[en] In principle, PET in combination with amino acids labelled with positron-emitting radionuclides and kinetic metabolic models, can quantify local protein synthesis rates in tissue in vivo. These PET measurements have clinical potential in, for example, oncology, neurology and psychiatry. An optimal positron-emitting amino acid for the measurement of PSR has a high protein incorporation, can easily be prepared by automated equipment and has minimal non-protein radioactive metabolites. Presently L-[methyl-11C]methionine, L-[1-11C]leucine, L-[1-11C]tyrosine, L-[1-11C]phenylalanine, L-[1-11C]methionine and L-[2-18F]fluorotyrosine are under evaluation in normal volunteers and/or in patients. Several other amino acids are suggested. No comparison of the clinical usefulness of the different amino acids in man is yet available. Because of the longer half life of 18F compared to 11C, [18F]fluoro amino acids may have advantages over [11C]amino acids for the investigation of tissue with relative slow protein synthesis, such as brain, and for application in institutions with an off site, but nearby cyclotron. The half life of [13N]amino acids is considered to be too short for flexible clinical application. As yet no metabolic compartmental model has been investigated for [13N]amino acids. For routine application reliable preparation of the radiopharmaceutical is essential. Of all the amino acids under evaluation, a reliable, high yield, easy to automate production procedure is available for L-[methyl-11C]methionine only. It is however unlikely that this tracer can accurately measure PSR because of its non-protein metabolism. For the other amino acids the main problems in production are associated with complex multistep syntheses and/or low radiochemical yields, complex purification methods and the need to isolate the L-enantiomer. The kinetic metabolic models under investigation, consist of 4 or 5 compartments depending on the necessity to compensate for labelled metabolites. The metabolic profile of the amino acids is mainly extracted from animal experiments. Because of the number and amount of labelled metabolites in plasma, [11C]carboxylic labelled amino acids are preferred to amino acids with carbon-11 in another position. As yet no recommendation can be given on the optimal labelled amino acid(s) for PSR measurement in vivo nor on the methods to prepare the amino acids reported for this purpose.
Disciplines :
Chemistry
Author, co-author :
Vaalburg, W.
Coenen, H. H.
Crouzel, C.
Elsinga, P. H.
Langstrom, B.
Lemaire, Christian ; Université de Liège - ULiège > Centre de recherches du cyclotron
Meyer, Gilles ; Université de Liège - ULiège > Dép. d'électric., électron. et informat. (Inst.Montefiore) > Systèmes et modélisation
Language :
English
Title :
Amino acids for the measurement of protein synthesis in vivo by PET.
Publication date :
1992
Journal title :
International Journal of Radiation Applications and Instrumentation. Part B, Nuclear Medicine and Biology
Atkins, Christman, Fowler, Hauser, Hoyte, Klopper, Liu, Wolf (1972) Organic radiopharmaceuticals labelled with isotopes of short half-life. V. 18F-labelled 5- and 6-fluorotryptophan. J Nucl Med 13:713-719.
Barrio, Keen, Chugani, Ackerman, Chugani, Phelps (1983) L-[11C]Phenylalanine for the determination of cerebral protein synthesis rates in man with positron emission tomography. J. Nucl. Med. 24:P70.
Barrio, Keen, Ropchan, MacDonald, Baumgartner, Padgett, Phelps (1983) L-[l-11C]Leucine: routine synthesis by enzymatic resolution. J Nucl Med 24:515-521.
Bergström, Ericson, Hagenfeldt, Mosskin, von Holst, Norin, Eriksson, Ehrin, Johnström (1987) PET study of methionine accumulation in glioma and normal brain tissue competition with branched chain amino acids. Journal of Computer Assisted Tomography 11:208-213.
Bjurling, Antoni, Watanabe, Langstrom (1990) Enzymatic synthesis of carboxyl-11C-labelled l-tyrosine, L-DOPA, L-trytophan and 5-hydroxy-L-trytophan. Acta Chemica Scandinavica 44:178-182.
Bodsch, Takahashi, Grosse Ophoff, Hossmann (1985) Local Rates of Cerebral Protein Synthesis in the Gerbil and Monkey Brain. J. Cereb. Bld Flow Metab. , A. Hartmann, S. Hoyer, Springer, Heidelberg; 481-486.
Bodsch, Coenen, Stocklin, Takahashi, Hossmann (1988) Biochemical and autoradiographic study of cerebral protein synthesis with 18F- and 14C-fluorophenylalanine. Journal of Neurochemistry 50:979-983.
