Effects of Achilles Tendon Moment Arm Length on Insertional Achilles Tendinopathy
Effects of Achilles Tendon Moment Arm Length on Insertional Achilles Tendinopathy
Miyamoto, Takuma;Shinohara, Yasushi;Matsui, Tomohiro;Kurokawa, Hiroaki;Taniguchi, Akira;Kumai, Tsukasa;Tanaka, Yasuhito
2020-09-23 00:00:00
applied sciences Article Eects of Achilles Tendon Moment Arm Length on Insertional Achilles Tendinopathy 1 2 , 3 1 Takuma Miyamoto , Yasushi Shinohara *, Tomohiro Matsui , Hiroaki Kurokawa , 1 4 1 Akira Taniguchi , Tsukasa Kumai and Yasuhito Tanaka Orthopaedic Surgery, Nara Medical University, Nara 634-8521, Japan; k166136@naramed-u.ac.jp (T.M.); blackandriver@hotmail.co.jp (H.K.); a-tani@naramed-u.ac.jp (A.T.); yatanaka@naramed-u.ac.jp (Y.T.) College of Sport and Health Science, Ritsumeikan University, Shiga 525-8577, Japan Orthopaedic Surgery, Saiseikai Nara Hospital, Nara 630-8145, Japan; t.matsui19810671@live.jp Faculty of Sport Sciences, Waseda University, Tokyo 169-8050, Japan; kumakumat@waseda.jp * Correspondence: ysr15159@fc.ritsumei.ac.jp; Tel.: +81-77-561-2617 Received: 21 August 2020; Accepted: 22 September 2020; Published: 23 September 2020 Abstract: Insertional Achilles tendinopathy (IAT) is caused by traction force of the tendon. The eectiveness of the suture bridge technique in correcting it is unknown. We examined the moment arm in patients with IAT before and after surgery using the suture bridge technique, in comparison to that of healthy individuals. We hypothesized that the suture bridge method influences the moment arm length. An IAT group comprising 10 feet belonging to 8 patients requiring surgical treatment for IAT were followed up postoperatively and compared with a control group comprising 15 feet of 15 healthy individuals with no ankle complaints or history of trauma or surgery. The ratio of the moment arm (MA) length/foot length was found to be statistically significant between the control group, the IAT group preoperatively and the IAT group postoperatively (p < 0.01). Despite no significant dierence in the force between the control and preoperative IAT groups, a significantly higher force to the Achilles tendon was observed in the IAT group postoperatively compared to the other groups (p < 0.05). This study demonstrates that a long moment arm may be one of the causes of IAT, and the suture bridge technique may reduce the Achilles tendon moment arm. Keywords: insertional Achilles tendinopathy; Achilles tendon moment arm; suture bridge method 1. Introduction The Achilles tendon, attached to the posterior process of the calcaneus, is the largest and strongest tendon in the body. It is composed of the gastrocnemius muscle, originating from the condyle of the femur, and the soleus muscle, originating from the upper tibia. The gastrocnemius and soleus muscles, collectively known as the triceps surae, flex the ankle joint during gait. In the gait cycle, balance is maintained against gravity during the stance phase, and flexing the ankle joint during the toe-o phase provides a forward propulsive force [1]. The contraction of the triceps surae is exerted as a rotational force (torque) around the ankle axis, which can be calculated theoretically as the product of the muscle cross-section and the moment arm (MA) (Figure 1) [2–4]. In general, the length of the MA is known to change depending on the angles of plantarflexion and dorsiflexion of the ankle joint, which is dierent in each individual [2–4]. However, the length of the MA of the triceps surae has been reported to change depending on the angle of plantar- and dorsiflexion of the ankle joint [5–7]. Yet, it has also been reported that motion does not cause any change in the length of the MA [8,9], and that the plantarflexion moment length, from the plantarflexion region to the dorsiflexion region, is dierent in each individual, with little change caused by motion [2–4]. Appl. Sci. 2020, 10, 6631; doi:10.3390/app10196631 www.mdpi.com/journal/applsci Appl. Sci. 2020, 10, 6631 2 of 11 Thus, the changes in the length of the MA in motion has attracted great attention. Moreover, the shape of the foot has been shown to influence the Achilles tendon MA [10]. However, these studies examined the length of the MA only in healthy individuals and it has not been investigated in patients with Appl. Sci. 2020, 10, x FOR PEER REVIEW 2 of 11 Achilles tendon disorders. Figure 1. The contraction of the triceps surae can be calculated theoretically as the product of the Figure 1. The contraction of the triceps surae can be calculated theoretically as the product of the triceps surae muscle cross-section area and the Achilles tendon moment arm using the lever rule. triceps surae muscle cross-section area and the Achilles tendon moment arm using the lever rule. The center of rotation (COR) and tendon excursion (TE) methods are mainly used for the In general, the