Radiopharmacology is the study and preparation of radiopharmaceuticals, which are radioactive pharmaceuticals. Radiopharmaceuticals are used in the field of nuclear medicine as tracers in the diagnosis and treatment of many diseases. Many radiopharmaceuticals use technetium-99m (Tc-99m) which has many useful properties as a gamma-emitting tracer nuclide. In the book Technetium a total of 31 different radiopharmaceuticals based on Tc-99m are listed for imaging and functional studies of the brain, myocardium, thyroid, lungs, liver, gallbladder, kidneys, skeleton, blood and tumors.[1]
The term radioisotope has historically been used to refer to all radiopharmaceuticals, and this usage remains common. Technically, however, many radiopharmaceuticals incorporate a radioactive tracer atom into a larger pharmaceutically-active molecule, which is localized in the body, after which the radionuclide tracer atom allows it to be easily detected with a gamma camera or similar gamma imaging device. An example is fludeoxyglucose in which fluorine-18 is incorporated into deoxyglucose. Some radioisotopes (for example gallium-67, gallium-68, and radioiodine) are used directly as soluble ionic salts, without further modification. This use relies on the chemical and biological properties of the radioisotope itself, to localize it within the body.
[edit] History
See nuclear medicine.
[edit] Production
Production of a radiopharmaceutical involves two processes:
- The production of the radionuclide on which the pharmaceutical is based.
- The preparation and packaging of the complete radiopharmaceutical.
Radionuclides used in radiopharmaceuticals are mostly radioactive isotopes of elements with atomic numbers less than that of bismuth, that is, they are radioactive isotopes of elements that also have one or more stable isotopes. These may be roughly divided into two classes:
- Those with fewer neutrons in the nucleus to those required for stability are known as neutron-deficient, and tend to be most easily produced using a proton accelerator such as a medical cyclotron.
- Those with excess neutrons in the nucleus to those required for stability are known as proton-deficient, and tend to be most easily produced in a nuclear reactor.
[edit] Practical use
Because radiopharmeuticals require special licenses and handling techniques, they are often kept in local centers for medical radioisotope storage, often known as radiopharmacies. A radiopharmacist may dispense them from there, to local centers where they are handled at the practical medicine facility.
[edit] Specific radiopharmaceuticals
A list of nuclear medicine radiopharmaceuticals follows. Some radioisotopes* are used in ionic or inert form without attachment to a pharmaceutical, these are also included. There is a section for each radioisotope with a table of radiopharmaceuticals using that radioisotope. The sections are ordered alphabetically by the English name of the radioisotope. Sections for the same element are then ordered by atomic mass number.
[edit] Calcium-47
47Ca is a beta and gamma emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| Ca-47-Ca2+ |
Bone metabolism |
IV |
In-vitro |
Non-imaging |
[edit] Carbon-11
11C is a positron emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| C11-L-methyl-methionine |
Brain tumour imaging
Parathyroid imaging
|
IV |
In-vivo |
Imaging |
[edit] Carbon-14
14C is a beta emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| C14-Glycocholic acid |
Breath test for small intestine bacterial overgrowth |
Oral |
In-vitro |
Non-imaging |
| C14-PABA (para-amino benzoic acid) |
Pancreatic studies |
Oral |
In-vitro |
Non-imaging |
| C14-Urea |
Breath test to detect Helicobacter pylori |
Oral |
In-vitro |
Non-imaging |
| C14-d-xylose |
Breath test for small intestine bacterial overgrowth |
Oral |
In-vitro |
Non-imaging |
[edit] Chromium-51
51Cr is a gamma emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| Cr51-Red blood cells |
Red cell volume; sites of sequestration; gastrointestinal blood loss |
IV |
In-vitro |
Non-imaging |
| Cr51-Cr3+ |
Gastrointestinal protein loss |
IV |
In-vitro |
Non-imaging |
| Cr51-EDTA (ethylenediaminetetraacetic acid) |
Glomerular filtration rate measurement |
IV |
In-vitro |
Non-imaging |
[edit] Cobalt-57
57Co is a gamma emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| Co57-Cyanocobalamin (vitamin B12) |
Gastrointestinal absorption |
Oral |
In-vitro |
Non-imaging |
[edit] Cobalt-58
58Co is a gamma emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| Co58-Cyanocobalamin (vitamin B12) |
Gastrointestinal absorption |
Oral |
In-vitro |
Non-imaging |
[edit] Erbium-169
169Er is a beta emitter.
