In vivo quantification of localized neuronal activation and inhibition in the rat brain using a dedicated high temporal-resolution β+-sensitive microprobe

Understanding brain disorders, the neural processes implicated in cognitive functions and their alterations in neurodegenerative pathologies, or testing new therapies for these diseases would benefit greatly from combined use of an increasing number of rodent models and neuroimaging methods specifically adapted to the rodent brain. Besides magnetic resonance (MR) imaging and functional MR, positron-emission tomography (PET) remains a unique methodology to study in vivo brain processes. However, current high spatial-resolution tomographs suffer from several technical limitations such as high cost, low sensitivity, and the need of restraining the animal during image acquisition. We have developed a β+-sensitive high temporal-resolution system that overcomes these problems and allows the in vivo quantification of cerebral biochemical processes in rodents. This β-MICROPROBE is an in situ technique involving the insertion of a fine probe into brain tissue in a way very similar to that used for microdialysis and cell electrode recordings. In this respect, it provides information on molecular interactions and pathways, which is complementary to that produced by these technologies as well as other modalities such as MR or fluorescence imaging. This study describes two experiments that provide a proof of concept to substantiate the potential of this technique and demonstrate the feasibility of quantifying brain activation or metabolic depression in individual living rats with 2-[18F]fluoro-2-deoxy-d-glucose and standard compartmental modeling techniques. Furthermore, it was possible to identify correctly the origin of variations in glucose consumption at the hexokinase level, which demonstrate the strength of the method and its adequacy for in vivo quantitative metabolic studies in small animals.

[1]  Yiping Shao,et al.  PET and NMR dual acquisition (PANDA): applications to isolated, perfused rat hearts , 1997, NMR in biomedicine.

[2]  M. West Anesthetics Eliminate Somatosensory-Evoked Discharges of Neurons in the Somatotopically Organized Sensorimotor Striatum of the Rat , 1998, The Journal of Neuroscience.

[3]  A. P. Jeavons,et al.  A 3D HIDAC-PET camera with sub-millimetre resolution for imaging small animals , 1998 .

[4]  J. Mazziotta,et al.  Positron emission tomography and autoradiography: Principles and applications for the brain and heart , 1985 .

[5]  G. Bonvento,et al.  Local Uncoupling of the Cerebrovascular and Metabolic Responses to Somatosensory Stimulation after Neuronal Nitric Oxide Synthase Inhibition , 1997, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[6]  André Luxen,et al.  Effect of endogenous serotonin on the binding of the 5‐HT1A PET ligand 18F‐MPPF in the rat hippocampus: kinetic β measurements combined with microdialysis , 2002, Journal of neurochemistry.

[7]  G. Paxinos,et al.  The Rat Brain in Stereotaxic Coordinates , 1983 .

[8]  H. Atkins,et al.  Pinhole SPECT: an approach to in vivo high resolution SPECT imaging in small laboratory animals. , 1994, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[9]  U. Ungerstedt,et al.  Effects of halothane anaesthesia on extracellular levels of dopamine, dihydroxyphenylacetic acid, homovanillic acid and 5-hydroxyindolacetic acid in rat striatum: a microdialysis study , 1990, Naunyn-Schmiedeberg's Archives of Pharmacology.

[10]  A. Guerra,et al.  Image noise properties of a phosphor-coated CCD X-ray detector , 1998 .

[11]  Arion F. Chatziioannou,et al.  Molecular imaging of small animals with dedicated PET tomographs , 2001, European Journal of Nuclear Medicine and Molecular Imaging.

[12]  A. Miller,et al.  Loss of radioactive 2-deoxy-d-glucose-6-phosphate from brains of conscious rats: Implications for quantitative autoradiographic determination of regional glucose utilization , 1978, Neuroscience.

[13]  E. Hoffman,et al.  Tomographic measurement of local cerebral glucose metabolic rate in humans with (F‐18)2‐fluoro‐2‐deoxy‐D‐glucose: Validation of method , 1979, Annals of neurology.

[14]  N. Harada,et al.  Is synaptic dopamine concentration the exclusive factor which alters the in vivo binding of [ 11 C ]raclopride?: PET studies combined with microdialysis in conscious monkeys , 1999, Brain Research.

[15]  L. Sokoloff,et al.  Effects of anesthesia on functional activation of cerebral blood flow and metabolism , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[16]  SIC, an Intracerebral β+-Range–Sensitive Probe for Radiopharmacology Investigations in Small Laboratory Animals: Binding Studies with 11C-Raclopride , 2002 .

[17]  Roger Lecomte,et al.  Initial results from the Sherbrooke avalanche photodiode positron tomograph , 1996 .

[18]  W C Eckelman,et al.  Kinetic Modeling of [11C]Raclopride: Combined PET-Microdialysis Studies , 1997, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[19]  M. Nader,et al.  PET Imaging of Dopamine D2 Receptors with [18F]Fluoroclebopride in Monkeys: Effects of Isoflurane- and Ketamine-Induced Anesthesia , 1999, Neuropsychopharmacology.

[20]  M. Reivich,et al.  THE [14C]DEOXYGLUCOSE METHOD FOR THE MEASUREMENT OF LOCAL CEREBRAL GLUCOSE UTILIZATION: THEORY, PROCEDURE, AND NORMAL VALUES IN THE CONSCIOUS AND ANESTHETIZED ALBINO RAT 1 , 1977, Journal of neurochemistry.

[21]  J. Mazziotta,et al.  Positron emission tomography and autoradiography , 1985 .

[22]  A. Tobin,et al.  Metabolic Compromise with Systemic 3-Nitropropionic Acid Produces Striatal Apoptosis in Sprague–Dawley Rats but Not in BALB/c ByJ Mice , 1998, Experimental Neurology.

[23]  S. Cherry,et al.  Performance evaluation of microPET: a high-resolution lutetium oxyorthosilicate PET scanner for animal imaging. , 1999, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[24]  Yves Charon,et al.  SIC, an intracerebral radiosensitive probe for in vivo neuropharmacology investigations in small laboratory animals: theoretical considerations and practical characteristics , 2000 .

[25]  Magdalena Rafecas,et al.  A prototype high-resolution animal positron tomograph with avalanche photodiode arrays and LSO crystals , 2001, European Journal of Nuclear Medicine.

[26]  John H. Krystal,et al.  Positron emission tomography and autoradiography: Principles and applications for the brain and heart , 1985 .

[27]  Nobuko Mataga,et al.  Ketamine increases the striatal N-[11C]methylspiperone binding in vivo: positron emission tomography study using conscious rhesus monkey , 1994, Brain Research.

[28]  S R Cherry,et al.  Quantitative Assessment of Longitudinal Metabolic Changes In Vivo after Traumatic Brain Injury in the Adult Rat using FDG-MicroPET , 2000, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[29]  Jacques Seylaz,et al.  Sustained attenuation of the cerebrovascular response to a 10 min whisker stimulation following neuronal nitric oxide synthase inhibition , 2000, Neuroscience Research.

[30]  F. Condé,et al.  Partial Inhibition of Brain Succinate Dehydrogenase by 3‐Nitropropionic Acid Is Sufficient to Initiate Striatal Degeneration in Rat , 1998, Journal of neurochemistry.

[31]  Yves Charon,et al.  An original emission tomograph for in vivo brain imaging of small animals , 1996 .

[32]  M. Ueki,et al.  Effect of alpha‐chloralose, halothane, pentobarbital and nitrous oxide anesthesia on metabolic coupling in somatosensory cortex of rat , 1992, Acta anaesthesiologica Scandinavica.