length of the MA is known to change depending on the angles of plantarflexion measurement of the lever arm of Achilles tendon [5], with MRI and ultrasound generally used for and dorsiflexion of the ankle joint, which is different in each individual [2–4]. However, the length of these methods, respectively. Manja et al. [10] proposed a new method using a weight-bearing X-ray. the MA of the triceps surae has been reported to change depending on the angle of plantar- and The method allowed the evaluation of the morphology and anatomical position of the bone and soft dorsiflexion of the ankle joint [5–7]. Yet, it has also been reported that motion does not cause any tissue. Therefore, we are now able to investigate in various patients with Achilles tendon disorders. change in the length of the MA [8,9], and that the plantarflexion moment length, from the Insertional Achilles tendinopathy (IAT), an Achilles tendon disorder, is caused by the traction plantarflexion region to the dorsiflexion region, is different in each individual, with little change force of the Achilles tendon [11,12]. This traction force is influenced by the rotational torque of the caused by motion [2–4]. Thus, the changes in the length of the MA in motion has attracted great ankle joint, and the moment arm length is proportional to the plantar flexion torque of the ankle attention. Moreover, the shape of the foot has been shown to influence the Achilles tendon MA [10]. joint [13]. Therefore, when force is applied to the ankle joint, the Achilles tendon moment arm length However, these studies examined the length of the MA only in healthy individuals and it has not is inversely proportional to the traction force applied to the insertion of the Achilles tendon. On the been investigated in patients with Achilles tendon disorders. other hand, with a short moment arm, the circular arc associated with ankle rotation is thought to The center of rotation (COR) and tendon excursion (TE) methods are mainly used for the shorten, reducing the length displacement of the muscle-tendon complex, and further reducing the measurement of the lever arm of Achilles tendon [5], with MRI and ultrasound generally used for consumption of elastic energy of the Achilles tendon [13,14]. Thus, the moment arm of the ankle joint these methods, respectively. Manja et al. [10] proposed a new method using a weight-bearing X-ray. is expected to influence the traction force applied to the insertion of the Achilles tendon, the length The method allowed the evaluation of the morphology and anatomical position of the bone and soft displacement of the muscle-tendon complex, and the elastic energy. tissue. Therefore, we are now able to investigate in various patients with Achilles tendon disorders. Surgical treatments for IAT include para-tendon excision, adhesion detachment, intra-tendon Insertional Achilles tendinopathy (IAT), an Achilles tendon disorder, is caused by the traction degeneration excision, and calcaneal wedge osteotomy [15,16]. Of these, we preferred surgical force of the Achilles tendon [11,12]. This traction force is influenced by the rotational torque of the treatment of insertional Achilles tendinosis with reattachment of the Achilles tendon using the suture ankle joint, and the moment arm length is proportional to the plantar flexion torque of the ankle joint bridge technique (Figure 2). This method firmly fixes the enthesis by pressing the tendon with the [13]. Therefore, when force is applied to the ankle joint, the Achilles tendon moment arm length is surface, and good outcomes have been reported with this method [17]. inversely proportional to the traction force applied to the insertion of the Achilles tendon. On the However, due to the lack of basic research on this surgical technique, its eectiveness remains other hand, with a short moment arm, the circular arc associated with ankle rotation is thought to unknown. This study aimed to examine the moment arm length as an anatomical feature in patients shorten, reducing the length displacement of the muscle-tendon complex, and further reducing the with IAT. We hypothesized that the suture bridge method for IAT influences the moment arm length. consumption of elastic energy of the Achilles tendon [13,14]. Thus, the moment arm of the ankle joint is expected to influence the traction force applied to the insertion of the Achilles tendon, the length displacement of the muscle-tendon complex, and the elastic energy. Surgical treatments for IAT include para-tendon excision, adhesion detachment, intra-tendon degeneration excision, and calcaneal wedge osteotomy [15,16]. Of these, we preferred surgical treatment of insertional Achilles tendinosis with reattachment of the Achilles tendon using the suture bridge technique (Figure 2). This method firmly fixes the enthesis by pressing the tendon with the surface, and good