| Name |
Treatment of |
Route of administration |
| Er169-Colloid |
Arthritic conditions |
Intra-articular |
[edit] Fluorine-18
18F is a positron emitter with a half life of 109 minutes. It is produced in medical cyclotrons, usually from oxygen-18, and then chemically attached to a pharmaceutical. See PET scan.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| F18-FDG (Fluorodeoxyglucose) |
Tumor imaging
Myocardial imaging
|
IV |
In-vivo |
Imaging |
| F18-Fluoride |
Bone imaging |
IV |
In-vivo |
Imaging |
| F18-Fluorocholine |
Prostate tumor imaging |
IV |
In-vivo |
Imaging |
[edit] Gallium-67
67Ga is a gamma emitter. See gallium scan.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| Ga67-Ga3+ |
Tumor imaging |
IV |
In-vivo |
Imaging |
| Ga67-Ga3+ |
Infection/inflammation imaging |
IV |
In-vivo |
Imaging |
[edit] Gallium-68
68Ga is a positron emitter, with a 68 minute half life, produced by elution from germanium-68 in a gallium-68 generator. See also positron emission tomography.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| Ga68-Dotatoc or Dotatate |
Neuroendocrine tumor imaging |
IV |
In-vivo |
Imaging |
[edit] Hydrogen-3
3H or tritium is a beta emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| H3-water |
Total body water |
Oral or IV |
In-vitro |
Non-imaging |
[edit] Indium-111
111In is a gamma emitter.
[edit] Iodine-123
123I is a gamma emitter. It is used only diagnostically, as its radiation is penetrating and short-lived.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| I123-Iodide |
Thyroid uptake |
Oral or IV |
In-vivo |
Non-imaging |
| I123-Iodide |
Thyroid imaging
Thyroid metastases imaging
|
Oral or IV |
In-vivo |
Imaging |
| I123-o-Iodohippurate |
Renal imaging |
IV |
In-vivo |
Imaging |
| I123-MIBG (m-iodobenzylguanidine) |
Neuroectodermal tumour imaging |
IV |
In-vivo |
Imaging |
| I123-FP-CIT |
SPECT imaging of Parkinson's Disease |
IV |
In-vivo |
Imaging |
[edit] Iodine-125
125I is a gamma emitter with a long half-life of 59.4 days (the longest of all radioiodines used in medicine). Iodine-123 is preferred for imaging, so I-125 is used diagnostically only when the test requires a longer period to prepare the radiopharmaceutical and trace it, such as a fibrinogen scan to diagnose clotting. I-125's gamma radiation is of medium penetration, making it more useful as a therapeutic isotope for brachytherapy implant of radioisotope capsules for local treatment of cancers.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| I125-fibrinogen |
Clot imaging |
IV |
In-vivo |
Imaging |
[edit] Iodine-131
131I is a beta and gamma emitter. It is used both to destroy thyroid and thyroid cancer tissues (via beta radiation, which is short-range), and also other neuroendocrine tissues when used in MIBG. It can also be seen by a gamma camera, and can serve as a diagnostic imaging tracer, when treatment is also being attempted at the same time. However iodine-123 is usually preferred when only imaging is desired.
