Catalogue
Articles
RSS feedX
Search Filters
Format
Subjects
Library Location
Language
Publication DateBiological and Pharmaceutical Bulletin, ISSN 0918-6158, 2018, Volume 41, Issue 8, pp. 1145 - 1151
Articular chondrocytes are embedded in the cartilage of diarthrodial joints and responsible for the synthesis and secretion of extracellular matrix. The...
voltage-dependent Cl− channel | TMEM16 | chondrocyte | chloride channel | osteoarthritis | cartilage | Cartilage | Chondrocyte | Chloride channel | channel | Voltage-dependent Cl | Osteoarthritis | POTASSIUM CHANNELS | voltage-dependent CF channel | INTRACELLULAR CALCIUM | CANDIDATE GENES | ACTIVATED CHLORIDE CURRENTS | VOLUME REGULATION | RABBIT ARTICULAR CHONDROCYTES | ION-CHANNEL | PHARMACOLOGY & PHARMACY | OSTEOARTHRITIS MODEL | EXPRESSION | Cell proliferation | Electric potential | Drug development | Calcium signalling | Bone growth | Biomedical materials | Pain | Joints (anatomy) | Extracellular matrix | Biocompatibility | Physiology | Ion channels | Potassium channels (voltage-gated) | Membrane potential | Bone (endochondral) | Calcium channels | Cell survival | Proteoglycans | Secretion | Calcium channels (voltage-gated) | Cystic fibrosis | Cartilage (articular) | Acidity | Mammals | Joint diseases | Resistance | Collagen | Chondrocytes | Fibrosis | Conductance | Cell size | Potassium | Osteogenesis | Calcium ions | Cartilage diseases
voltage-dependent Cl− channel | TMEM16 | chondrocyte | chloride channel | osteoarthritis | cartilage | Cartilage | Chondrocyte | Chloride channel | channel | Voltage-dependent Cl | Osteoarthritis | POTASSIUM CHANNELS | voltage-dependent CF channel | INTRACELLULAR CALCIUM | CANDIDATE GENES | ACTIVATED CHLORIDE CURRENTS | VOLUME REGULATION | RABBIT ARTICULAR CHONDROCYTES | ION-CHANNEL | PHARMACOLOGY & PHARMACY | OSTEOARTHRITIS MODEL | EXPRESSION | Cell proliferation | Electric potential | Drug development | Calcium signalling | Bone growth | Biomedical materials | Pain | Joints (anatomy) | Extracellular matrix | Biocompatibility | Physiology | Ion channels | Potassium channels (voltage-gated) | Membrane potential | Bone (endochondral) | Calcium channels | Cell survival | Proteoglycans | Secretion | Calcium channels (voltage-gated) | Cystic fibrosis | Cartilage (articular) | Acidity | Mammals | Joint diseases | Resistance | Collagen | Chondrocytes | Fibrosis | Conductance | Cell size | Potassium | Osteogenesis | Calcium ions | Cartilage diseases
Journal Article
Details 
Digital rights
Loading RightsThe Journal of Physiology, ISSN 0022-3751, 11/2011, Volume 589, Issue 21, pp. 5071 - 5089
Non‐Technical Summary The debilitating condition of arthritis is caused by degeneration of the cartilage, a tissue that allows almost frictionless motion...