outcomes have been reported with this method [17]. Appl. Sci. 2020, 10, 6631 3 of 11 Appl. Sci. 2020, 10, x FOR PEER REVIEW 3 of 11 Figure 2. We performed a reconstruction of the Achilles tendon with a suture bridge technique. ①: Figure 2. We performed a reconstruction of the Achilles tendon with a suture bridge technique. O 1 : Bone Bone spurs, calcifications in the tendon, and Haglund’s prominence is removed. ②: Two Swive Locks spurs, calcifications in the tendon, and Haglund’s prominence is removed. O 2 : Two Swive Locks with with Fiber Tape inserted in the proximal hole. ③: Fiber Tape is passed through the Achilles tendon Fiber Tape inserted in the proximal hole. O 3 : Fiber Tape is passed through the Achilles tendon and and inserted into the prepared distal hole using Swive Lock. ④: The tails on the distal row flushed to inserted into the prepared distal hole using Swive Lock. O 4 : The tails on the distal row flushed to the the anchor. (A): Preoperative X-ray. (B): Postoperative X-ray for the same case. anchor. (A): Preoperative X-ray. (B): Postoperative X-ray for the same case. 2. Materials However, d and Methods ue to the lack of basic research on this surgical technique, its effectiveness remains unknown. This study aimed to examine the moment arm length as an anatomical feature in patients This is a retrospective study. Fourteen individuals (16 feet) who required surgical treatment for with IAT. We hypothesized that the suture bridge method for IAT influences the moment arm length. IAT at our hospital between 2014 and 2019 were included in the IAT group. Those with a history of collagen diseases or trauma other than Achilles tendon injuries, and those who could not be followed 2. Materials and Methods up for more than one year after surgery were excluded from the study. As a result, 8 individuals This is a retrospective study. Fourteen individuals (16 feet) who required surgical treatment for (10 feet; IAT group) were examined in this study. Fifteen healthy individuals (with no complaints of IAT at our hospital between 2014 and 2019 were included in the IAT group. Those with a history of ankle joint injuries nor history of surgical trauma) were included for examination in the control group. collagen diseases or trauma other than Achilles tendon injuries, and those who could not be followed The reconstruction in all IAT cases was performed using the Achilles SpeedBridge system (Arthrex, up for more than one year after surgery were excluded from the study. As a result, 8 individuals (10 FL, USA). After extending the Achilles tendon in the midline and partly separating it from the insertion, feet; IAT group) were examined in this study. Fifteen healthy individuals (with no complaints of ankle the osteophytes, intra-tendinous degeneration site, and posterior superior calcaneus at the enthesis joint injuries nor history of surgical trauma) were included for examination in the control group. were excised. Subsequently, fiber tape was used to fix the Achilles tendon to the calcaneus using four The reconstruction in all IAT cases was performed using the Achilles SpeedBridge system knotless anchors. We analyzed a clinical evaluation by the American Orthopedic Foot and Ankle (Arthrex, FL, USA). After extending the Achilles tendon in the midline and partly separating it from Society ankle/hindfoot scale (AOFAS scale) and visual analog pain scale (VAS) 1 year after the surgery. the insertion, the osteophytes, intra-tendinous degeneration site, and posterior superior calcaneus at At 6 months to 1 year after the surgery, 1.5T MRI (Vantage Titan Ver3.0, Canon, Tokyo, Japan) the enthesis were excised. Subsequently, fiber tape was used to fix the Achilles tendon to the images were taken to evaluate the morphology of the Achilles tendon insertion area and abnormal calcaneus using four knotless anchors. We analyzed a clinical evaluation by the American Orthopedic signal in the tendon before and after surgery. Foot and Ankle Society ankle/hindfoot scale (AOFAS scale) and visual analog pain scale (VAS) 1 year after the surgery. Appl. Sci. 2020, 10, 6631 4 of 11 Plain X-ray images were used to measure the lever arm. The images of the aected side were taken for patients in the IAT group, while those of the healthy side were taken for patients in the control group. As described by Manja et al. [10], who used plain X-ray images of the feet during Appl. Sci. 2020, 10, x FOR PEER REVIEW 4 of 11 weight-bearing, the weight-bearing plane was taken as the plantar axis from the lateral image; a straight line perpendicular to this plantar axis, passing through the center of the Achilles tendon, was set as the At 6 months to 1 year after the surgery, 1.5T MRI (Vantage Titan Ver3.0, Canon, Tokyo, Japan) central axis of the Achilles tendon. The shortest distance from the central axis of the Achilles tendon images were taken to evaluate the