Bolster, ten Hoeve, Vaalburg, van Dijk, Zijlstra, Paans, Wijnberg, Woldring (1985) The preparation of carbon-11 labelled proline for positron emission tomography Preliminary distribution studies in rats with Walker 256 carcinosarcoma. The International Journal of Applied Radiation and Isotopes 36:339-343.
Bolster, Vaalburg, van Dijk, Zijlstra, Paans, Wijnberg, Woldring (1985) Synthesis of carbon-11 labelled ornithine and lysine Preliminary accumulation studies in rats with Walker 256 carcinosarcoma. The International Journal of Applied Radiation and Isotopes 36:263-267.
Bolster, Vaalburg, Elsinga, Wijnberg, Woldring (1986) Synthesis of DL-[1-11C]methionine. International Journal of Radiation Applications and Instrumentation. Part A. Applied Radiation and Isotopes 37:1069-1070.
Bolster, Vaalburg, Paans, van Dijk, Elsinga, Zijlstra, Piers, Mulder, Woldring, Wijnberg (1986) Carbon-11 labelled tyrosine to study tumor metabolism by Positron Emission Tomography (PET). European Journal of Nuclear Medicine 12:321-324.
Bustany, Henry, de Rotrou, Signoret, Cabanis, Zarifan, Ziegler, Derlon, Crouzel, Soussaline, Comar (1985) Correlation between clinical state and positron emission tomography measurement of local brain synthesis in Alzheimer's dementia, Parkinson's disease, Schizophrenia and gliomas. The Metabolism of the Human Brain Studied with Positron Emission Tomography , T. Greitz, D.H. Ingvar, L. Widen, Raven Press, New York; 241-249.
Casey, Digenis, Wesner, Washburn, Chaney, Hayes, Callahan (1981) Preparation and preliminary tissue studies of optically active d-, and L-[11C]phenylalanine. The International Journal of Applied Radiation and Isotopes 32:1291-1300.
Choi, Pardridge (1986) Phenylalanine transport at the human blood-brain barrier. J Biol Chem 261:6536-6541.
Coenen, Stocklin (1988) Evaluation of radiohalogenated amino acid analogues as potential tracers for PET and SPECT studies of protein synthesis. Radioisot. Klinik. Forschung. 18:402-440.
Coenen, Kling, Stocklin (1989) Cerebral metabolism of L-[2-18F]fluorotyrosine, a new PET tracer of protein synthesis. J Nucl Med 30:1367-1372.
Coenen, Franken, Kling, Stocklin (1988) Direct electrophilic radiofluorination of phenylalanine tyrosine and dopa. International Journal of Radiation Applications and Instrumentation. Part A. Applied Radiation and Isotopes 39:1243-1250.
Coenen, Bodsch, Takahashi, Hossmann, Stocklin (1986) Synthesis, autoradiography and biochemistry of L-[18F]fluorophenylalanines for probing protein synthesis. Nuklearmedizin , (Suppl.); 22:600.
Coenen, Franken, Metwally, Stocklin (1986) Electrophilic radiofluorination of aromatic compounds with [18F]2 and [18F]CH3CO2F and regioselective preparation of L-p-[18F]fluorophenylalanine. J. Labelled Cmpd. Radiopharm. 23:1179-1181.
Coenen, Wutz, Stocklin, DeGrado, Kling (1990) Pharmacokinetics and metabolism of L-[2-18F]fluorotyrosine in the brain and periphery of mice. J. Nucl. Med. , (Abstract); 31:716.
Comar, Cartron, Mazière, Marazano (1976) Labelling and metabolism of methionine-methyl-11C. European Journal of Nuclear Medicine 1:11-14.
Crouzel, Langstrom, Pike, Coenen (1987) Recommendations for a practical production of [11C]methyl iodide. International Journal of Radiation Applications and Instrumentation. Part A. Applied Radiation and Isotopes 38:601-603.
Diamondstone (1982) Amino acid metabolism II. Metabolism of the individual amino acids. Textbook of Biochemistry with Clinical Correlations , T.M. Derlin, New York; 563-626.
Fowden (1972) Fluoroamino acids and protein synthesis. Ciba Foundation Symposium, Carbon-Fluorine Compounds , North Holland, Ansterdam; 141-159.
Glasser, Maher, Wurtman (1983) Changes in brain levels of acidic basic and neural amino acids after consumption of single meals containing various proportions of protein. Journal of Neurochemistry 41:1016-1021.
Goulding, Palmer (1972) The preparation of fluorine-18 labelled p-fluorophenylalanine for clinical use. The International Journal of Applied Radiation and Isotopes 23:133-138.