MATRIX SYNTHESIS | PHYSIOLOGY | POTASSIUM CHANNELS | TASK-2 KCNK5 | INTRACELLULAR CALCIUM | ION-CHANNEL | BUPIVACAINE | EXPRESSION | NEUROSCIENCES | MODULATION | CARTILAGE | Membrane Potentials - drug effects | Tetraethylammonium - pharmacology | Humans | Cells, Cultured | Potassium Channels, Tandem Pore Domain - genetics | Calcium Channel Blockers - pharmacology | Elapid Venoms - pharmacology | RNA, Messenger - metabolism | Peptides - pharmacology | Patch-Clamp Techniques | Potassium - physiology | Chondrocytes - physiology | Large-Conductance Calcium-Activated Potassium Channel alpha Subunits - genetics | Tibia | Potassium Channels, Tandem Pore Domain - physiology | Large-Conductance Calcium-Activated Potassium Channel alpha Subunits - physiology | Real-Time Polymerase Chain Reaction | Metabolism | Potassium | Knee | Cell culture | Calcium | Arthritis | Cell membranes | Tetraethylammonium | Potassium channels | Gene expression | Joint diseases | pH effects | Potassium channels (calcium-gated) | Polymerase chain reaction | Cartilage | Bupivacaine | Chondrocytes | Ion channels | Bone | Membrane potential | Molecular and Cellular
MATRIX SYNTHESIS | PHYSIOLOGY | POTASSIUM CHANNELS | TASK-2 KCNK5 | INTRACELLULAR CALCIUM | ION-CHANNEL | BUPIVACAINE | EXPRESSION | NEUROSCIENCES | MODULATION | CARTILAGE | Membrane Potentials - drug effects | Tetraethylammonium - pharmacology | Humans | Cells, Cultured | Potassium Channels, Tandem Pore Domain - genetics | Calcium Channel Blockers - pharmacology | Elapid Venoms - pharmacology | RNA, Messenger - metabolism | Peptides - pharmacology | Patch-Clamp Techniques | Potassium - physiology | Chondrocytes - physiology | Large-Conductance Calcium-Activated Potassium Channel alpha Subunits - genetics | Tibia | Potassium Channels, Tandem Pore Domain - physiology | Large-Conductance Calcium-Activated Potassium Channel alpha Subunits - physiology | Real-Time Polymerase Chain Reaction | Metabolism | Potassium | Knee | Cell culture | Calcium | Arthritis | Cell membranes | Tetraethylammonium | Potassium channels | Gene expression | Joint diseases | pH effects | Potassium channels (calcium-gated) | Polymerase chain reaction | Cartilage | Bupivacaine | Chondrocytes | Ion channels | Bone | Membrane potential | Molecular and Cellular
Journal Article
Details
Digital rights
Loading RightsAnnals of the Rheumatic Diseases, ISSN 0003-4967, 06/2017, Volume 76, Issue 6
Journal Article
Details
Digital rights
Loading Rights
4.
Full Text
Design of a nested eight‐channel sodium and four‐channel proton coil for 7T knee imaging
Magnetic Resonance in Medicine, ISSN 0740-3194, 07/2013, Volume 70, Issue 1, pp. 259 - 268
The critical design aim for a sodium/proton coil is to maximize sodium sensitivity and transmit field homogeneity while simultaneously providing adequate...
phased‐array | high‐field sodium MRI | cartilage | dual‐tuned coil | phased-array | high-field sodium MRI | dual-tuned coil | TO-NOISE-RATIO | MRI | FIXED CHARGE-DENSITY | QUADRATURE BIRDCAGE | RF COIL | NMR | ARTICULAR-CARTILAGE | JOINT IN-VIVO | MAGNETIC-RESONANCE | RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING | Protons | Reproducibility of Results | Humans | Magnetic Resonance Spectroscopy - instrumentation | Equipment Design | Image Interpretation, Computer-Assisted - instrumentation | Knee Joint - chemistry | Magnetics - instrumentation | Algorithms | Magnetic Resonance Imaging - instrumentation | Sodium - analysis | Sensitivity and Specificity | Knee Joint - anatomy & histology | Equipment Failure Analysis | Diagnostic imaging
phased‐array | high‐field sodium MRI | cartilage | dual‐tuned coil | phased-array | high-field sodium MRI | dual-tuned coil | TO-NOISE-RATIO | MRI | FIXED CHARGE-DENSITY | QUADRATURE BIRDCAGE | RF COIL | NMR | ARTICULAR-CARTILAGE | JOINT IN-VIVO | MAGNETIC-RESONANCE | RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING | Protons | Reproducibility of Results | Humans | Magnetic Resonance Spectroscopy - instrumentation | Equipment Design | Image Interpretation, Computer-Assisted - instrumentation | Knee Joint - chemistry | Magnetics - instrumentation | Algorithms | Magnetic Resonance Imaging - instrumentation | Sodium - analysis | Sensitivity and Specificity | Knee Joint - anatomy & histology | Equipment Failure Analysis | Diagnostic imaging
Journal Article
Details
Digital rights
Loading RightsProceedings of the National Academy of Sciences, ISSN 0027-8424, 11/2014, Volume 111, Issue 47, pp. E5114 - E5122
Diarthrodial joints are essential for load bearing and locomotion. Physiologically, articular cartilage sustains millions of cycles of mechanical loading....