morphology of the Achilles tendon insertion area and abnormal to the center of the first metatarsal head parallel to the plantar axis was defined as the length of the signal in the tendon before and after surgery. sole. A perfect circle was drawn to fit the pulley surface of the talus, and the center point was used Plain X-ray images were used to measure the lever arm. The images of the affected side were as the center of motion. The shortest distance from the center of motion to the central axis of the taken for patients in the IAT group, while those of the healthy side were taken for patients in the Achilles tendon was defined as the MA length. In addition, the angle between the Achilles tendon control group. As described by Manja et al. [10], who used plain X-ray images of the feet during moment arm and the line from the center of the ankle joint movement to the insertion of the Achilles weight-bearing, the weight-bearing plane was taken as the plantar axis from the lateral image; a tendon was defined as the angle (Figure 3). The central axis of the Achilles tendon at the time straight line perpendicular to this plantar axis, passing through the center of the Achilles tendon, was of postoperative measurement was the midpoint from the most dorsal surface to the bottom of the set as the central axis of the Achilles tendon. The shortest distance from the central axis of the Achilles insertion (Figure 4). Also, the ratio of the MA length/foot length was used to standardize the dierence tendon to the center of the first metatarsal head parallel to the plantar axis was defined as the length in foot size. Furthermore, in order to take the influence of body weight into account, the force applied of the sole. A perfect circle was drawn to fit the pulley surface of the talus, and the center point was to the Achilles tendon at the time of heel raise can be calculated as the rotational force around the ankle used as the center of motion. The shortest distance from the center of motion to the central axis of the joint axis. Then, the force applied to the Achilles tendon, F, can be estimated by: Achilles tendon was defined as the MA length. In addition, the angle between the Achilles tendon moment arm and the line from the center of the ankle joint movement to the insertion of the Achilles F = w (L MA)/MA tendon was defined as the α angle (Figure 3). The central axis of the Achilles tendon at the time of postoperative measurement was the midpoint from the most dorsal surface to the bottom of the where w is the body weight, MA is the Achilles tendon moment arm length, and L is the length of the insertion (Figure 4). Also, the ratio of the MA length/foot length was used to standardize the sole [14,18,19] (Figure 5). In the present study, this formula was used to calculate the force applied difference in foot size. Furthermore, in order to take the influence of body weight into account, the to the Achilles tendon, and the average value of three measurements performed by one examiner force applied to the Achilles tendon at the time of heel raise can be calculated as the rotational force was used. around the ankle joint axis. Then, the force applied to the Achilles tendon, F, can be estimated by: Both the control group and the IAT group were examined, and all measurements were taken pre- F = w × (L − MA)/MA and post-operatively. Statistical tests were performed using Microsoft Excel. Data were tested using unpaired student t-tests, and eects were considered significant at 95% CI and p < 0.05. All subjects gave where w is the body weight, MA is the Achilles tendon moment arm length, and L is the length of their informed consent for inclusion before they participated in the study. The study was conducted in the sole [14,18,19] (Figure 5). In the present study, this formula was used to calculate the force applied accordance with the Declaration of Helsinki, and the protocol was approved by the Ethics Committee to the Achilles tendon, and the average value of three measurements performed by one examiner was of Nara Medical University (Approval number: 2740). used. Figure 3. Cont. Appl. Sci. 2020, 10, 6631 5 of 11 Appl. Sci. 2020, 10, x FOR PEER REVIEW 5 of 11 Appl. Sci. 2020, 10, x FOR PEER REVIEW 5 of 11 Appl. Sci. 2020, 10, x FOR PEER REVIEW 5 of 11 Figure 3. The measurement of the lateral weightbearing radiograph were (A) the centerline of the Figure 3. The measurement of the lateral weightbearing radiograph were (A) the centerline of the Figure 3. The measurement of the lateral weightbearing radiograph were (A) the centerline of the Figure 3. The measurement of the lateral weightbearing radiograph were (A) the centerline of the Achilles tendon insertion, (B) plantar axis, (C) the center of rotation of the ankle, (L) the length of the Achilles tendon insertion, (B) plantar axis, (C) the center of rotation of the ankle, (L) the