Gübitz, Jellenz, Santi (1981) Separation of the optical isomers of amino acids by ligand exchange chromatography using chemically bonded chiral phases. Journal of Chromatography A 203:377-384.
Halldin, Schoeps, Stone-Elander, Wiesel (1987) The Bücherer-Strecker synthesis of d- and L-[l-11C]tyrosine and the in vivo study of L-[l-11C]tyrosine in human brain using positron emission tomography. European Journal of Nuclear Medicine 13:288-291.
Hawkins, Huang, Barrio, Keen, Feng, Maziotta, Phelps (1989) Estimation of local cerebral protein synthesis rates with L-[l-11C]leucine and PET: methods, model and results in animals and humans. Journal of Cerebral Blood Flow & Metabolism 9:446-460.
Heiss, Coenen, Wienhard, Herholz, Rudolf, Kling, Stocklin (1990) L-[2-18F]Fluorotyrosine uptake in gliomas studied by dynamic PET. J. Nucl. Med. , (Abstract); 31:799.
Hoyte, Liu, Christman, Atkins, Hauser, Wolf (1971) Organic radiopharmaceuticals labelled with short-lived nuclides. III. 18F-labelled phenylalanines. J Nucl Med 12:280.
Ishiwata, Ido, Vaalburg (1988) Increased amounts of D-enantiomer dependant on alkaline concentrations in the synthesis of L-[methyl-11C]methionine. International Journal of Radiation Applications and Instrumentation. Part A. Applied Radiation and Isotopes 39:311-314.
Ishiwata, Vaalburg, Elsinga, Paans, Woldring (1988) Metabolic studies with L-[l-14C]tyrosine for the investigation of a kinetic model to measure protein synthesis rates with PET. J Nucl Med 29:524-529.
Ishiwata, Vaalburg, Elsinga, Paans, Woldring (1988) Comparison of L-[l-11C]methionine and L-methyl-[11C]methionine for measuring in vivo protein synthesis rates with PET. J Nucl Med 29:1419-1427.
Ishiwata, Vaalburg, Paans, Elsinga, Vissering, Woldring (1986) A comparison of L-[l-11C]tyrosine, L-[l-11C]methionine and L-[S-methyl-11C]methionine for measuring protein synthesis rates in tumors with PET. Clinical Demands in Nuclear Medicine, Proc. European Nuclear Medicine Congress, Goslar , Schattauer, Stuttgart; 37-40.
Ishiwata, Hatazawa, Kubota, Kameyana, Itoh, Matsuzawa, Takahashi, Iwata, Ido (1989) Metabolic fate of L-[methyl-11C]methionine in human plasma. European Journal of Nuclear Medicine 15:665-669.
Keen, Barrio, Huang, Hawkins, Phelps (1989) In vivo cerebral protein synthesis rates with leucyl-transfer RNA used as a precursor pool determination of biochemical parameters to structure tracer kinetic models for positron emission tomography. Journal of Cerebral Blood Flow & Metabolism 9:429-443.
Kirikae, Diksic, Yamamoto (1989) Quantitative measurement of regional glucose utilization and rate of valine incorporation into proteins by double-tracer autoradiography in the rat brain tumor model. Journal of Cerebral Blood Flow & Metabolism 9:87-95.
Lajtha (1974) Amino acid transport in the brain in vivo and in vitro. Aromatic Amino Acid in the Brain. Ciba Found. Symp. 22:25-41.
Langstrom, Antoni, Gulberg, Halldin, Malmborg, Någren, Rimland, Svärd (1987) Synthesis of L and D-[methyl-11C]methionine. J Nucl Med 28:1037-1040.
Lemaire, Guillaume, Christiaens, Palmer, Cantineau (1987) A new route for the synthesis of fluorine-18 fluoro aromatic substituted amino acids no carrier added fluorine-18 L-p-fluorophenylalanine. International Journal of Radiation Applications and Instrumentation. Part A. Applied Radiation and Isotopes 38:1033-1038.
Lundqvist, Stålnacke, Långström, Jones (1985) Labelled metabolites in plasma after intravenous administration of [11CH3]-L-methionine. The Metabolism of the Human Brain Studied with Positron Emission Tomography, T.V.B. Greitz, D.H. Ingvar, L. Widen, Raven Press, New York; .
Metwally, Coenen, Stocklin (1987) Protection of functional groups and stannylation of phenylalanine. Bulletin of the Chemical Society of Japan 60:4437-4440.
Mineura, Kowada, Shishido (1989) Brain tumor imaging with synthesized 18F-fluorophenylalanine and positron emission tomography. Surgical Neurology 31:468-469.