Cartilage | Cartilage injury | Piezo | Mechanotransduction | Chondrocyte | CHONDROCYTE DEATH | MECHANICAL INJURY | PERICELLULAR MATRIX | mechanotransduction | INTRACELLULAR CALCIUM | MULTIDISCIPLINARY SCIENCES | cartilage | CELL-SURFACE | COMPRESSION | chondrocyte | cartilage injury | GENE-EXPRESSION | ACTIVATED ION CHANNELS | DYNAMIN | Animals | Chondrocytes - physiology | Ion Channels - genetics | Stress, Mechanical | Ion Channels - physiology | Mice | RNA, Small Interfering | Calcium Signaling | Cartilage, Articular - physiology | Biological Sciences | PNAS Plus
Cartilage | Cartilage injury | Piezo | Mechanotransduction | Chondrocyte | CHONDROCYTE DEATH | MECHANICAL INJURY | PERICELLULAR MATRIX | mechanotransduction | INTRACELLULAR CALCIUM | MULTIDISCIPLINARY SCIENCES | cartilage | CELL-SURFACE | COMPRESSION | chondrocyte | cartilage injury | GENE-EXPRESSION | ACTIVATED ION CHANNELS | DYNAMIN | Animals | Chondrocytes - physiology | Ion Channels - genetics | Stress, Mechanical | Ion Channels - physiology | Mice | RNA, Small Interfering | Calcium Signaling | Cartilage, Articular - physiology | Biological Sciences | PNAS Plus
Journal Article
Details
Digital rights
Loading RightsAnnals of the Rheumatic Diseases, ISSN 0003-4967, 06/2017, Volume 76, Issue Suppl 2, p. 6
Osteoarthritis (OA) has long been viewed as a degenerative “wear-and-tear” disease of cartilage. There is, however, increasing evidence to confirm that...
Chemical sensors | Pathogenesis | Innate immunity | Arthritis | Inflammation | Anti-inflammatory agents | Interleukin 17 | Calcium influx | Transient receptor potential proteins | Pain | Rheumatoid arthritis | Rodents | Interleukin 1 | Chondrocytes | Sensory neurons | Ankyrin | Osteoarthritis | Cartilage diseases
Chemical sensors | Pathogenesis | Innate immunity | Arthritis | Inflammation | Anti-inflammatory agents | Interleukin 17 | Calcium influx | Transient receptor potential proteins | Pain | Rheumatoid arthritis | Rodents | Interleukin 1 | Chondrocytes | Sensory neurons | Ankyrin | Osteoarthritis | Cartilage diseases
Journal Article
Details
Digital rights
Loading RightsBiofabrication, ISSN 1758-5082, 06/2013, Volume 5, Issue 2, pp. 025004 - 1-11
Tissue engineering has been a promising field of research, offering hope of bridging the gap between organ shortage and transplantation needs. However,...