length of the Achilles tendon insertion, (B) plantar axis, (C) the center of rotation of the ankle, (L) the length of the Achilles tendon insertion, (B) plantar axis, (C) the center of rotation of the ankle, (L) the length of the sole, (MA) the Achilles tendon moment arm (α). The angle between the Achilles tendon moment arm sole, (MA) the Achilles tendon moment arm (). The angle between the Achilles tendon moment arm sole, (MA) the Achilles tendon moment arm (α). The angle between the Achilles tendon moment arm sole, (MA) the Achilles tendon moment arm (α). The angle between the Achilles tendon moment arm and the line connecting the insertion point and the center of rotation. and the and the line co line connecting nnecting the in the insertion sertion point point and and the center o the center of f rotation. rotation. and the line connecting the insertion point and the center of rotation. Figure 4. B: Plantar axis. Af: Front edge of the Achilles tendon insertion. Ar: Rear edge of the Achilles Figure 4. B: Plantar axis. Af: Front edge of the Achilles tendon insertion. Ar: Rear edge of the Achilles Figure 4. B: Plantar axis. Af: Front edge of the Achilles tendon insertion. Ar: Rear edge of the Achilles Figure 4. B: Plantar axis. Af: Front edge of the Achilles tendon insertion. Ar: Rear edge of the Achilles tendon insertion. The central axis of Ar and Af was defined as Ap (the central axis of post-operated tendon insertion. The central axis of Ar and Af was defined as Ap (the central axis of post-operated tendon insertion. The central axis of Ar and Af was defined as Ap (the central axis of post-operated tendon insertion. The central axis of Ar and Af was defined as Ap (the central axis of post-operated Achilles tendon insertion). Achilles tendon insertion). Achilles tendon insertion). Achilles tendon insertion). Figure 5. (A) The centerline of the Achilles tendon insertion, (C) the center of rotation of the ankle, (L) the length of the sole, and (MA) the Achilles tendon moment arm. (F) Traction force of the Achilles tendon. (W) Reaction force by body weight. We calculated F using principle of lever. Appl. Sci. 2020, 10, x FOR PEER REVIEW 6 of 11 Figure 5. (A) The centerline of the Achilles tendon insertion, (C) the center of rotation of the ankle, (L) the length of the sole, and (MA) the Achilles tendon moment arm. (F) Traction force of the Achilles tendon. (W) Reaction force by body weight. We calculated F using principle of lever. Both the control group and the IAT group were examined, and all measurements were taken pre- and post-operatively. Statistical tests were performed using Microsoft Excel. Data were tested using unpaired student t-tests, and effects were considered significant at 95% CI and p < 0.05. All subjects gave their informed consent for inclusion before they participated in the study. The study was conducted in accordance with the Declaration of Helsinki, and the protocol was approved by the Appl. Sci. 2020, 10, 6631 6 of 11 Ethics Committee of Nara Medical University (Approval number: 2740). 3. Results 3. Results The average height of subjects in the healthy group was 163 7.4 cm, with average body weight The average height of subjects in the healthy group was 163 ± 7.4 cm, with average body weight and BMI of 64.5 12.1 kg and 24.3 4.8 kg/m 2 , respectively. The average height of subjects in the IAT and BMI of 64.5 ± 12.1 kg and 24.3 ± 4.8 kg/m , respectively. The average height of subjects in the IAT groups was 163.613.3 cm, with average body weight and BMI of 73.5 11.0 kg and 27.7 4.5 kg/m2 , groups was 163.6 ±13.3 cm, with average body weight and BMI of 73.5 ± 11.0 kg and 27.7 ± 4.5 kg/m , respectively. Thus, there was no significant dierence between the groups for these items (Table 1). respectively. Thus, there was no significant difference between the groups for these items (Table 1). Table 1. Patient Characteristics. Table 1. Patient Characteristics. IAT Control p Value IAT Control p Value n 10 feet (8 people) 15 feet (15 people) n 10 feet (8 people) 15 feet (15 people) Sex Male: 4 Female: 4 Male: 8 Female: 7 Sex Male: 4 Female: 4 Male: 8 Female: 7 Age, y 55.5 ± 14.4 37.4 ± 16.2 Age, y 55.5 14.4 37.4 16.2 Height, cm Height, cm 164 164 ± 13 13.3 .3 163 163 ± 7 7.44.44 >0.05 >0.05 Body weight, kg 73.5 11.0 64.5 12.1 >0.05 Body weight, kg 73.5 ± 11.0 64.5 ± 12.1 >0.05 BMI, kg/m 27.7 4.58 24.3 4.83 >0.05 BMI, kg/m 27.7 ± 4.58 24.3 ± 4.83 >0.05 Abbreviations: IAT, insertional Achilles tendinopathy. BMI, body mass index. Values are given as mean standard Abbreviations: IAT, insertional Achilles tendinopathy. BMI, body mass index. Values are given as deviation (SD). mean ± standard deviation (SD). The AOFAS scale and VAS improved in all cases (AOFAS scale: Preoperative averaged 71.7, The AOFAS scale and VAS improved in all cases (AOFAS scale: Preoperative averaged 71.7, postoperative averaged 