The Relation between Cerebral Activity and Force in the Motor Areas of the Human Brain. Dettmers, Christian, Gereon R Fink, Roger N Lemon, Klaus M Stephan, Richard Passingham, David Silbersweig, Andrew Holmes, Michael C Ridding, David J Brooks, Richard SJ Frackowiak. Wellcome Department of Cognitive Neurology and MRC Cyclotron Unit, Hammersmith Hospital, London, UK, Neurologische Universitsklinik, Bonn, Germany, Max-Planck-Institut f[umlaut]ur neurologische Forschung, K[diaeresis]oln, Germany, Sobell Dept of Neurophysiology, Institute of Neurology Queen, Square, London, UK, Neurologisches Therapiecentrum an der Universit[umlaut]at D[umlaut]usseldorf, Dusseldorf, Germany, Dept of Experimental Psychology, University of Oxford, Oxford,UK, Dept of Psychiatry, The New York Hospital, New York, USA, MRC Human Movement and Balance Unit, Queen Square, London, UK, Institute of Neurology, Queen Square, London, UK.
APStracts 2:0112N, 1995.
SUMMARY AND CONCLUSIONS
1. Positron emission tomography (PET) studies were performed in six normal right-handed male volunteers (age 30 ¯+ 3) to investigate the relationship between cerebral activation as measured by relative regional cerebral blood flow (rCBF) and force peak exerted during right index finger flexion. The purpose was to determine in which central motor structures activity is directly correlated with force for repeatedly executed movements. 2. Twelve PET rCBF measurements were performed in each volunteer using H 2 15 O as a perfusion tracer. Volunteers pressed a morse-key repetitively with their right index finger for two minutes while lying in a supine position in the PET camera. The device was fitted with strain gauges to measure the force peaks exerted upon it. Scans were collected twice each at 5 different levels of exerted force peak and in a resting state. Individual and group results were co-registered with anatomical magnetic resonance images (MRI). 3. Group analysis revealed four major regions with a high correlation between rCBF and different degrees of repetitively exerted force peaks. One was located in the arm area of the left lateral surface (primary somatosensory and motor cortex (SI, MI)). The second area was situated on the left mesial surface of the brain, posterior to the anterior commissure (AC) and encompassing the first gyrus dorsal to the cingulate sulcus. This area is thought to be homologous to the posterior part of the supplementary motor area (SMA) in the monkey. The third area was the dorsal bank of the posterior cingulate sulcus. The fourth area showing a significant correlation between rCBF and force peaks was in the cerebellar vermis. 4. Individual PET data were co-registered with each individual's magnetic resonance images (MRI) in order to identify precisely the locations of structures demonstrating a positive correlation between rCBF and force peak. Activated areas on the mesial surface consisted of the same two distinct regions seen in the group data. In three subjects the focus on the lateral surface of the cortex appeared to extend into the caudal premotor area; in two it extended into the rostral part of the superior parietal area. In no subject did blood flow in the anterior cingulate areas and anterior SMA show a correlation with the force exerted. Cerebellar correlations were present in the vermis in all subjects. 5. In addition to the activation in the primary sensorimotor cortex a comparison of all activated conditions with the resting state revealed a significant activation in the cerebellar vermis, left putamen/claustrum, bilateral insular cortices, right and left ventrolateral premotor areas, bilateral parietal opercular regions (SII), left ventral posterior SMA and bilateral dorsal posterior SMA. 6. At the lowest force level exerted by the right index finger rCBF in the right primary sensorimotor cortex showed a decrease relative to rest of 5.9 %. At higher force levels rCBF showed an 8.7 % increase. This was associated with electromyographic evidence of contractions of left shoulder muscles. 7. The relationship between relative increase of rCBF and force peaks was exponential with an initial steep increase in rCBF reaching a plateau at higher force levels. The initial slope was steepest in MI. This area, together with the posterior cingulate motor area and the ventral part of the posterior SMA constitute an executive motor system responsible for the execution of controlled force pulses by the index finger. This system is a subset of the areas associated with the generation of finger movements, and is responsible for all the components that together result in application of the required digital force. 

Received 1 November 1994; accepted in final form 20 March 1995.
APS Manuscript Number J689-4.
Article publication pending J. Neurophysiol.
ISSN 1080-4757 Copyright 1995 The American Physiological Society.
Published in APStracts on  1 May 1995.