CELLS | ALGINATE SCAFFOLD | MATERIALS SCIENCE, BIOMATERIALS | FABRICATION | ENGINEERING, BIOMEDICAL | HYDROGEL | Gene Expression | Hydrogel, Polyethylene Glycol Dimethacrylate - chemistry | Cell Survival | Cells, Cultured | Microfluidic Analytical Techniques - instrumentation | Stem Cells - cytology | Calcium Chloride - chemistry | Hexuronic Acids - chemistry | Stem Cells - metabolism | Tissue Scaffolds | Animals | Cattle | Alginates - chemistry | Cartilage - cytology | Glucuronic Acid - chemistry | Tissue Engineering | Rheology | Tissue engineering | Filaments | Barriers | Organs | Viability | Channels | Three dimensional
CELLS | ALGINATE SCAFFOLD | MATERIALS SCIENCE, BIOMATERIALS | FABRICATION | ENGINEERING, BIOMEDICAL | HYDROGEL | Gene Expression | Hydrogel, Polyethylene Glycol Dimethacrylate - chemistry | Cell Survival | Cells, Cultured | Microfluidic Analytical Techniques - instrumentation | Stem Cells - cytology | Calcium Chloride - chemistry | Hexuronic Acids - chemistry | Stem Cells - metabolism | Tissue Scaffolds | Animals | Cattle | Alginates - chemistry | Cartilage - cytology | Glucuronic Acid - chemistry | Tissue Engineering | Rheology | Tissue engineering | Filaments | Barriers | Organs | Viability | Channels | Three dimensional
Journal Article
Details
Digital rights
Loading RightsPLOS ONE, ISSN 1932-6203, 11/2011, Volume 6, Issue 11, p. e27957
Background: Understanding the key elements of signaling of chondroprogenitor cells at the earliest steps of differentiation may substantially improve our...
INACTIVATION | CALCIUM OSCILLATIONS | CHONDROCYTES | KV1.5 | SODIUM-CHANNELS | MULTIDISCIPLINARY SCIENCES | GROWTH | ACTIVATED POTASSIUM CHANNEL | PROLIFERATION | ION CHANNELS | DIFFERENTIATION | Tetraethylammonium - pharmacology | Chondrocytes - cytology | Chondrogenesis - drug effects | Chondrogenesis - genetics | Cell Count | Cytosol - drug effects | Extracellular Space - drug effects | Cartilage - drug effects | Gene Expression Profiling | Cell Lineage - drug effects | Chondrocytes - drug effects | Extracellular Space - metabolism | Potassium Channels, Voltage-Gated - metabolism | Cartilage - cytology | Sodium Channels - metabolism | Cell Membrane - metabolism | Tetrodotoxin - pharmacology | Cell Membrane - drug effects | Chondrocytes - metabolism | Potassium Channels, Voltage-Gated - genetics | Membrane Potentials - drug effects | Cartilage - embryology | Ions | Cartilage - metabolism | Chick Embryo | Gene Expression Regulation - drug effects | Patch-Clamp Techniques | Animals | Calcium Signaling - drug effects | Cell Differentiation - drug effects | Cytosol - metabolism | Kinetics | Ion Channel Gating - drug effects | Ammonium | Regulators | Thymidine | Confocal | Cartilage | Signal transduction | Embryology | Cell growth | Sodium channels (voltage-gated) | Physiology | Potassium channels (voltage-gated) | Membrane potential | Chondrogenesis | Calcium channels (voltage-gated) | Cultures | Anatomy & physiology | Gene expression | Joint diseases | Embryos | Polymerase chain reaction | Stem cells | Chondrocytes | Hypoxia | Tetrodotoxin | Cell proliferation | Electric potential | Plasma | Mesenchyme | Science | Oscillations | Confocal microscopy | Biology | Phase transitions | Limb buds | Depolarization | Calcium signalling | Windows (intervals) | Lymphocytes | Rodents | Ion channels | Localization | Calcium channels | Tissue engineering | Data processing | Histology | Biophysics | Tea | Microscopy | Differentiation | Potassium | Apoptosis