92.3; VAS: Preoperative averaged 5.0, postoperative averaged 0.83). postoperative averaged 92.3; VAS: Preoperative averaged 5.0, postoperative averaged 0.83). MRI assessment after surgery for IAT revealed Achilles tendon insertion running from the proximal MRI assessment after surgery for IAT revealed Achilles tendon insertion running from the knotless anchor insert to the distal knotless anchor insert via the suture bridge technique in all cases proximal knotless anchor insert to the distal knotless anchor insert via the suture bridge technique in (Figure 6). Also, MRI findings showed the disappearance of abnormal signals in the Achilles tendon in all cases (Figure 6). Also, MRI findings showed the disappearance of abnormal signals in the Achilles all cases. tendon in all cases. Figure 6. The MRI images of T2-weighted images of the same patient. ↔: Length of Achilles tendon Figure 6. The MRI images of T2-weighted images of the same patient. $: Length of Achilles tendon insertion. (A): Pre-operation of the Achilles tendon insertion. (B): Post-operation of the Achilles insertion. (A): Pre-operation of the Achilles tendon insertion. (B): Post-operation of the Achilles tendon tendon insertion. We can see the postoperative Achilles tendon insertion presence from the proximal insertion. We can see the postoperative Achilles tendon insertion presence from the proximal knotless knotless anchor insert to the distal knotless anchor insert. anchor insert to the distal knotless anchor insert. There was no significant dierence in the angle between the control and IAT groups. The ratio There was no significant difference in the α angle between the control and IAT groups. The ratio 3 2 −3 −2 of MA length/foot length was 0.30 0.9 10 , in the control group, 0.31 1.0 10 , in the IAT of MA length/foot length was 0.30 ± 0.9 × 10 , in the control group, 0.31 ± 1.0 × 10 , in the IAT group group preoperatively, and 0.27 0.2 10 in the IAT group postoperatively, showing significant dierences between these groups (p < 0.05). The force applied to the Achilles tendon was 148.5 24.9 kg in the control group, 166.2 23.0 kg in the IAT group preoperatively, and 200.8 25.4 kg in the IAT group postoperatively. Despite no significant dierence in the force between the control and preoperative IAT groups, a significantly higher force to the Achilles tendon was observed in the IAT group postoperatively, compared to the other groups (p < 0.05) (Figure 7). Appl. Sci. 2020, 10, x FOR PEER REVIEW 7 of 11 −1 preoperatively, and 0.27 ± 0.2 × 10 in the IAT group postoperatively, showing significant differences between these groups (p < 0.05). The force applied to the Achilles tendon was 148.5 ± 24.9 kg in the control group, 166.2 ± 23.0 kg in the IAT group preoperatively, and 200.8 ± 25.4 kg in the IAT group postoperatively. Despite no significant difference in the force between the control and preoperative IAT groups, a significantly higher force to the Achilles tendon was observed in the IAT group postoperatively, compared to the other groups (p < 0.05) (Figure 7). Appl. Sci. 2020, 10, 6631 7 of 11 Appl. Sci. 2020, 10, x FOR PEER REVIEW 8 of 11 Figure 7. Radiographic Measurement. (A): Comparison of the angle between the control and Figure 7. Radiographic Measurement. (A): Comparison of the α angle between the control and pre- pre-operative IAT groups. (B): Comparison of the ratio of MA length/foot length between the control operative IAT groups. (B): Comparison of the ratio of MA length/foot length between the control group, the preoperative IAT group, and the postoperative IAT group, showing significant dierences group, the preoperative IAT group, and the postoperative IAT group, showing significant differences between these groups (p < 0.05). (C): Comparison of the force applied to the Achilles tendon between between these groups (p < 0.05). (C): Comparison of the force applied to the Achilles tendon between the control group, the preoperative IAT group, and the postoperative IAT group, showing that a the control group, the preoperative IAT group, and the postoperative IAT group, showing that a significantly higher force to the Achilles tendon was observed in the IAT group postoperatively, significantly higher force to the Achilles tendon was observed in the IAT group postoperatively, compared to the other groups (p < 0.05). Values are given as mean SD. compared to the other groups (p < 0.05). Values are given as mean ± SD. 4. Discussion COR method and TE methods are mainly used for the measurement of the lever arm of Achilles tendon [5]. It has been reported that the TE method shows a shorter moment arm than the COR method [5]. However, it has also been reported that there is no difference in measurements between the two methods [20]. Thus, there is no unified view on this issue. Furthermore, the Achilles tendon moment arm has been shown to be influenced