Transient haemodynamic events in neurologically compromised infants: a simultaneous EEG and diffuse optical imaging study.

We describe a series of novel simultaneous EEG and diffuse optical imaging studies of newborn infants. These experiments provide evidence of large, transient haemodynamic events which occur repeatedly and consistently within and across several infants with neurological damage, all of whom were diagnosed with seizures. A simple but independent process of rejecting artifacts and identifying events within diffuse optical imaging data is described, and this process is applied to data from 4 neurologically damaged neonates and from 19 healthy, age-matched controls. This method results in the consistent identification of events in three out of four of the neurologically damaged infant group which are dominated by a slow (>30s) and significant increase in oxyhaemoglobin concentration, followed by a rapid and significant decrease before a slow return to baseline. No comparable events are found in any of our control data sets. The importance and physiological implications of our findings are discussed, as is the suitability of a combined EEG and diffuse optical imaging approach to the study and monitoring of neonatal brain injury.

Hand tapping: a simple, reproducible, objective marker of motor dysfunction in Huntington's disease.

Huntington's disease (HD) is a severe neurodegenerative condition in which the impairment in voluntary movement is related to functional disability. Clinical assessment of motor deficit currently relies largely on subjective rating scales without objective measurement. We have developed a quick and easy-to-use hand tapping device that enables measurement of (a) the number of taps in 30 seconds, (b) variability in tapping rhythm and (c) fatigue over the testing period. Initial cross-sectional testing of 178 consecutive HD clinic patients using an early model of the device showed that the total number of taps in 30 seconds correlated with the motor UHDRS (Spearmann's rho, r(s) = -0.81, p < 0.0001) and independence scores (r(s) = 0.78, p = 0.01). Longitudinal data from a small cohort followed over 10 years reveals a correlation between total number of taps in 30 seconds and motor UHDRS over time (rs = -0.49, p < 0.001), and suggests the technique may provide an objective measure of disease progression. Further tests on 15 HD patients and 9 controls were repeated three times in a single day using an updated device. The HD group made significantly fewer taps in 30 seconds (median HD = 79, control = 104, p = 0.009) and had greater variability of inter-tap interval (mean interdecile range HD = 148, control = 56, p = 0.016) compared to controls. Both the total number of taps and variability of inter-tap interval correlated with motor UHDRS. Of vital importance for any potential marker of disease progression is that these tapping parameters were reproducible with repeated measurement. Given that hand tapping parameters differ between HD and control populations, they correlate with motor UHDRS over time and are reproducible, we propose that assessment of hand tapping represents a useful objective adjunct to the clinical assessment of HD patients.

The effect of truncated human alpha-synuclein (1-120) on dopaminergic cells in a transgenic mouse model of Parkinson's disease.

Alpha-Synuclein is thought to play an important role in the pathology of Parkinson's disease (PD). Truncated forms of this protein can be found in PD brain extracts, and these species aggregate faster and are more susceptible to oxidative stress than the full-length protein. We investigated the effect of truncated alpha-synuclein on dopaminergic cells using a transgenic mouse expressing alpha-synuclein (1-120) driven by the rat tyrosine hydroxylase promoter on a mouse alpha-synuclein null background. We found a selective reduction in the yield of dopaminergic cells from transgenic embryonic ventral mesencephalic cell cultures. However, in vivo the substantia nigra/ventral tegmentum dopaminergic cell counts were not reduced in transgenics, although these mice are known to have reduced striatal dopamine. When transplanted to the striatum in the unilateral 6-hydroxydopamine-lesioned mouse model of PD, dopaminergic cells derived from transgenic embryonic ventral mesencephala were significantly smaller at 6 weeks, and showed a trend towards being less effective at ameliorating rotational asymmetry than those from control alpha-synuclein null mice. These results suggest that alpha-synuclein (1-120) renders dopaminergic cells more susceptible to stress, which may have important implications as to how this truncated protein might contribute to dopaminergic cell death in sporadic PD.