INACTIVATION | CALCIUM OSCILLATIONS | CHONDROCYTES | KV1.5 | SODIUM-CHANNELS | MULTIDISCIPLINARY SCIENCES | GROWTH | ACTIVATED POTASSIUM CHANNEL | PROLIFERATION | ION CHANNELS | DIFFERENTIATION | Tetraethylammonium - pharmacology | Chondrocytes - cytology | Chondrogenesis - drug effects | Chondrogenesis - genetics | Cell Count | Cytosol - drug effects | Extracellular Space - drug effects | Cartilage - drug effects | Gene Expression Profiling | Cell Lineage - drug effects | Chondrocytes - drug effects | Extracellular Space - metabolism | Potassium Channels, Voltage-Gated - metabolism | Cartilage - cytology | Sodium Channels - metabolism | Cell Membrane - metabolism | Tetrodotoxin - pharmacology | Cell Membrane - drug effects | Chondrocytes - metabolism | Potassium Channels, Voltage-Gated - genetics | Membrane Potentials - drug effects | Cartilage - embryology | Ions | Cartilage - metabolism | Chick Embryo | Gene Expression Regulation - drug effects | Patch-Clamp Techniques | Animals | Calcium Signaling - drug effects | Cell Differentiation - drug effects | Cytosol - metabolism | Kinetics | Ion Channel Gating - drug effects | Ammonium | Regulators | Thymidine | Confocal | Cartilage | Signal transduction | Embryology | Cell growth | Sodium channels (voltage-gated) | Physiology | Potassium channels (voltage-gated) | Membrane potential | Chondrogenesis | Calcium channels (voltage-gated) | Cultures | Anatomy & physiology | Gene expression | Joint diseases | Embryos | Polymerase chain reaction | Stem cells | Chondrocytes | Hypoxia | Tetrodotoxin | Cell proliferation | Electric potential | Plasma | Mesenchyme | Science | Oscillations | Confocal microscopy | Biology | Phase transitions | Limb buds | Depolarization | Calcium signalling | Windows (intervals) | Lymphocytes | Rodents | Ion channels | Localization | Calcium channels | Tissue engineering | Data processing | Histology | Biophysics | Tea | Microscopy | Differentiation | Potassium | Apoptosis
Journal Article
Details
Digital rights
Loading RightsCurrent Osteoporosis Reports, ISSN 1544-1873, 12/2016, Volume 14, Issue 6, pp. 260 - 268
Worldwide, osteoarthritis (OA) is one of the leading causes of chronic pain, for which adequate relief is not available. Ongoing peripheral input from the...
Pain | Medicine & Public Health | Orthopedics | GPCRs | Nerve growth factor | Targets | Ion channels | Epidemiology | Osteoarthritis | KNEE | PRIMARY AFFERENTS | GENE-RELATED PEPTIDE | INTRAARTICULAR INJECTION | SODIUM-CHANNELS | SENSING ION CHANNELS | RAT MODEL | NERVE GROWTH-FACTOR | ARTICULAR-CARTILAGE | ENDOCRINOLOGY & METABOLISM | JOINT PAIN | Arthralgia - etiology | Transient Receptor Potential Channels - antagonists & inhibitors | Calcium Channels - metabolism | Receptors, G-Protein-Coupled - metabolism | Humans | Calcium Channel Blockers - therapeutic use | Molecular Targeted Therapy | Osteoarthritis - drug therapy | Receptors, Calcitonin Gene-Related Peptide - metabolism | Nerve Growth Factor - antagonists & inhibitors | Voltage-Gated Sodium Channel Blockers - therapeutic use | Receptors, Chemokine - antagonists & inhibitors | Transient Receptor Potential Channels - metabolism | Osteoarthritis - complications | Nerve Growth Factor - metabolism | Acid Sensing Ion Channel Blockers - therapeutic use | Receptors, Calcitonin Gene-Related Peptide - antagonists & inhibitors | Receptors, Chemokine - metabolism | Osteoarthritis - metabolism | Receptors, Bradykinin - metabolism | Arthralgia - metabolism | Receptors, G-Protein-Coupled - antagonists & inhibitors | Bradykinin Receptor Antagonists - therapeutic use | Arthralgia - drug therapy | Voltage-Gated Sodium Channels - metabolism | Acid Sensing Ion Channels - metabolism | Calcium channels | Care and treatment | Analysis | Chronic pain | Nerve Growth Factor
