This study examined the association of physical fitness and motor ability of university-aged students with the risk of LS in middle-aged and older Japanese men. The results showed that the risk of LS was lower in high side-step test (agility) participants than in low side-step test (agility) participants at a young age. The results of this study demonstrate the good agility at a young age contributes to a lower risk of LS at middle and old age.
During the follow-up period, the risk of LS was suspected for 31 (13.4%) participants in this study. However, Sasaki et al. reported the risk of LS in Japan for 56 (21.2%) men, among the 264 men whose mean ages were 56.3±14.1 (21–86) years [22]. Although the age of the subjects in the previous study is similar to the age of the subjects in this study, and LS test methods consisting of only the Loco-check questionnaire, the proportion of people suspected of having LS risk in our study was lower, probably owing to the greater physical fitness and motor ability of our subjects.
Overall, 231 of the 1385 individuals’ second follow-up survey in 2017 (16.7%) met the criteria for the present study. The median year of graduation of the participants in the present study at the university (at the baseline) was 1981. We thus compared the physical fitness and motor ability test results of the subjects in the present study with male students in their fourth year of study at Juntendo University in 1981 (Supplementary Table 3). Although we had no way to conduct statistical analyses, for all tests, the differences are very small, indicating that the sample of our study can represent the data of alumni who graduated from the Department of Physical Education of a university. Therefore, we believe that the dropout data have little effect on the results of this study. The median age of the participants in the present study at the university (at the baseline) was 21 years; we therefore also compared the results of the physical fitness and motor ability tests of the subjects in the present study to those of age peers in general who were 21 years old in 1981 (Supplementary Table 3). In addition, although we have no way to conduct statistical analysis, for all tests, the results of the subjects in the present study are better than those of age peers in general in 1981, indicating that the subjects of our study are likely to have better physical fitness and motor ability. This reveals that further investigation is needed to determine the effects of physical fitness and motor ability at young age on LS risk and compare them with age peers in general.
Agility has been identified as the ability to include whole-body change of direction as well as change of limb direction [26, 27], the ability to coordinate, quickly and accurately, the big muscles of the body in a particular activity (a neurological function) [28]. This definition suggests that ability involves modulated movements and physical reactions. If agility is a concept of harmony, then it can also be considered as physical control, with muscle control being an integral part of agility. Since the side-step test includes the concepts mentioned above, this test is an accepted way to measure agility, and is also considered an effective indicator. In LS, the three main components of the locomotive system are the bones (support), joints and intervertebral discs (mobility, shock absorption), and the muscular and nervous systems (drive, control) [29]. Therefore LS is identified as a condition in which mobility functions such as sit-to-stand or gait, are reduced as a result of locomotive organ/system impairment [1]. Although agility and LS are essentially two completely different concepts, we can see that agility has many determinants that are common to LS. For example, the whole-body change of direction as well as change of limbs in the definition of agility is actually dependent on the support of bones and the help of joints. In addition, modulation of movements in the definition of agility and the nervous system in LS refer to the individual’s ability to control the body and muscles. Hence agility may be a predictor of the risk of LS.
In this follow-up survey, 15 (6.5%) participants were suspected of having LS risk owing to their inability to “cross the road before the light turns red” (Supplementary Table 4), implying that the subjects are unable to move or walk quickly within a limited time. The side-step test (agility) assesses the number of times the subject can quickly move left and right within a specified time (Additional file 1). This may imply that if one has poor agility when one is young, one’s ability to move quickly within a limited period of time during middle and old age will be poor, leading to LS.
Furthermore, our results support past findings with respect to the association between physical fitness and LS risk in the older adult population. Yoshimura et al. found that slower Five Times Sit-to-Stand Test times (lower extremity strength) were associated with a higher stage of LS in middle-aged and older individuals [7]. Negrete and Brophy reported that the single-leg isokinetic squat strength (lower extremity strength) was associated with complex multi-directional tasks over short distances (agility) in university-aged subjects [30]. In addition, Pembrey et al. concluded in their study that agility, and jumping ability (lower extremity strength) could assess the same physical attributes in young competitive-level team sports players [31]. These authors showed that lower extremity strength played an important role in agility among university-aged subjects. In addition, 12 (5.2%) participants were suspected of having LS risk owing to the need for holding on to the handrail when climbing the stairs (Supplementary Table 4), implying that the strength of the lower limbs of these individuals has decreased. As mentioned previously, the strength of the lower limbs plays a very important role in agility. Thus, maintaining good strength of the lower limbs at a young age ensures that the strength of the lower limbs will not decline quickly in middle and old age. We believe that although the relationship between the lower limb strength of young and older adults is equivocal; both may be positively correlated. Therefore, based on these findings, agility at a young age may be a sensitive factor for predicting the risk of LS, and may indirectly help prevent the progression of LS.