by weight-bearing [21], and an evaluation method using weight-bearing X-ray has been developed for taking images during weight-bearing [10]. It is also feasible to use radiographs to measure the Achilles tendon moment arm [10]. In the present study, we examined the group of patients with IAT before and after surgery, in comparison to a control group of healthy individuals. In order to measure the moment arm and evaluation of the morphology of the bone during weight-bearing in each group, we decided to use a weight-bearing X-ray for evaluation. Also, the usage of an X-ray is a simple method and allows us to perform anatomical calculations easily. Therefore, we determined that it was a good method in our study. A study using this measurement method reported a moment arm length of 64.3 mm [10]. In the present study, the average moment arm lengths of the healthy and IAT groups were 51.7 mm and 53.7 mm, respectively, both of which were shorter than the previously reported value. However, the length of the sole of subjects in the previous report was 185.7 mm, in contrast to 171 mm and 170.1 mm in healthy and IAT groups, respectively, in the present study. This suggests that the moment arm length may be influenced by the difference in the physical constitution. In addition, Manja et al. [10] showed that the moment arm length and α angle are influenced by the difference in the shape of the foot, such as flat and concave feet. In the present study, no significant difference in α angle between the control and experimental groups was observed, indicating that the results are not influenced by the difference in the shape of the subject’s foot, even in flat and concave feet. To date, there have been no reports comparing the Achilles tendon moment lengths between healthy individuals and patients with IAT, but many factors are known to influence the pathophysiology of IAT. Lyman et al. [22] stated that it is caused by the traction force of the Achilles tendon during ankle movement. In the present study, those with IAT had a significantly longer Appl. Sci. 2020, 10, 6631 8 of 11 4. Discussion COR method and TE methods are mainly used for the measurement of the lever arm of Achilles tendon [5]. It has been reported that the TE method shows a shorter moment arm than the COR method [5]. However, it has also been reported that there is no dierence in measurements between the two methods [20]. Thus, there is no unified view on this issue. Furthermore, the Achilles tendon moment arm has been shown to be influenced by weight-bearing [21], and an evaluation method using weight-bearing X-ray has been developed for taking images during weight-bearing [10]. It is also feasible to use radiographs to measure the Achilles tendon moment arm [10]. In the present study, we examined the group of patients with IAT before and after surgery, in comparison to a control group of healthy individuals. In order to measure the moment arm and evaluation of the morphology of the bone during weight-bearing in each group, we decided to use a weight-bearing X-ray for evaluation. Also, the usage of an X-ray is a simple method and allows us to perform anatomical calculations easily. Therefore, we determined that it was a good method in our study. A study using this measurement method reported a moment arm length of 64.3 mm [10]. In the present study, the average moment arm lengths of the healthy and IAT groups were 51.7 mm and 53.7 mm, respectively, both of which were shorter than the previously reported value. However, the length of the sole of subjects in the previous report was 185.7 mm, in contrast to 171 mm and 170.1 mm in healthy and IAT groups, respectively, in the present study. This suggests that the moment arm length may be influenced by the dierence in the physical constitution. In addition, Manja et al. [10] showed that the moment arm length and angle are influenced by the dierence in the shape of the foot, such as flat and concave feet. In the present study, no significant dierence in angle between the control and experimental groups was observed, indicating that the results are not influenced by the dierence in the shape of the subject’s foot, even in flat and concave feet. To date, there have been no reports comparing the Achilles tendon moment lengths between healthy individuals and patients with IAT, but many factors are known to influence the pathophysiology of IAT. Lyman et al. [22] stated that it is caused by the traction force of the Achilles tendon during ankle movement. In the present study, those with IAT had a significantly longer Achilles tendon moment arm than healthy individuals. However, there was no significant dierence in the force applied to the Achilles tendon between two groups. This indicates that the traction force of the Achilles tendon, which is the cause of IAT, is not influenced simply by the force applied to the Achilles