Background
Medial tibial stress syndrome (MTSS) is one of the most commonly observed injuries in runners [
1,
2]. Previous studies have reported that 15.2% of high school runners developed MTSS during the 13 weeks of cross-country season [
3] and 43.6% of high school runners developed MTSS during the 3 years of the follow-up period [
4], and took 44–78 days to resume their original athletic level [
5]. These studies indicated that prevention or treatment for MTSS is important; however, there is limited evidence regarding interventions being effective for the treatment and prevention of MTSS. A recent systematic review found that use of foot orthoses is beneficial for preventing MTSS [
6]. Conversely, wearing thick-soled and heavy shoes decreased the running economy [
7]. Thus, understanding of the etiology and correct intervention is important for preventing MTSS, without hampering the running performance.
A magnetic resonance imaging study has indicated that MTSS is a lesion in the junction of the periosteum and fascia [
1]. A previous study reported that elongational stress of the lower limb muscles, such as the soleus, flexor digitorum longus (FDL), or tibialis posterior (TP) increased strain in the tibial fascia [
8]. As larger navicular drop and excessive pronation during running are considered as risk factors of MTSS [
9‐
11], it is assumed that MTSS is related to overuse of ankle inversion muscles. Furthermore, FDL had a higher proportion of attachment to the posteromedial border of the tibia, which is a more common location of MTSS than is the soleus (SOL) (FDL, 97%; SOL, 49%) [
12], which suggested that MTSS could be developed by elongational stress of the FDL.
Considering the relationship between MTSS and ankle strength, a cross-sectional study reported that isokinetic inversion strength was relatively weaker than eversion strength of the ankle in patients with MTSS [
13], and the mean number of standing heel-raise repetition test, an index of isotonic plantar flexion endurance of the ankle, was low [
14]; however, a prospective study that investigated the risk factors of MTSS reported that preclinical ankle strength was not related to the development of MTSS [
15], but the results conflicted with those of cross-sectional and prospective studies. The reason for this incongruence is assumed to be the inability by the participants to develop enough force due to pain at the time of measurement during the cross-sectional study. On the other hand, the participants did not have pain at the time of measurement during the prospective study.
In addition, the inversion muscle strength is a combination of three muscles (i.e., the TP, FDL, and flexor hallucis longus (FHL) forces. Because the FDL had a higher proportion of attachment to the posteromedial border of the tibia, which is the most common location of MTSS [
12], plantar flexion strength of the lesser toes could be related to MTSS. Therefore, it was assumed that by measuring the plantar flexion strength of the hallux and lesser toes, the relationship between MTSS and muscle strength could be better understood. The relationship between MTSS and muscle strength of the hallux and lesser toes has not been evaluated due to the lack of quantitative methods.
Furthermore, MTSS is known to recur, and previous studies have reported that a patient with previous history of MTSS is at a risk of MTSS [
15,
16]. This suggests that there must be some physical factor that induces MTSS in runners with a history of MTSS. Therefore, we assumed that a cross-sectional study investigating the relationships between MTSS and muscle strength of the hallux and lesser toes could be useful for estimation of MTSS risk factors. Moreover, because pain may inhibit force development, it is important to measure the muscle strength of subjects with a history of MTSS who are devoid of pain at the time of measurement.
This study aimed to conduct a detailed investigation of the muscle strength characteristics, including the muscle strength of the 1st metatarsophalangeal joint (MTPJ) and 2nd–5th MTPJ plantar flexion, in runners with a history of MTSS by using a newly developed device. The hypothesis of the study was that the strength of the 2nd–5th MTPJ plantar flexion should be higher in runners with a history of MTSS because FDL, which attaches to the most common location of MTSS, excessively functions in runners with a history of MTSS.
Results
Normal distribution was confirmed in all measurements of alignment and strength except for leg–heel alignment and inversion strength of the ankle. The results of the foot alignment are shown in Table
1. For both navicular drop and leg–heel alignment, there was no significant difference between participants with and without a history of MTSS. (
p = 0.98 for navicular drop and 0.72 for leg–heel alignment). The reliability results are shown in Table
2, and the results of the strength are shown in Table
3. For the 1st MTPJ plantar flexion, the MVIC torque was 9.8 ± 2.3 N∙m in the participants without history of MTSS and 12.0 ± 3.0 N∙m in the participants with a history of MTSS, with significant difference (
p = 0.04). For the 2nd–5th MTPJ plantar flexion, the MVIC torque was 6.0 ± 1.6 N∙m in the participants without history of MTSS and 6.0 ± 2.1 N∙m in the participants with a history of MTSS, but the difference was not significant (
p = 0.94). For the MVIC torque of the ankle, there was no significant difference between participants with and without a history of MTSS (
p = 0.45 for plantar flexion, 0.75 for dorsi flexion, 0.66 for eversion and 0.90 for inversion).
