Joint explorative analysis of neuroreceptor subsystems in the human brain: application to receptor–transporter correlation using PET data

Positron emission tomography (PET) has proved to be a highly successful technique in the qualitative and quantitative exploration of the human brain's neurotransmitter-receptor systems. In recent years, the number of PET radioligands, targeted to different neuroreceptor systems of the human brain, has increased considerably. This development paves the way for a simultaneous analysis of different receptor systems and subsystems in the same individual. The detailed exploration of the versatility of neuroreceptor systems requires novel technical approaches, capable of operating on huge parametric image datasets. An initial step of such explorative data processing and analysis should be the development of novel exploratory data-mining tools to gain insight into the "structure" of complex multi-individual, multi-receptor data sets. For practical reasons, a possible and feasible starting point of multi-receptor research can be the analysis of the pre- and post-synaptic binding sites of the same neurotransmitter. In the present study, we propose an unsupervised, unbiased data-mining tool for this task and demonstrate its usefulness by using quantitative receptor maps, obtained with positron emission tomography, from five healthy subjects on (pre-synaptic) serotonin transporters (5-HTT or SERT) and (post-synaptic) 5-HT(1A) receptors. Major components of the proposed technique include the projection of the input receptor maps to a feature space, the quasi-clustering and classification of projected data (neighbourhood formation), trans-individual analysis of neighbourhood properties (trajectory analysis), and the back-projection of the results of trajectory analysis to normal space (creation of multi-receptor maps). The resulting multi-receptor maps suggest that complex relationships and tendencies in the relationship between pre- and post-synaptic transporter-receptor systems can be revealed and classified by using this method. As an example, we demonstrate the regional correlation of the serotonin transporter-receptor systems. These parameter-specific multi-receptor maps can usefully guide the researchers in their endeavour to formulate models of multi-receptor interactions and changes in the human brain.

[1]  T. Cunnane Non-synaptic Interactions Between Neurons: Modulation of Neurochemical Transmission by E. Sylvester Vizi, John Wiley & Sons, 1984. £22.50 (xiii + 260 pages) ISBN 0 471 90378 7 , 1985, Trends in Neurosciences.

[2]  Sylvain Houle,et al.  Synthesis and in vivo evaluation of novel radiotracers for the in vivo imaging of the norepinephrine transporter. , 2003, Nuclear medicine and biology.

[3]  K Wienhard,et al.  The ECAT EXACT HR: Performance of a New High Resolution Positron Scanner , 1994, Journal of computer assisted tomography.

[4]  Lars Farde,et al.  The advantage of using positron emission tomography in drug research , 1996, Trends in Neurosciences.

[5]  C. Halldin,et al.  Brain radioligands--state of the art and new trends. , 2001, The quarterly journal of nuclear medicine : official publication of the Italian Association of Nuclear Medicine (AIMN) [and] the International Association of Radiopharmacology.

[6]  K. Zilles,et al.  Human brain atlas: For high‐resolution functional and anatomical mapping , 1994, Human brain mapping.

[7]  F E Turkheimer,et al.  Modeling Dynamic PET-SPECT Studies in the Wavelet Domain , 2000, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[8]  B. Gulyás,et al.  PET studies with carbon-11 radioligands in neuropsychopharmacological drug development. , 2001, Current pharmaceutical design.

[9]  C. Halldin,et al.  [11C]MDL 100907, a radioligland for selective imaging of 5-HT(2A) receptors with positron emission tomography. , 1996, Life sciences.

[10]  Yuan-Hwa Chou,et al.  [11C]PE2I: a highly selective radioligand for PET examination of the dopamine transporter in monkey and human brain , 2003, European Journal of Nuclear Medicine and Molecular Imaging.

[11]  E. Vizi Presynaptic modulation of neurochemical transmission , 1979, Progress in Neurobiology.

[12]  L. Farde,et al.  PET analysis of human dopamine receptor subtypes using 11C-SCH 23390 and 11C-raclopride , 2004, Psychopharmacology.

[13]  E. Vizi,et al.  Modulatory role of presynaptic nicotinic receptors in synaptic and non-synaptic chemical communication in the central nervous system , 1999, Brain Research Reviews.

[14]  Lars Farde,et al.  Wavelet-Aided Parametric Mapping of Cerebral Dopamine D2 Receptors Using the High Affinity PET Radioligand [11C]FLB 457 , 2002, NeuroImage.

[15]  Glutamate uptake in synaptic plasticity: from mollusc to mammal. , 2002, Current molecular medicine.

[16]  Vizi Es Non-synaptic intercellular communication: presynaptic inhibition. , 1982 .

[17]  Bernd Fritzke,et al.  Growing cell structures--A self-organizing network for unsupervised and supervised learning , 1994, Neural Networks.

[18]  E. Vizi Role of high-affinity receptors and membrane transporters in nonsynaptic communication and drug action in the central nervous system. , 2000, Pharmacological reviews.

[19]  F. Bloom,et al.  The Biochemical Basis of Neuropharmacology , 1976 .

[20]  T. Greitz,et al.  Head fixation device for reproducible position alignment in transmission CT and positron emission tomography. , 1981, Journal of computer assisted tomography.

[21]  Bernd Fritzke,et al.  A Growing Neural Gas Network Learns Topologies , 1994, NIPS.

[22]  J Sandell,et al.  Use of PET and the radioligand [carbonyl-(11)C]WAY-100635 in psychotropic drug development. , 2000, Nuclear medicine and biology.

[23]  P. Molinoff,et al.  Basic Neurochemistry: Molecular, Cellular and Medical Aspects , 1989 .

[24]  S. Amara,et al.  Excitatory amino acid transporters: keeping up with glutamate , 2002, Neurochemistry International.

[25]  R. Blakely,et al.  Biogenic amine transporters: regulation in flux , 2000, Current Opinion in Neurobiology.

[26]  Y. Dunant,et al.  Low- and High-Affinity Reactions in Rapid Neurotransmission , 2003, Neurochemical Research.

[27]  J Sandell,et al.  Carbon-11-NNC 112: a radioligand for PET examination of striatal and neocortical D1-dopamine receptors. , 1998, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.