The ability to execute precise and rapid braking is an important determinant of safe driving. Vision, cognition, mobility and strength are important attributes involved in complex coordination during driving-related braking 1,2. Compared with other drivers, older adults have significantly lower ankle plantar flexor strength, a characteristic associated with worse braking time performance 3.

Measurements of muscle strength are a feature of all studies related to motor evaluations of drivers. Such evaluation is part of the Assessment of Driving Related Skills (ADReS) 4.

Isokinetic dynamometry provides an objective measure of muscular functional parameters. Motor adaptation is characterized by acute improvements in physical function and muscle strength capacity 5–7. An issue related to motor learning or adaptation is the extent to which the effects of motor adaptation can modify the results of objective assessments, even during the short period between repeated isokinetic tests 7,8.

However, it is unclear whether acute motor adaptation extends to all muscle groups and populations. Thus, the aim of this study was to analyze the effects of acute motor adaptation for older drivers who were performing two isokinetic tests of the ankle joint that involved plantar flexor and dorsiflexor movements.

The subjects' sociodemographic characteristics are shown in Table 1.

Means and standard deviations of examined variables, including peak torque (PTQ), PTQ adjusted for body weight (PTQ/BW), total work (TW), and agonist/antagonist ratio for plantar flexion and dorsiflexion, are shown in Table 2. Muscle strength was significantly higher in the dominant limb than in the non-dominant limb. On the dominant side, plantar flexors produced significantly higher values for PTQ/BW and TW for the second test than for the first test, whereas PTQ, PTQ/BW, and TW for dorsiflexion were significantly higher for the second test than for the first test. For the non-dominant lower limb, plantar flexors exhibited significantly lower values for PTQ and TW during the second test than during the first test. There were no significant differences in dorsiflexion outcomes for the non-dominant limb. The agonist/antagonist ratio decreased significantly for both lower limbs from the first assessment to the second assessment.

The means and standard deviations for coefficients of variation (CVs), minimums and maximums are shown in Table 3. CVs were significantly lower for the second test than for the first test for plantar flexion on the dominant side (p<0.001). CVs were significantly higher for the dominant limb than for the non-dominant limb.

The primary findings of this research were that multiple repetitions of the tests led to neuromuscular integration of motor learning, which resulted in more reliable outcomes. The relative discomfort (restraint) caused by equipment positioning can inhibit assessments of individuals, affecting their performances during the execution of tests; therefore, the effect of adaptation is highly relevant to this study.

For the dominant ankle, better results were obtained for the second test than for the first test for the PT/BW and TW variables for plantar flexion muscle strength; this finding is consistent with those reported in other studies 7,8. This phenomenon suggests an adaptation and learning effect with respect to the use of computerized strength testing equipment. Driving ability is a complex task that demands various skills and physical capacities, such as muscle strength, which is one of the most important predictors of driving safety 3,9. In a previous study, ankle plantar flexor muscles were evaluated because of the specificity of movements associated with driving, and a robust relationship between these muscles and the dynamic task of braking was observed. The results showed that lower muscle strength during plantar flexion was associated with worse braking time performance 3. Therefore, older drivers took longer to brake a car, which could cause accidents in certain situations 1.

In another study involving knee flexion and extension assessment, better performance was observed on a second trial than on a first trial completed during the same session 7; this observation is consistent with our findings for the ankle joint.

For the non-dominant ankle, our assessments revealed lower strength for the second trial than for the first trial, with only plantar flexor PTQ and TW exhibiting improvement for the second trial. Certain psychological factors can explain this phenomenon. Dominance itself leads to higher cortical representation of muscle on the dominant side; as a result, motor adaptation is faster on that side based on the recruitment of more motor units during movement 10. On the non-dominant side, only plantar flexor performance was better for the second trial than for the first trial. Higher strength and activity for plantar flexors than for other muscles during daily activities (gait, balance and orthostatic activities) could potentially explain this finding. Driving a vehicle with a mechanical transmission involves the use of the left ankle during top gear, which could make learning easier for muscles associated with this ankle. A study that compares performance between older drivers and non-drivers might shed light on this possibility 11.

The dominant limb had better performance for all isokinetic variables for both tested muscle groups. In their meta-analysis, Mcgrath et al. 10 affirm that there are significant differences between the performances of thigh muscles for the dominant and non-dominant leg in adults; specifically, functional asymmetries have been observed for the lower legs of athletes with different skills and specializations 10,12. However, results have suggested that vehicle direction (in particular, the force designed to press the accelerator and brake pedal for approximately 432.8 (±9.2) years) appeared to promote a selective muscle pattern, and may generate imbalances between the dominant and non-dominant limbs.

The CVs of repetitions decreased for the second trial only for the dominant plantar flexors, which reflects these muscles' better capacity for contraction maintenance during subsequent repetitions. Lower CVs indicate greater muscle fatigue resistance and the higher capacity of a muscle to recruit motor units. In combination, these capabilities allow for constant torque production during all repetitions 6,13,14.

The agonist/antagonist ratio for the dominant and non-dominant limbs decreased for the second trial. This outcome might indicate a decrease in dorsiflexor concentric PTQ or an increase in plantar flexor PTQ that resulted in an imbalance in the tested joint 12,15. These results confirm the importance of task specificity for driving assessments and suggest that driving creates imbalances between muscle group agonists/antagonists for the same limb.

One of the most important clinical implications of performing muscle strength assessment for healthy elderly individuals by utilizing two tests in a short time is to use the second test to improve the trustworthiness of the results.

Our results demonstrate that relative to an initial test, on a second test of plantar flexion and dorsiflexion, older drivers exhibit better performance with their dominant limb and lower test execution variability, suggesting that they adapted to the execution of the proposed movements for the second test, even with a short recovery period between tests.

Alonso AC was responsible for the data collection, manuscript writing and data analysis. Ernandes RC was responsible for the data collection and manuscript revision. Wenzel DR, Ayama S and Canonica AC were responsible for the data collection and manuscript writing. Luna NM and Santos SS were responsible for the manuscript writing. Brech GC was responsible for research design and manuscript revision. Mochizuki L was responsible for the data analysis and interpretation. Peterson M was responsible for the manuscript language and grammar revisions. Garcez-Leme LE and Greve JM were responsible for the research supervision and manuscript revision.