Pain | Medicine & Public Health | Orthopedics | GPCRs | Nerve growth factor | Targets | Ion channels | Epidemiology | Osteoarthritis | KNEE | PRIMARY AFFERENTS | GENE-RELATED PEPTIDE | INTRAARTICULAR INJECTION | SODIUM-CHANNELS | SENSING ION CHANNELS | RAT MODEL | NERVE GROWTH-FACTOR | ARTICULAR-CARTILAGE | ENDOCRINOLOGY & METABOLISM | JOINT PAIN | Arthralgia - etiology | Transient Receptor Potential Channels - antagonists & inhibitors | Calcium Channels - metabolism | Receptors, G-Protein-Coupled - metabolism | Humans | Calcium Channel Blockers - therapeutic use | Molecular Targeted Therapy | Osteoarthritis - drug therapy | Receptors, Calcitonin Gene-Related Peptide - metabolism | Nerve Growth Factor - antagonists & inhibitors | Voltage-Gated Sodium Channel Blockers - therapeutic use | Receptors, Chemokine - antagonists & inhibitors | Transient Receptor Potential Channels - metabolism | Osteoarthritis - complications | Nerve Growth Factor - metabolism | Acid Sensing Ion Channel Blockers - therapeutic use | Receptors, Calcitonin Gene-Related Peptide - antagonists & inhibitors | Receptors, Chemokine - metabolism | Osteoarthritis - metabolism | Receptors, Bradykinin - metabolism | Arthralgia - metabolism | Receptors, G-Protein-Coupled - antagonists & inhibitors | Bradykinin Receptor Antagonists - therapeutic use | Arthralgia - drug therapy | Voltage-Gated Sodium Channels - metabolism | Acid Sensing Ion Channels - metabolism | Calcium channels | Care and treatment | Analysis | Chronic pain | Nerve Growth Factor
Journal Article
Details
Digital rights
Loading RightsJournal of the Mechanical Behavior of Biomedical Materials, ISSN 1751-6161, 02/2018, Volume 78, pp. 298 - 314
Over the past decades, significant progress has been achieved in the field of tissue engineering (TE) to restore/repair damaged tissues or organs and, in this...
Dispensing-based bioprinting | 3D bioprinting | Hybrid scaffolds | Tissue engineering | Biomaterials | Vessel-like channels | DESIGN | MATERIALS SCIENCE, BIOMATERIALS | DRUG-DELIVERY | ENGINEERING, BIOMEDICAL | 3-DIMENSIONAL FIBER-DEPOSITION | CONSTRUCTS | ALGINATE HYDROGEL | POROUS SCAFFOLDS | ARTICULAR-CARTILAGE | GROWTH-FACTORS | CELL-LADEN | FREEFORM FABRICATION | Blood Vessels | Tissue Scaffolds | Mechanical Phenomena | Tissue Engineering - methods | Bioprinting - methods | Humans | Technology application | Biomedical materials | Production processes | 3D printing
Dispensing-based bioprinting | 3D bioprinting | Hybrid scaffolds | Tissue engineering | Biomaterials | Vessel-like channels | DESIGN | MATERIALS SCIENCE, BIOMATERIALS | DRUG-DELIVERY | ENGINEERING, BIOMEDICAL | 3-DIMENSIONAL FIBER-DEPOSITION | CONSTRUCTS | ALGINATE HYDROGEL | POROUS SCAFFOLDS | ARTICULAR-CARTILAGE | GROWTH-FACTORS | CELL-LADEN | FREEFORM FABRICATION | Blood Vessels | Tissue Scaffolds | Mechanical Phenomena | Tissue Engineering - methods | Bioprinting - methods | Humans | Technology application | Biomedical materials | Production processes | 3D printing
Journal Article
Details
Digital rights
Loading RightsCellular Physiology and Biochemistry, ISSN 1015-8987, 12/2011, Volume 28, Issue 6, pp. 1111 - 1122
Chondrocytes are the cells within cartilage which produce and maintain the extracellular matrix. Volume regulation in these cells is vital to their function...
