | Polyethylene Glycols - chemistry | Doxorubicin - chemistry | Drug Carriers - chemistry | Antineoplastic Agents - metabolism | Paclitaxel - chemistry | Antineoplastic Agents - pharmacology | Doxorubicin - metabolism | Peptide Hydrolases - metabolism | Biodegradation, Environmental | Cell Survival - drug effects | Drug Carriers - metabolism | Oxidation-Reduction | Folic Acid - chemistry | Polymethacrylic Acids - chemistry | Antineoplastic Agents - chemistry | Mice, Inbred ICR | Animals | Drug Liberation | Nanostructures - chemistry | Glutathione - chemistry | Mice | HeLa Cells | Doxorubicin - pharmacology | Hydrogels - chemistry | Hydrogen-Ion Concentration | Index Medicus
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