Skeletal scintigraphy in children
Identifieur interne : 004F40 ( Main/Exploration ); précédent : 004F39; suivant : 004F41Skeletal scintigraphy in children
Auteurs : Larry D. Samuels [États-Unis, Suède]Source :
- Seminars in Nuclear Medicine [ 0001-2998 ] ; 1973.
Descripteurs français
- KwdFr :
- Adolescent, Adulte, Baryum, Dysplasies osseuses (diagnostic), Dysprosium, Enfant, Facteurs temps, Femelle, Fluor, Fractures osseuses (diagnostic), Humains, Inflammation (diagnostic), Isotopes du strontium, Lanthane, Maladies articulaires (diagnostic), Maladies osseuses (diagnostic), Myosite ossifiante (diagnostic), Mâle, Ostéomyélite (diagnostic), Ostéosarcome (diagnostic), Radio-isotopes, Récidive tumorale locale (diagnostic), Scintigraphie, Technétium, Thulium, Tumeurs osseuses (diagnostic).
- MESH :
- Wicri :
English descriptors
- KwdEn :
- Abdominal tumors, Adolescent, Adult, Alveolar sarcoma, Barium, Benign, Benign bone cyst, Benign tumors, Blood clearance, Bone Diseases (diagnosis), Bone Diseases, Developmental (diagnosis), Bone Neoplasms (diagnosis), Bone disease, Bone lesions, Bone scanning, Bone scans, Bone tumor, Bone tumors, Child, Dysprosium, Early detection, Electronic contrast enhancement, Extraosseous tumors, Female, Femur, Fluorine, Fracture, Fractures, Bone (diagnosis), Gallium isotopes, Gamma emission, General properties, Growth centers, Growth rate, Humans, Imaging, Inflammation (diagnosis), Intense uptake, Isotope, Joint Diseases (diagnosis), Joint disease, Joint space, Lanthanum, Lateral views, Lesion, Localization, Long bone, Lung scanning, Male, Malignant, Malignant bone tumors, Malignant tumors, Medical radioisotope scintigraphy, Metastatic, Metastatic osteosarcoma, Myositis Ossificans (diagnosis), Myositis ossificans, Neoplasm Recurrence, Local (diagnosis), Nucl, Nuclear medicine, Nuclear medicine laboratory, Older children, Osteomyelitis, Osteomyelitis (diagnosis), Osteosarcoma, Osteosarcoma (diagnosis), Pediatric, Pediatric cases, Pediatric patient, Pediatric patients, Positive scans, Primary bone tumors, Prominent abdomen, Pulmonary metastases, Radiation dose, Radiation exposure, Radioisotopes, Radiol, Radionuclide, Radionuclide Imaging, Radionuclide uptake, Rectilinear scanner, Rheumatoid arthritis, Right knee, Sarcoma, Scan, Scanning, Scintigraphy, Scintiscan, Skeletal imaging, Skeletal lesions, Skeletal scanning, Skeletal scintigraphy, Soft tissue, Strontium, Strontium Isotopes, Study time interval, Subcutaneous leukemic, Technetium, Thulium, Time Factors, Tumor, Unpublished data, Unsuspected fracture, Uptake.
- MESH :
- chemical : Barium, Dysprosium, Fluorine, Lanthanum, Radioisotopes, Strontium Isotopes, Technetium, Thulium.
- diagnosis : Bone Diseases, Bone Diseases, Developmental, Bone Neoplasms, Fractures, Bone, Inflammation, Joint Diseases, Myositis Ossificans, Neoplasm Recurrence, Local, Osteomyelitis, Osteosarcoma.