However, this association was not confirmed in Model 1. This is because LS risk includes several important factors, including age, which were not considered in Model 1. Age is considered to be an important factor in LS risk [11, 25]. Nevertheless, agility was still not associated with risk of LS when a young age was considered in Model 2. This is because, among the 231 participants, 205 (88.7%) were aged 21 years, 23 (10.0%) were aged 22 years, and three (1.3%) were aged 23 years at the fourth year at university (at baseline). This result (Model 2) suggested that this difference did not introduce confounding effects. Therefore, in Model 3 we identified a negative relationship in terms of agility and the risk of LS when age and BMI at the follow-up survey were considered. The reasons for considering BMI in Model 3 is that BMIs reported in the follow-up survey were significantly higher than those of the participants in the NLS group. It is also important to take the daily step counts into consideration. The significant estimate is not stronger in Model 4 than in Model 3, suggesting that our results are not due to confounding effects from daily step counts except for the side-step test.
We did not find any relationship between the vertical jump test (power) or the step-test (endurance) and the risk of LS. Although the vertical jump test also shares characteristics in common with lower extremity strength, the vertical jump test does not only measure lower extremity strength, it also depends on speed (instantaneous power) [32, 33]. The step-test assesses the ability to perform a specific muscular action for a prolonged period of time,and not just a bout of lower extremity strength [33]. Meanwhile, LS is identified as a condition in which mobility functions, such as sit-to-stand or gait, are reduced as a result of locomotive organ/system impairment [1]. It is noteworthy that the Loco-check questionnaire did not comprise items of instantaneous power and endurance; thus, the vertical jump test and the step-test might not be factors predictive of the risk of LS.
In this study, back muscle strength and grip strength did not show any association with the risk of LS. The most plausible reason for this finding was that seven questions on the Loco-check questionnaire evaluated the lower-extremity physical function status in middle-aged and older adults, and there was no question related to back muscle strength or grip strength, therefore back muscle strength and grip strength were not associated with the risk of LS.
Conversely, there was no significant relationship found between trunk lift (flexibility), standing trunk flexion (flexibility), and the risk of LS. Consistent with our results, no significant relationship between functional reach (flexibility) [34] and the risk of LS has been reported in Japanese individuals aged 40–91 years[13]. This result suggests that there is no association between flexibility and the risk of LS.
Physical fitness is defined as the ability to carry out daily tasks with vigor and alertness without undue fatigue and with ample energy to enjoy leisure-time pursuits and respond to emergencies[35]. Moreover, basic physical fitness elements include muscle strength, and muscular and circulatory endurance. Muscle power, agility, speed, and flexibility contribute to motor ability; thus, kinesthetic arm-eye foot-eye coordination is needed for general motor ability [26]. Thus, we may consider physical fitness to reflect ADL, and that motor ability is higher than physical function. In this study, none of the motor ability measurement items were associated with the risk of LS. Although the reason for these results is unclear: the seven questions on the Loco-check questionnaire designed to evaluate ADL and motor ability may not have been able to directly evaluate the ADL.
Our study has several limitations. Firstly, the current findings were not representative of all Japanese men because the study population was predominantly composed of middle-aged and older men from a single department in one university, and almost all were former university athletes. Secondly, only male alumni were included in this study. Therefore, the relationship between physical fitness, motor ability at a young age and LS risk of middle-aged and older women was not addressed. Thirdly, a self-selection bias was possible because the medical background and LS-risk test was examined using a self-administered questionnaire. In addition, since there was no information on when participants experienced the difficulty in LS, in this study, the time of the follow-up survey was regarded as the time at which they experienced the difficulty in LS. Therefore, there is a possibility that the participants had already experienced the difficulty in LS before the time of the follow-up survey. Finally, although we considered several potential confounding factors, we did not rule out the influence of current physical fitness, motor ability, and socioeconomic status. However, we considered the influence of daily step counts. However, despite these limitations, the current findings are the first to confirm the influence of physical fitness and motor ability at a young age on the progression of LS risk over a long follow-up period.