de Bauke Jong

Regional cerebral blood flow changes related to affective speech presentation in persistent vegetative state

A story told by his mother was presented on tape to a trauma patient in persistent vegetative state (PVS). During auditory presentation, measurements of regional cerebral blood flow (rCBF) were performed by means of positron emission tomography (PET). Changes in rCBF related to this stimulus condition, as compared to presenting non-word sound, were evaluated by means of statistical parametric mapping (SPM). This analysis indicated activation of rostral anterior cingulate, right middle temporal and right premotor cortices, which may reflect appropriate cortical involvement in processing emotional attributes of sound or speech.

Changes in striatal dopamine D2 receptor binding in pre‐clinical Huntington’s disease

Background:  Carriers of the Huntington disease (HD) mutation develop a progressive neurodegenerative disorder after a pre‐clinical phase. We examined the value of 11C‐raclopride PET (RAC) as a biomarker for pre‐clinical HD pathophysiology.

The distribution of cerebral activity related to visuomotor coordination indicating perceptual and executional specialization

The distribution of increased regional cerebral blood flow (rCBF) related to visuomotor coordination was studied by means of positron emission tomography (PET) in normal subjects. An experimental condition, in which a vertically presented zigzag figure had to be copied in a horizontal orientation, was compared with a control condition in which the same horizontal drawing was made, guided by a horizontally presented example. Cognitive components dealing with the mismatch in visual orientation resulted in activation of (i) right dorsal premotor cortex, (ii) right posterior parietal cortex, (iii) visual cortex (area V1) and (iv) left fusiform gyrus. In a second experiment, conditions were compared in which the same horizontal zigzag figure was copied in either a vertical or a horizontal orientation. Now, the motor components of the transformation of orientation appeared to be associated only with left premotor cortex activation. The differential distribution of activations is regarded to reflect the selective effort to cope with either the visual or the motor component of spatial incongruity, and indicates specialization for perceptual and executive components in visuomotor control. We propose that the perceptual component of visuomotor transformation in our experiment relates to a realignment of the coordinates of a percept to an internally defined coordinate system. The executive component relates to guidance of movement within an internal representation of space. In a preceding behavioural experiment, a majority of patients with Parkinsons disease (PD) failed on the task in which they had to make a horizontal copy of a vertically presented picture. This finding may suggest a deficit in the maintenance of an internal spatial representation to guide movement.

Cerebral activation related to implicit sequence learning in a Double Serial Reaction Time task

Using functional magnetic resonance imaging (fMRI), we examined the distribution of cerebral activations related to implicitly learning a series of fixed stimulus-response combinations. In a novel - bimanual - variant of the Serial Reaction Time task (SRT), simultaneous finger movements of the two hands were made in response to pairs of visual stimuli that were presented in a fixed order (Double SRT). Paired stimulus presentation prevented explicit sequence knowledge occurring during task practice, which implied that a dual task paradigm could be avoided. Extensive prescanning training on randomly ordered stimulus pairs allowed us to focus on the acquisition of implicit sequence knowledge. Activation specifically related to the acquisition of fixed sequence knowledge was highly significant in the right ventrolateral prefrontal cortex. The medial prefrontal and right ventral premotor cortex were more indirectly related with such procedural learning. We conclude that this set of activations reflects a stage of implicit sequence learning constituted by components of (i) spatial working memory (right ventral prefrontal cortex), (ii) response monitoring and selection (medial prefrontal cortex), and (iii) facilitated linkage of visuospatial cues to compatible responses (right ventral premotor). Comparing the random-order stimulus-response actions with fixed sequences showed activations in dorsal premotor and posterior parietal cortices, consistent with a dorsal pathway dominance in real-time visuomotor control. The relative long time during which performance improves in the DoSRT provides an opportunity for future study of various stages in both general skill and fixed sequence learning.

Functional dominance of finger flexion over extension, expressed in left parietal activation.

Sensory stimuli may elicit a widely distributed parietal-premotor circuitry underlying task-related movements such as grasping. These stimuli include the visual presentation of an object to be grasped, as well as the observation of grasping performed by others. In this study, we used functional Magnetic Resonance Imaging (fMRI) to test whether the performance of simple finger flexion, contrasted to extension, might similarly activate higher-order circuitry associated with grasping. Statistical Parametric Mapping (SPM) showed that flexion, compared to extension, was related with significant activation of the left posterior parietal cortex and posterior insula, bilaterally. This pattern supported our hypothesis that simple finger flexion has a specific relation with circuitry involved in preparing manual tasks. Although the two motor conditions showed major overlap in the primary motor cortex, increased flexion-related activation at the precentral motor-premotor junction further supported its association with higher-order motor control.

Iterative versus filtered backprojection reconstruction for statistical parametric mapping of PET activation measurements

The significance of task-induced cerebral blood flow responses, assessed using statistical parametric mapping, depends, among other things, on the signal-to-noise ratio (SNR) of these responses. Generally, positron emission tomography sinograms of H(2)(15)O activation studies are reconstructed using filtered backprojection (FBP). Alternatively, the acquired data can be reconstructed using an iterative reconstruction procedure. It has been demonstrated that the application of iterative reconstruction methods improves image SNR as compared with FBP. The aim of this study was to compare FBP with iterative reconstruction, to assess the statistical power of H(2)(15)O-PET activation studies using statistical parametric mapping. For this case study, PET data originating from a bimanual motor task were reconstructed using both FBP and maximum likelihood expectation maximization (ML-EM), an iterative algorithm. Both resulting data sets were statistically analyzed using statistical parametric mapping. It was found, with this dataset, that the statistical analysis of the iteratively reconstructed data confirm the a priori expected physiological response. In addition, increased Z scores were obtained in the iteratively reconstructed data. In particular, for the expected task-related response, activation of the posterior border of the left angular gyrus, the Z score increased from 3.00 to 3.96. Furthermore, the number of statistically significant clusters doubled while their volume increased by more than 50%. In conclusion, iterative reconstruction has the potential to increase the statistical power in H(2)(15)O-PET activation studies as compared with FBP reconstruction.