[edit] Diagnostic
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| I131-Iodide |
Thyroid uptake |
Oral |
In-vivo |
Non-imaging |
| I131-Iodide |
Thyroid metastases imaging |
Oral or IV |
In-vivo |
Imaging |
| I131-MIBG (m-iodobenzylguanidine) |
Neuroectodermal tumor imaging |
IV |
In-vivo |
Imaging |
[edit] Therapeutic
| Name |
Treatment of |
Route of administration |
| I131-Iodide |
Thyrotoxicosis |
IV or Oral |
| I131-Iodide |
Non-toxic goiter |
IV or Oral |
| I131-Iodide |
Thyroid carcinoma |
IV or Oral |
| I131-MIBG (m-iodobenzylguanidine) |
Malignant disease |
IV |
[edit] Iron-59
59Fe is a beta and gamma emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| Fe59-Fe2+ or Fe3+ |
Iron metabolism |
IV |
In-vitro |
Non-imaging |
[edit] Krypton-81m
81Krm is a gamma emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| Kr81m-Gas |
Lung ventilation imaging |
Inhalation |
In-vivo |
Imaging |
| Kr-81m-Aqueous solution |
Lung perfusion imaging |
IV |
In-vivo |
Imaging |
[edit] Nitrogen-13
13N is a positron emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| N13-Ammonia |
Myocardial blood flow imaging |
IV |
In-vivo |
Imaging |
[edit] Oxygen-15
15O is a positron emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| O15-Water |
Cerebral blood flow imaging
Myocardial blood flow imaging
|
IV bolus |
In-vivo |
Imaging |
[edit] Phosphorus-32
32P is a beta emitter.
| Name |
Treatment of |
Route of administration |
| P32-Phosphate |
Polycythemia and related disorders |
IV or Oral |
[edit] Rubidium-82
82Rb is a positron and gamma emitter.
| Name |
Treatment of |
Route of administration |
| Rb-82 Chloride |
Myocardial Imaging |
IV |
[edit] Samarium-153
153Sm is a beta and gamma emitter.
| Name |
Treatment of |
Route of administration |
| Sm153-EDTMP (Ethylenediaminotetramethylenephosphoric acid) |
Bone metastases |
IV |
[edit] Selenium-75
75Se is a gamma emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| Se75-Selenorcholesterol |
Adrenal gland imaging |
IV |
In-vivo |
Imaging |
| Se75-SeHCAT (23-Seleno-25-homo-tauro-cholate) |
Bile salt absorption |
Oral |
In-vivo |
Imaging |
[edit] Sodium-22
22Na is a positron and gamma emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| Na22-Na+ |
Electrolyte studies |
Oral or IV |
In-vitro |
Non-imaging |
[edit] Sodium-24
24Na is a beta and gamma emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| Na24-Na+ |
Electrolyte studies |
Oral or IV |
In-vitro |
Non-imaging |
[edit] Strontium-89
89Sr is a beta emitter.
| Name |
Treatment of |
Route of administration |
| Sr89-Chloride |
Bone metastases |
IV |
[edit] Technetium-99m
99mTc is a gamma emitter. It is obtained on-site at the imaging center as the soluble pertechnetate which is eluted from a technetium-99m generator, and then either used directly as this soluble salt, or else used to synthesize a number of technetium-99m-based radiopharmaceuticals.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| Tc99m-pertechnetate |
Thyroid uptake and thyroid imaging
Stomach and salivary gland imaging
Meckel's diverticulum imaging
Brain imaging
Micturating cystogram
First pass blood flow imaging
First pass peripheral vascular imaging
|
IV |
In-vivo |
Imaging |
| Tc99m-pertechnetate |
Lacrimal imaging |
Eye drops |
In-vivo |
Imaging |
| Tc99m-Human albumin |
Cardiac blood pool imaging |
IV |
In-vivo |
Imaging |
| Tc99m-Human albumin |
Peripheral vascular imaging |
IV |
In-vivo |
Imaging |
| Tc99m-Human albumin macroaggregates or microspheres |
Lung perfusion imaging |
IV |
In-vivo |