Review | Potassium ion channel | RVD | Cell Volume Regulation | RVI | TRPV6 | TRPV4 | TRPV5 | Membrane potential | Ion channel | PHYSIOLOGY | BOVINE ARTICULAR CHONDROCYTES | INTRACELLULAR CALCIUM | AQUAPORIN WATER CHANNELS | LONGITUDINAL BONE-GROWTH | CELL BIOLOGY | MEMBRANE ION CHANNELS | POTENTIAL VANILLOID 4 | FEMORAL-HEAD CARTILAGE | OSTEOARTHRITIC HUMAN CARTILAGE | IN-SITU | POTASSIUM CHANNEL | Potassium Channels - metabolism | TRPV Cation Channels - metabolism | Chondrocytes - cytology | TRPV Cation Channels - physiology | Chondrocytes - physiology | Ion Channels - metabolism | Humans | Potassium Channels - physiology | Cell Size | Ion Channels - physiology | Membrane Potentials - physiology | Chondrocytes - metabolism
Review | Potassium ion channel | RVD | Cell Volume Regulation | RVI | TRPV6 | TRPV4 | TRPV5 | Membrane potential | Ion channel | PHYSIOLOGY | BOVINE ARTICULAR CHONDROCYTES | INTRACELLULAR CALCIUM | AQUAPORIN WATER CHANNELS | LONGITUDINAL BONE-GROWTH | CELL BIOLOGY | MEMBRANE ION CHANNELS | POTENTIAL VANILLOID 4 | FEMORAL-HEAD CARTILAGE | OSTEOARTHRITIC HUMAN CARTILAGE | IN-SITU | POTASSIUM CHANNEL | Potassium Channels - metabolism | TRPV Cation Channels - metabolism | Chondrocytes - cytology | TRPV Cation Channels - physiology | Chondrocytes - physiology | Ion Channels - metabolism | Humans | Potassium Channels - physiology | Cell Size | Ion Channels - physiology | Membrane Potentials - physiology | Chondrocytes - metabolism
Journal Article
Details
Digital rights
Loading RightsMagnetic Resonance in Medicine, ISSN 0740-3194, 03/2017, Volume 77, Issue 3, pp. 1276 - 1283
Purpose To use quantitative susceptibility mapping (QSM) to investigate changes in cartilage canals in the distal femur of juvenile goats after their surgical...
chondronecrosis | OCD | quantitative susceptibility mapping | vascular canal abnormality | high‐field MRI | epiphyseal cartilage | cartilage canals | QSM | osteochondrosis | osteochondritis dissecans | high-field MRI | VIVO | MRI | RELAXATION | PREDILECTION SITES | LESIONS | ARTICULAR-CARTILAGE | T-2 | ARCHITECTURE | RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING | Osteochondritis Dissecans - pathology | Cartilage, Articular - diagnostic imaging | Reproducibility of Results | Goats | Image Interpretation, Computer-Assisted - methods | Magnetic Resonance Imaging - methods | Asymptomatic Diseases | Osteochondritis Dissecans - diagnosis | Cartilage, Articular - pathology | Algorithms | Animals | Sensitivity and Specificity | Image Enhancement - methods | In Vitro Techniques | Osteochondrosis | high field MRI
chondronecrosis | OCD | quantitative susceptibility mapping | vascular canal abnormality | high‐field MRI | epiphyseal cartilage | cartilage canals | QSM | osteochondrosis | osteochondritis dissecans | high-field MRI | VIVO | MRI | RELAXATION | PREDILECTION SITES | LESIONS | ARTICULAR-CARTILAGE | T-2 | ARCHITECTURE | RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING | Osteochondritis Dissecans - pathology | Cartilage, Articular - diagnostic imaging | Reproducibility of Results | Goats | Image Interpretation, Computer-Assisted - methods | Magnetic Resonance Imaging - methods | Asymptomatic Diseases | Osteochondritis Dissecans - diagnosis | Cartilage, Articular - pathology | Algorithms | Animals | Sensitivity and Specificity | Image Enhancement - methods | In Vitro Techniques | Osteochondrosis | high field MRI
Journal Article
Details
Digital rights
Loading Rights