- Teeft :
- Abdominal tumors, Adolescent, Adult, Alveolar sarcoma, Benign, Benign bone cyst, Benign tumors, Blood clearance, Bone disease, Bone lesions, Bone scanning, Bone scans, Bone tumor, Bone tumors, Child, Early detection, Electronic contrast enhancement, Extraosseous tumors, Female, Femur, Fracture, Gallium isotopes, Gamma emission, General properties, Growth centers, Growth rate, Humans, Imaging, Intense uptake, Isotope, Joint disease, Joint space, Lateral views, Lesion, Localization, Long bone, Lung scanning, Male, Malignant, Malignant bone tumors, Malignant tumors, Medical radioisotope scintigraphy, Metastatic, Metastatic osteosarcoma, Myositis ossificans, Nucl, Nuclear medicine, Nuclear medicine laboratory, Older children, Osteomyelitis, Osteosarcoma, Pediatric, Pediatric cases, Pediatric patient, Pediatric patients, Positive scans, Primary bone tumors, Prominent abdomen, Pulmonary metastases, Radiation dose, Radiation exposure, Radiol, Radionuclide, Radionuclide Imaging, Radionuclide uptake, Rectilinear scanner, Rheumatoid arthritis, Right knee, Sarcoma, Scan, Scanning, Scintigraphy, Scintiscan, Skeletal imaging, Skeletal lesions, Skeletal scanning, Skeletal scintigraphy, Soft tissue, Strontium, Study time interval, Subcutaneous leukemic, Time Factors, Tumor, Unpublished data, Unsuspected fracture, Uptake.
Abstract
Skeletal scintigraphy in children has not generally been possible until the past 5 yr, since only 87mSr 18F and the phosphate compounds of 99mTc are recommended for pediatric use and their availability has been limited until very recently. The literature on pediatric use of 87mSr and 18F is reviewed and compared with a series of 200 children scanned with 87mSr in the author's laboratory. Illustrated examples are given of 87mSr diagnosis of malignant bone disease, metastatic bone, sarcoma, and soft tissue sarcoma. as well as the nonmalignant diseases osteoarthritis, osteomyelitis, myositis ossificas, growth deformity, and nonunion of fracture. The necessity for waiting an adequate period of time between injection of 87mSr and scanning is emphasized: at least 2 hr are required for children and 4–5 hr for adults or teenaged patients. The mechanism of uptake of boneseeking nuclides by bone tumors is not known; several theories are considered. Our recent experience suggests that it may be feasible to exploit 87mSr for its general tumor-localizing properties in addition to its bone-seeking property, as has been done with the radioactive gallium isotopes.
Url:
DOI: 10.1016/S0001-2998(73)80007-8
Affiliations:
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Le document en format XML
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<profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Abdominal tumors</term>
<term>Adolescent</term>
<term>Adult</term>
<term>Alveolar sarcoma</term>
<term>Barium</term>
<term>Benign</term>
<term>Benign bone cyst</term>
<term>Benign tumors</term>
<term>Blood clearance</term>
<term>Bone Diseases (diagnosis)</term>
<term>Bone Diseases, Developmental (diagnosis)</term>
<term>Bone Neoplasms (diagnosis)</term>
<term>Bone disease</term>
<term>Bone lesions</term>
<term>Bone scanning</term>
<term>Bone scans</term>
<term>Bone tumor</term>
<term>Bone tumors</term>
<term>Child</term>
<term>Dysprosium</term>
<term>Early detection</term>
<term>Electronic contrast enhancement</term>
<term>Extraosseous tumors</term>
<term>Female</term>
<term>Femur</term>
<term>Fluorine</term>
<term>Fracture</term>
<term>Fractures, Bone (diagnosis)</term>
<term>Gallium isotopes</term>
<term>Gamma emission</term>
<term>General properties</term>
<term>Growth centers</term>
<term>Growth rate</term>
<term>Humans</term>
<term>Imaging</term>
<term>Inflammation (diagnosis)</term>
<term>Intense uptake</term>
<term>Isotope</term>
<term>Joint Diseases (diagnosis)</term>
<term>Joint disease</term>
<term>Joint space</term>
<term>Lanthanum</term>
<term>Lateral views</term>