tendon. It has been shown that the Achilles tendon exerts approximately 4 to 6 times its weight during running [23,24], stretching approximately 8% of the total length of the Achilles tendon [25]. It has also been shown that, despite the smaller force applied during walking than in running, approximately 7% of the total length of the Achilles tendon is stretched during walking [26]. This indicates that the insertion of the Achilles tendon is influenced not only by simple tension but also by the elastic energy due to the stretching of the Achilles tendon [27]. In fact, triceps surae eccentric exercise has been recommended as a conservative therapy for IAT [28,29], and the extension of the Achilles tendon is a major cause of IAT. Our data revealed that individuals with IAT had a longer moment arm length than healthy individuals. This suggests that, with a long moment arm, the arc length associated with the ankle rotation lengthens, increasing the length displacement of the muscle-tendon complex, and further increasing the elastic energy consumption of the Achilles tendon [13,14]. Therefore, the elasticity of the Achilles tendon is shown to be greatly responsible for the development of IAT. In addition, any measurements of the moment arm length before and after surgery using the suture bridge technique have not been reported to date. As a surgical treatment for IAT, the calcaneal wedge osteotomy takes the influence of the moment arm into account and aims to reduce stress on the insertion of the Achilles tendon by shortening the calcaneus length and slightly lifting the insertion of the Achilles tendon [30]. The suture bridge technique used in the present study has also been reported to have good long-term outcomes [17,31]. This method can treat various pathological conditions that influence IAT with minimal invasion [31]. Furthermore, by comparing the preoperative and Appl. Sci. 2020, 10, 6631 9 of 11 postoperative data in this study, the postoperative Achilles tendon moment arm was found to be shortened. On the other hand, the force applied to the Achilles tendon was significantly increased in individuals with IAT compared to healthy individuals. This indicates that this method may not reduce the force applied to the Achilles tendon. Rather, it may reduce the length displacement of the Achilles tendon by reducing the Achilles tendon moment arm, thereby reducing the energy applied to the Achilles tendon. There are three limitations to this study. First, the number of cases was small. The study needs to proceed with an increased number of cases, and proper statistical analysis needs to be performed. Secondly, the Achilles tendon insertion is an area, but for the sake of simplicity, it was considered to be a point. Performing 3D analyses allows more precise analyses, and we will need to investigate the area of the Achilles tendon insertion. Third, the moment arm measurement method used in this study was the static evaluation. An X-ray or MRI scan is required to measure the Achilles tendon moment arm after the reconstruction of Achilles tendon insertion using the suture bridge technique. However, it is dicult to measure the dynamic change of the moment arm before and after surgery with the measurement methods reported to date. Therefore, a new measurement method needs to be developed for measuring a dynamic moment arm using X-ray or ultrasonic waves in the future. 5. Conclusions In this study, we examined the moment arm in patients with IAT before and after undergoing the suture bridge technique compared to that of healthy individuals. The Achilles tendon moment arm was significantly longer in patients with IAT. We hypothesized that the suture bridge technique for IAT influences the moment arm length. To test this, we examined the changes in the moment arm length of patients with IAT before and after the surgery by analyzing the X-ray images of the lateral side of their feet during under weight-bearing. This study demonstrates that a long moment arm may be one of the causes of IAT, and the suture bridge technique may reduce the Achilles tendon moment arm. These findings suggest that it is important to consider the influence of the Achilles tendon moment arm in the treatment of IAT. Author Contributions: Conceptualization, Y.S.; methodology, Y.S. and T.M. (Takuma Miyamoto); software, T.M. (Takuma Miyamoto); validation, T.M. (Takuma Miyamoto), Y.S. and Y.T.; formal analysis, T.M. (Takuma Miyamoto); investigation, T.M. (Takuma Miyamoto); resources, Y.T., T.K., A.T., H.K. and T.M. 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Intermediate and long-term outcomes of the suture bridge technique for the management of insertional Achilles tendinopathy. Foot Ankle Spec. 2013, 6, 185–190. [CrossRef] [PubMed] © 2020 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
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