Imaging methods: their application to psychopharmacology
Ten years ago, neuroimaging was largely restricted to determining the localization of pathological lesions in the human brain. Due to the rapidadvances in magnetic resonance imaging (MRI) and related technologies,methods have now been developed to determine the precise functional importance of brain lesions, how cognitive operations are carried out within the brain and why they fail. MRI is an example of the technological development that is no longer restricted to the crude location of a brain lesion. The recently introduced analytical approach enables the size of the image structures in the MRI to bethe researcher to track major fibre bundles in white matter. Another important change has been the shift from positron emission tomography (PET) to MRI-based techniques for the indirect measurement of neuronal activity. Nevertheless, PET and single photon emission computed tomography (SPECT) remain the only viable techniques for studying ligand binding in the human brain and the increasing resolution of PET is constantly improving as new detectors are developed. Recently, new radiotracers have enabled signal transduction mechanisms and gene expression to be evaluated in the human brain. Specific molecules can now be determined in the human brain by means of magnetic resonance spectroscopy (MRS). Such methods have enabled the glutamate–GABA system to be assessed during neuronal activation and have shown how this pathway is defective in depression and altered by pharmacological treatments. Unlike most of the techniques described here, MRS is also applicable to analysing changes in energy metabolism and the glutamate/GABA pathway in the rat brain. Undoubtedly, one of the most important advances has been in functional magnetic resonance imaging (fMRI), which enables the researcher to distinguish between the encoding and retrieval phases of memory. An additional application of the fMRI technique in the study of mood and emotion has revealed that the systems involved are widely distributed throughout the brain. However, despite these improvements it will never be possible using fMRI to approach the accuracy of event-related potential (ERP) methods which can quantify events occurring over milliseconds. ERP methods have now been combined with fMRI so that it is possible, for example, to measure signals that occur in visual tasks when they arrive at the cortex, how the signals are modulated by attention and how they are decoded into semantic information. Once these intricate processes have been elucidated in normal behaviour, it should be possible to apply them to specific psychiatric disorders such as schizophrenia where there appears to be a major deficit in the processing of visual stimuli.Finally, it has now become possible to use imaging methods to study the functional interaction between different brain regions. This has been made possible by the development of effective connectivity mapping which is based on moment-to-moment relationships between fMRI signals in different brain regions to create equations which enable the contribution of the activity of one brain region with another to be quantified. Another approach has been to combine fMRI with transcranial magnetic stimulation (TMS). In this technique, areas of the brain are directly stimulated by magnetic currents and the resulting changes in brain regions quantified by fMRI. To date, these techniques have been applied almost entirely to man. Over the next decade it will be equally important to further refine them so they may become applicable to the brains of experimental animals, particularly rodents. So far it has only been possible to determine gross structural changes in the rat, for example, using MRI. Some examples of the application of new imaging methods to psychopharmacology
Ten years ago, neuroimaging was largely restricted to determining the localization of pathological lesions in the human brain. Due to the rapidadvances in magnetic resonance imaging (MRI) and related technologies,methods have now been developed to determine the precise functional importance of brain lesions, how cognitive operations are carried out within the brain and why they fail. MRI is an example of the technological development that is no longer restricted to the crude location of a brain lesion. The recently introduced analytical approach enables the size of the image structures in the MRI to bethe researcher to track major fibre bundles in white matter. Another important change has been the shift from positron emission tomography (PET) to MRI-based techniques for the indirect measurement of neuronal activity. Nevertheless, PET and single photon emission computed tomography (SPECT) remain the only viable techniques for studying ligand binding in the human brain and the increasing resolution of PET is constantly improving as new detectors are developed. Recently, new radiotracers have enabled signal transduction mechanisms and gene expression to be evaluated in the human brain. Specific molecules can now be determined in the human brain by means of magnetic resonance spectroscopy (MRS). Such methods have enabled the glutamate–GABA system to be assessed during neuronal activation and have shown how this pathway is defective in depression and altered by pharmacological treatments. Unlike most of the techniques described here, MRS is also applicable to analysing changes in energy metabolism and the glutamate/GABA pathway in the rat brain. Undoubtedly, one of the most important advances has been in functional magnetic resonance imaging (fMRI), which enables the researcher to distinguish between the encoding and retrieval phases of memory. An additional application of the fMRI technique in the study of mood and emotion has revealed that the systems involved are widely distributed throughout the brain. However, despite these improvements it will never be possible using fMRI to approach the accuracy of event-related potential (ERP) methods which can quantify events occurring over milliseconds. ERP methods have now been combined with fMRI so that it is possible, for example, to measure signals that occur in visual tasks when they arrive at the cortex, how the signals are modulated by attention and how they are decoded into semantic information. Once these intricate processes have been elucidated in normal behaviour, it should be possible to apply them to specific psychiatric disorders such as schizophrenia where there appears to be a major deficit in the processing of visual stimuli.Finally, it has now become possible to use imaging methods to study the functional interaction between different brain regions. This has been made possible by the development of effective connectivity mapping which is based on moment-to-moment relationships between fMRI signals in different brain regions to create equations which enable the contribution of the activity of one brain region with another to be quantified. Another approach has been to combine fMRI with transcranial magnetic stimulation (TMS). In this technique, areas of the brain are directly stimulated by magnetic currents and the resulting changes in brain regions quantified by fMRI. To date, these techniques have been applied almost entirely to man. Over the next decade it will be equally important to further refine them so they may become applicable to the brains of experimental animals, particularly rodents. So far it has only been possible to determine gross structural changes in the rat, for example, using MRI. Some examples of the application of new imaging methods to psychopharmacology
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