<term>Lesion</term>
<term>Localization</term>
<term>Long bone</term>
<term>Lung scanning</term>
<term>Male</term>
<term>Malignant</term>
<term>Malignant bone tumors</term>
<term>Malignant tumors</term>
<term>Medical radioisotope scintigraphy</term>
<term>Metastatic</term>
<term>Metastatic osteosarcoma</term>
<term>Myositis Ossificans (diagnosis)</term>
<term>Myositis ossificans</term>
<term>Neoplasm Recurrence, Local (diagnosis)</term>
<term>Nucl</term>
<term>Nuclear medicine</term>
<term>Nuclear medicine laboratory</term>
<term>Older children</term>
<term>Osteomyelitis</term>
<term>Osteomyelitis (diagnosis)</term>
<term>Osteosarcoma</term>
<term>Osteosarcoma (diagnosis)</term>
<term>Pediatric</term>
<term>Pediatric cases</term>
<term>Pediatric patient</term>
<term>Pediatric patients</term>
<term>Positive scans</term>
<term>Primary bone tumors</term>
<term>Prominent abdomen</term>
<term>Pulmonary metastases</term>
<term>Radiation dose</term>
<term>Radiation exposure</term>
<term>Radioisotopes</term>
<term>Radiol</term>
<term>Radionuclide</term>
<term>Radionuclide Imaging</term>
<term>Radionuclide uptake</term>
<term>Rectilinear scanner</term>
<term>Rheumatoid arthritis</term>
<term>Right knee</term>
<term>Sarcoma</term>
<term>Scan</term>
<term>Scanning</term>
<term>Scintigraphy</term>
<term>Scintiscan</term>
<term>Skeletal imaging</term>
<term>Skeletal lesions</term>
<term>Skeletal scanning</term>
<term>Skeletal scintigraphy</term>
<term>Soft tissue</term>
<term>Strontium</term>
<term>Strontium Isotopes</term>
<term>Study time interval</term>
<term>Subcutaneous leukemic</term>
<term>Technetium</term>
<term>Thulium</term>
<term>Time Factors</term>
<term>Tumor</term>
<term>Unpublished data</term>
<term>Unsuspected fracture</term>
<term>Uptake</term>
</keywords>
<keywords scheme="KwdFr" xml:lang="fr"><term>Adolescent</term>
<term>Adulte</term>
<term>Baryum</term>
<term>Dysplasies osseuses (diagnostic)</term>
<term>Dysprosium</term>
<term>Enfant</term>
<term>Facteurs temps</term>
<term>Femelle</term>
<term>Fluor</term>
<term>Fractures osseuses (diagnostic)</term>
<term>Humains</term>
<term>Inflammation (diagnostic)</term>
<term>Isotopes du strontium</term>
<term>Lanthane</term>
<term>Maladies articulaires (diagnostic)</term>
<term>Maladies osseuses (diagnostic)</term>
<term>Myosite ossifiante (diagnostic)</term>
<term>Mâle</term>
<term>Ostéomyélite (diagnostic)</term>
<term>Ostéosarcome (diagnostic)</term>
<term>Radio-isotopes</term>
<term>Récidive tumorale locale (diagnostic)</term>
<term>Scintigraphie</term>
<term>Technétium</term>
<term>Thulium</term>
<term>Tumeurs osseuses (diagnostic)</term>
</keywords>
<keywords scheme="MESH" type="chemical" xml:lang="en"><term>Barium</term>
<term>Dysprosium</term>
<term>Fluorine</term>
<term>Lanthanum</term>
<term>Radioisotopes</term>
<term>Strontium Isotopes</term>
<term>Technetium</term>
<term>Thulium</term>
</keywords>
<keywords scheme="MESH" qualifier="diagnosis" xml:lang="en"><term>Bone Diseases</term>
<term>Bone Diseases, Developmental</term>
<term>Bone Neoplasms</term>
<term>Fractures, Bone</term>
<term>Inflammation</term>
<term>Joint Diseases</term>
<term>Myositis Ossificans</term>
<term>Neoplasm Recurrence, Local</term>
<term>Osteomyelitis</term>
<term>Osteosarcoma</term>
</keywords>
<keywords scheme="MESH" qualifier="diagnostic" xml:lang="fr"><term>Dysplasies osseuses</term>
<term>Fractures osseuses</term>
<term>Inflammation</term>
<term>Maladies articulaires</term>
<term>Maladies osseuses</term>
<term>Myosite ossifiante</term>
<term>Ostéomyélite</term>
<term>Ostéosarcome</term>
<term>Récidive tumorale locale</term>
<term>Tumeurs osseuses</term>
</keywords>
<keywords scheme="Teeft" xml:lang="en"><term>Abdominal tumors</term>
<term>Adolescent</term>
<term>Adult</term>
<term>Alveolar sarcoma</term>
<term>Benign</term>
<term>Benign bone cyst</term>
<term>Benign tumors</term>
<term>Blood clearance</term>
<term>Bone disease</term>