Imaging |
| Tc99m-Human albumin macroaggregates or microspheres |
Lung perfusion imaging with venography |
IV |
In-vivo |
Imaging |
| Tc99m-Phosphonates and phosphates |
Bone imaging |
IV |
In-vivo |
Imaging |
| Tc99m-Phosphonates and phosphates |
Myocardial imaging |
IV |
In-vivo |
Imaging |
| Tc99m-DTPA (diethylenetriaminepenta-acetic acid) |
Renal imaging
First pass blood flow studies
Brain imaging |
IV |
In-vivo |
Imaging |
| Tc99m-DTPA (diethylenetriaminepenta-acetic acid) |
Lung ventilation imaging |
Aerosol inhalation |
In-vivo |
Imaging |
| Tc99m-DMSA(V) (dimercaptosuccinic acid) |
Tumor imaging |
IV |
In-vivo |
Imaging |
| Tc99m-DMSA(III) (dimercaptosuccinic acid) |
Renal imaging |
IV |
In-vivo |
Imaging |
| Tc99m-Colloid |
Bone marrow imaging
GI Bleeding
|
IV |
In-vivo |
Imaging |
| Tc99m-Colloid |
Lymph node imaging |
Interstitial |
In-vivo |
Imaging |
| Tc99m-Colloid |
Esophageal transit and reflux imaging |
Oral |
In-vivo |
Imaging |
| Tc99m-Colloid |
Lacrimal imaging |
Eye drops |
In-vivo |
Imaging |
| Tc99m-HIDA (Hepatic iminodiacetic acid) |
Functional biliary system imaging |
IV |
In-vivo |
Imaging |
| Tc99m-Denatured red bood cells |
Red cell volume |
IV |
In-vitro |
Non-imaging |
| Tc99m-Red blood cells |
GI bleeding
Cardiac blood pool imaging
Peripheral vascular imaging
|
IV |
In-vivo |
Imaging |
| Tc99m-MAG3 (mercaptoacetyltriglycine) |
Renal imaging
First pass blood flow imaging
|
IV |
In-vivo |
Imaging |
| Tc99m-Exametazime |
Cerebral blood flow imaging |
IV |
In-vivo |
Imaging |
| Tc99m-Exametazime labelled leucocytes |
Infection/inflammation imaging |
IV |
In-vivo |
Imaging |
| Tc99m-Sestamibi (MIBI - methoxy isobutyl isonitrile) |
Parathyroid imaging
Non-specific tumor imaging
Thyroid tumor imaging
Breast imaging
Myocardial imaging
|
IV |
In-vivo |
Imaging |
| Tc99m-Sulesomab (IMMU-MN3 murine Fab'-SH antigranulocyte monoclonal antibody fragments) |
Infection/inflammation imaging |
IV |
In-vivo |
Imaging |
| Tc99m-Technegas |
Lung ventilation imaging |
Inhalation |
In-vivo |
Imaging |
| Tc99m-Human immunoglobulin |
Infection/inflammation imaging |
IV |
In-vivo |
Imaging |
| Tc99m-Tetrofosmin |
Parathyroid imaging
Myocardial imaging
|
IV |
In-vivo |
Imaging |
| Tc99m-ECD (ethyl cysteinate dimer) |
Brain imaging |
IV |
In-vivo |
Imaging |
[edit] Thallium-201
201Tl is a gamma emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| Tl201-Tl+ |
Non-specific tumor imaging
Thyroid tumor imaging
Myocardial imaging
Parathyroid imaging
|
IV |
In-vivo |
Imaging |
[edit] Xenon-133
133Xe is a gamma emitter.
| Name |
Investigation |
Route of administration |
In-vitro / in-vivo |
Imaging / non-imaging |
| Xe133-gas |
Lung ventilation studies |
Inhalation |
In-vivo |
Imaging |
| Xe133 in isotonic sodium chloride solution |
Cerebral blood flow |
IV |
In-vivo |
Imaging |
[edit] Yttrium-90
90Y is a beta emitter.
| Name |
Treatment of |
Route of administration |
| Y90-Silicate |
Arthritic conditions |
Intra-articular |
| Y90-Silicate |
Malignant disease |
Intracavitary |
[edit] See also
[edit] References
[edit] Reading
- Notes for guidance on the clinical administration of radiopharmaceuticals and use of sealed radioactive sources. Administration of radioactive substances advisory committee. March 2006. Produced by the Health Protection Agency.
- Malabsorption. In: The Merck Manual of Geriatrics, chapter 111.
- Leukoscan summary of product characteristics (Tc99m-Sulesomab).
- Schwochau, Klaus. Technetium. Wiley-VCH (2000). ISBN 3-527-29496-1
[edit] External links