Momma, Aoyagi, Rapoport, Smith (1987) Phenylalanine transport across the blood-brain as studied with the in situ brain perfusion technique. Journal of Neurochemistry 48:1291-1300.
Murakami, Takahashi, Kondo, Mizusawa, Nakamichi, Sasaki, Hagami, Iida, Kanno, Miura, Itoh, Uemura (1989) The slow metabolism of L-[2-18F]fluorophenylalanine in rat. Journal of Labelled Compounds and Radiopharmaceuticals 27:245-255.
Obrecht, Hermann, Ugi Isocyanide synthesis with phosphoryl chloride and diisopropylamine, Synthesis 1985, 400-402.
Oldendorf (1971) Brain uptake of radiolabelled amino acids amines and hexoses after arterial injection. Am J Physiol 221:1629-1639.
Oldendorf, Szabo (1976) Amino acid assignment to one of three blood-brain barrier amino acid carriers. Am. J. Physiol. 220:94-98.
O'Tuama, Guilarté, Douglass, Wagner, Wong, Dannals, Ravert, Wilson, La France, Bice, Links (1988) Assessment of [11C]L-methionine transport into the human brain. Journal of Cerebral Blood Flow & Metabolism 8:341-345.
Paans, Daemen, Elsinga, Vaalburg (1989) Determination of the in vivo protein synthesis rate using dynamic PET data from L-[l-11C]tyrosine in an animal model te]Nuclear Medicine; Quantitative Analysis in Imaging and Function. Proc. European Nuclear Medicine Congress , Strasbourg, Schattauer, Stuttgart; 30-33.
Palmer, Clark, Goulding (1977) The preparation of fluorine-18 labelled radiopharmaceuticals. The International Journal of Applied Radiation and Isotopes 28:53.
Phelps, Barrio, Huang, Keen, Chugani, Maziotta (1984) Criteria for the tracer kinetic measurement of cerebral protein synthesis in humans with positron emission tomography. Annals of Neurology , (Suppl.); 15:S192-S202.
Phelps, Barrio, Huang, Keen, Chugani, Maziotta (1985) Measurement of cerebral protein synthesis in man with positron computerized tomography: model, assumption and preliminary results. The Metabolism of Human Brain Studied with Positron Emission Tomography , T. Greiz, D.H. Ingvar, L. Widen, Raven Press, New York; 215-232.
Pollay (1978) Regional transport of phenylalanine across the blood-brain barrier. Journal of Neuroscience Research 2:11-19.
Reiman, Rosen, Gelbard, Benna, Laughlin (1982) Imaging of primary ewing sarcoma with 13N-L-glutamate. Radiology 192:495-500.
Robins (1966) Preparation and properties of p-hydroxyphenylacetaldehyde and 3-methoxy-4-hydroxyphenylacetaldehyde. Archives of Biochemistry and Biophysics 114:576-584.
Smith, Davidsen, Deibler, Patlak, Petigrew, Sokoloff (1980) A method for the determination of local rates of protein synthesis in brain. Trans. Am. Soc. Neurochem. 11:94.
Sokoloff, Smith (1983) Biochemical principles for the measurement of metabolic rates in vivo. Positron Emission Tomography of the Brain , W.D. Heiss, M.E. Phelps, Springer, New York; 2-18.
Vaalburg, Beerling-van der Molen, Reiffers, Rijskamp, Woldring, Wijnberg (1976) Preparation of carbon-11 labelled phenylalanine and phenylglycine by a new amino acid synthesis. The International Journal of Applied Radiation and Isotopes 27:153-157.
Vahvelainen, Oja (1972) Kinetics of influx of phenylalanine tyrosine tryptophan histidine and leucine into slices of brain cortex from adult and 7-day-old rats. Brain Research 40:477-488.
Vahvelainen, Oja (1975) Kinetic analysis of phenylalanine-induced inhibition in the saturable influx of tyrosine tryptophan leucine and histidine into brain cortex slices from adult and 7-day-old rats. Journal of Neurochemistry 24:885-892.
Westhead, Boyer (1961) The incorporation of p-fluorophenylalanine into some rabbit enzymes and other proteins. Biochimica et Biophysica Acta 54:145-156.
Weygand, Oettmeier (1970) Fluorine-containing amino acids. Russian Chemical Reviews 39:290-300.
Young (1982) The significance of tryptophan, phenylalanine tyrosine, and their metabolites in the nervous system. Handbook of Neurochemistry , A. Lajtha, Plenum Press, New York; 3:559-581.