<term>Bone lesions</term>
<term>Bone scanning</term>
<term>Bone scans</term>
<term>Bone tumor</term>
<term>Bone tumors</term>
<term>Child</term>
<term>Early detection</term>
<term>Electronic contrast enhancement</term>
<term>Extraosseous tumors</term>
<term>Female</term>
<term>Femur</term>
<term>Fracture</term>
<term>Gallium isotopes</term>
<term>Gamma emission</term>
<term>General properties</term>
<term>Growth centers</term>
<term>Growth rate</term>
<term>Humans</term>
<term>Imaging</term>
<term>Intense uptake</term>
<term>Isotope</term>
<term>Joint disease</term>
<term>Joint space</term>
<term>Lateral views</term>
<term>Lesion</term>
<term>Localization</term>
<term>Long bone</term>
<term>Lung scanning</term>
<term>Male</term>
<term>Malignant</term>
<term>Malignant bone tumors</term>
<term>Malignant tumors</term>
<term>Medical radioisotope scintigraphy</term>
<term>Metastatic</term>
<term>Metastatic osteosarcoma</term>
<term>Myositis ossificans</term>
<term>Nucl</term>
<term>Nuclear medicine</term>
<term>Nuclear medicine laboratory</term>
<term>Older children</term>
<term>Osteomyelitis</term>
<term>Osteosarcoma</term>
<term>Pediatric</term>
<term>Pediatric cases</term>
<term>Pediatric patient</term>
<term>Pediatric patients</term>
<term>Positive scans</term>
<term>Primary bone tumors</term>
<term>Prominent abdomen</term>
<term>Pulmonary metastases</term>
<term>Radiation dose</term>
<term>Radiation exposure</term>
<term>Radiol</term>
<term>Radionuclide</term>
<term>Radionuclide Imaging</term>
<term>Radionuclide uptake</term>
<term>Rectilinear scanner</term>
<term>Rheumatoid arthritis</term>
<term>Right knee</term>
<term>Sarcoma</term>
<term>Scan</term>
<term>Scanning</term>
<term>Scintigraphy</term>
<term>Scintiscan</term>
<term>Skeletal imaging</term>
<term>Skeletal lesions</term>
<term>Skeletal scanning</term>
<term>Skeletal scintigraphy</term>
<term>Soft tissue</term>
<term>Strontium</term>
<term>Study time interval</term>
<term>Subcutaneous leukemic</term>
<term>Time Factors</term>
<term>Tumor</term>
<term>Unpublished data</term>
<term>Unsuspected fracture</term>
<term>Uptake</term>
</keywords>
<keywords scheme="Wicri" type="topic" xml:lang="fr"><term>Adolescent</term>
<term>Adulte</term>
<term>Baryum</term>
<term>Dysprosium</term>
<term>Enfant</term>
<term>Facteurs temps</term>
<term>Femelle</term>
<term>Fluor</term>
<term>Humains</term>
<term>Isotopes du strontium</term>
<term>Lanthane</term>
<term>Mâle</term>
<term>Médecine nucléaire</term>
<term>Radio-isotopes</term>
<term>Scintigraphie</term>
<term>Technétium</term>
<term>Thulium</term>
</keywords>
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<front><div type="abstract" xml:lang="en">Skeletal scintigraphy in children has not generally been possible until the past 5 yr, since only 87mSr 18F and the phosphate compounds of 99mTc are recommended for pediatric use and their availability has been limited until very recently. The literature on pediatric use of 87mSr and 18F is reviewed and compared with a series of 200 children scanned with 87mSr in the author's laboratory. Illustrated examples are given of 87mSr diagnosis of malignant bone disease, metastatic bone, sarcoma, and soft tissue sarcoma. as well as the nonmalignant diseases osteoarthritis, osteomyelitis, myositis ossificas, growth deformity, and nonunion of fracture. The necessity for waiting an adequate period of time between injection of 87mSr and scanning is emphasized: at least 2 hr are required for children and 4–5 hr for adults or teenaged patients. The mechanism of uptake of boneseeking nuclides by bone tumors is not known; several theories are considered. Our recent experience suggests that it may be feasible to exploit 87mSr for its general tumor-localizing properties in addition to its bone-seeking property, as has been done with the radioactive gallium isotopes.</div>
</front>
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