Saccadic latency distributions in Parkinson's disease and the effects of L-dopa.

Parkinson's disease (PD) is associated with a loss of central dopaminergic pathways in the brain leading to an abnormality of movement, including saccades. In PD, analysis of saccadic latency distributions, rather than mean latencies, can provide much more information about how the neural decision process that precedes movement is affected by disease or medication. Subject to the constraints of intersubject variation and reproducibility, latency distribution may represent an attractive potential biomarker of PD. Here we report two studies that provide information about these parameters, and demonstrate a novel effect of dopamine on saccadic latency, implying that it influences the neural decision process itself. We performed a detailed cross-sectional study of saccadic latency distributions during a simple step task in 22 medicated patients and 27 age-matched controls. This revealed high intersubject variability and an overlap of PD and control distributions. A second study was undertaken on a different population specifically to investigate the effects of dopamine on saccadic latency distributions in 15 PD patients. L-dopa was found to prolong latency, although the magnitude of the effect varied between subjects. The implications of these observations for the use of saccadic latency distributions as a potential biomarker of PD are discussed, as are the effects of L-dopa on neural decision making, where it is postulated to increase the criterion level of evidence required before the decision to move is made.

The use of quantitative oculometry in the assessment of Huntington's disease.

Huntington's disease (HD) is a neurodegenerative disorder characterised by progressive motor, cognitive and psychiatric symptoms. Objective measurement of disease severity is of increasing importance for detecting symptomatic disease, as well as monitoring disease progression and the response to novel therapeutic interventions. Using a newly-developed infra-red scleral oculometer, we measured saccadic latencies and durations in HD patients exhibiting a broad range of symptoms (n=24) and control subjects of comparable ages (n=20) to see whether these parameters might reflect the presence or severity of HD. Latency distributions were characterised by creating reciprobit plots for each subject, whilst parametric statistics were applied to durations. Compared with the control group, we found the HD group had a significantly increased median latency, and early saccades were more prominent. In addition, HD patients exhibited an increased saccadic duration and variability of duration. Using Bayesian (likelihood) analysis, we obtained saccadic support values for the presence of clinical HD, which correlated with the motor Unified Huntington's Disease Rating Scale (UHDRS) score in these patients. A sensitivity/specificity analysis of all 44 participants showed that the use of this multivariate support measure was highly successful in predicting HD status, correctly diagnosing 75% of the HD patients, and (95%) of the controls; with a different criterion, these figures were 96 and 15%. Furthermore, we correctly predicted absence of disease in two additional subjects subsequently confirmed to be genetically unaffected. This strongly suggests that multivariate support values derived from saccadic parameters may provide an objective, quantitative biomarker of HD, especially the degree of motor impairment. However, larger longitudinal studies are required to determine whether they can reliably detect the earliest presymptomatic disease, or faithfully reflect disease progression.

Biomarkers and Parkinson's disease.

Biomarkers are characteristics that can be measured as an indicator of a normal biological process, and they have special relevance in Parkinson's disease. Parkinson's disease is a chronic neurodegenerative disorder that is difficult to study, given the site of pathology and because the resultant clinical phenotype fluctuates over time. We currently have no definitive diagnostic test, and thus for the clinician there is hope that biomarkers will help diagnose symptomatic and presymptomatic disease or provide surrogate end-points to demonstrate clinical efficacy of new treatments, such as neuroprotective therapies, and help stratify this heterogeneous disease. No biomarker is likely to fulfil all these functions, so we need to know how each has been validated in order to understand their uses and limitations, and be aware of potential pitfalls. In this review we discuss the current potential biomarkers for Parkinson's disease, highlight the problems with their use, and conclude with a discussion of future alternatives.

Isolated cerebellar syndrome following head injury with short posttraumatic amnesia.

We present the case of a man developing a profound cerebellar syndrome within 24 h of a minor head injury. His neuroimaging was normal and no other cause was found for his cerebellar syndrome. We discuss the possible pathological substrate for such a focal neurological deficit after minor head trauma.