Table 1
Foot alignment in participants with and without a history of MTSS
Navicular Drop (mm) | 7.1 ± 2.0 | 7.1 ± 1.9 | 0.98 | 0.01 |
Leg Heel Alignment (°) | 5.0 ± 1.4 | 5.1 ± 2.0 | 0.72 | 0.08 |
Table 2
Reliability values of the muscle strength measurements
Ankle | Plantar flexion | 0.93 | 7.3 |
Dorsiflexion | 0.83 | 6.8 |
Eversion | 0.86 | 9.2 |
Inversion | 0.64 | 9.8 |
1st MTPJ | Plantar flexion | 0.96 | 4.8 |
2nd–5th MTPJ | Plantar flexion | 0.94 | 8.3 |
Table 3
Muscle strengths of the ankle and toe in participants with and without a history of MTSS
Ankle | Plantar flexion | 84.2 ± 28.2 | 92.2 ± 28.2 | 0.45 | 0.15 |
Dorsiflexion | 32.7 ± 5.4 | 33.3 ± 5.3 | 0.75 | 0.07 |
Eversion | 21.6 ± 5.7 | 22.6 ± 5.8 | 0.66 | 0.09 |
Inversion | 23.5 ± 9.9 | 22.0 ± 5.9 | 0.90 | 0.02 |
1st MTPJ | Plantar flexion | 9.8 ± 2.3 | 12.0 ± 3.0 | 0.04 | 0.40 |
2nd–5th MTPJ | Plantar flexion | 6.0 ± 1.6 | 6.0 ± 2.1 | 0.94 | 0.02 |
Discussion
This study investigated muscle strength characteristics in runners with a history of MTSS by comparing the muscle strength of the ankle and toe between runners with and without a history of MTSS. To the best of our knowledge, this is the first study to show the relationship between MTSS and toe strength. For both navicular drop and leg–heel alignment, there was no significant difference between participants with and without a history of MTSS. Thus, the foot alignment of participants was not different between the two groups. The ICC values for all muscle strength measurements were >0.61, and substantial reliability was confirmed [
21].
In this study, the MVIC torque of the 1st MTPJ plantar flexion was significantly higher in runners with a history of MTSS than without it. In contrast, there was no significant difference in MVIC torque of the 2nd–5th MTPJ plantar flexion between the runners with a history of MTSS and without it. These results did not support our hypothesis that MTSS occurs because of excessive activity of the FDL, which could be identified as higher MVIC torque of the 2nd–5th MTPJ plantar flexion in runners with a history of MTSS. There are two possibilities regarding these results.
Our results suggest that runners with a history of MTSS adopt a strategy of reducing the load to the medial tibia because of their history of MTSS. A previous study reported that excessive pronation during motion is a risk factor of developing MTSS [
9,
11]. The results also suggest that the FDL and TP muscles that act to support the arch of the foot tend to be stressed in runners who potentially have a risk for developing MTSS. On the other hand, although the FHL, which is an agonist of 1st MTPJ plantar flexion, has a function similar to those of the FDL and TP as the inversion muscle of the ankle, FHL is not likely to be related to development of MTSS because the FHL does not connect to tibial fascia [
22]. Thus, this characteristic increase in MVIC torque of the 1st MTPJ in runners with a history of MTSS could be considered to be a result of increased activity of the FHL to avoid pain caused by contraction stress of the FDL, which could be a possible cause of MTSS. Although the activity of intrinsic and extrinsic muscles cannot be distinguished by measuring the MTPJ plantar flexion strength, our previous study investigated the associations between navicular drop and toe flexion strength at a different angle of the ankle and toe, and the result showed that navicular drop was correlated with only toe flexion strength at the position where the intrinsic foot muscles are relatively elongated [
23]. This previous study indicated the correlation between intrinsic foot muscle strength and navicular drop. In the current study, navicular drop was not different between the two groups. Therefore, we considered that the activity of intrinsic muscle was not different between the groups while measuring the MTPJ plantar flexion strength.
Surprisingly, there was no significant difference in MVIC torque of the 2nd–5th MTPJ plantar flexion between runners with and without a history of MTSS. If runners with a history of MTSS adopt a strategy of reducing activation of the FDL by relying on the FHL to avoid pain during running, the MVIC torques of the 2nd–5th MTPJ could be lower. A previous study reported that the FHL tendon branches to the 2nd and 3rd toe in most cases [
24]. Therefore, it could be considered that the absence of a significant difference in the MVIC torques of the 2nd–5th MTPJ between runners with and without a history of MTSS could be due to the effects of the branching of FHL tendon to the 2nd and 3rd toe. Collectively, muscle strength characteristics in runners with a history of MTSS could be considered to be a result of increasing activity of the FHL to reduce the load on FDL and avoid pain caused by contraction stress of the FDL.
There were no significant differences in the MVIC torque values at the ankle between runners with and without a history of MTSS. This result supports a previous study showing that the isometric strength of the ankle measured in painless legs was not related to the development of MTSS [
15]. Collectively, these results suggest that characteristics in runners with a history of MTSS can be best understood by measuring toe strength rather than the ankle strength.
There are a few limitations in this study. First, the sample size was not enough in this study. Although the sample size was insufficient, we considered that the results were important because at least a moderate effect size was observed in the 1st MTPJ plantar flexion. Second, we investigated the relationships between MTSS and muscle strength as a static assessment. Therefore, it is unclear whether the results directly reflect muscle endurance or activity during running. However, in this study, measurement position of the ankle and MTPJ is same as the angle when the highest MTPJ moment is produced during running [
25,
26]. Thus, it is considered that the MTPJ plantar flexion strength at this angle represents a certain aspect during running. Future study is needed to investigate the associations between MVIC torques in the MTPJ plantar flexion and endurance or dynamic assessments (e.g., alignment during running and plantar pressure of the foot).
Acknowledgments
We appreciate Mr. Syoji for helping in recruitment and Ms. Ibuki for checking the manuscript.