ABSTRACT
Objective:To compare the morphological differences of psoas major muscles between patients with lumbar disc herniation (LDH) of lower limb pain and lumbocrural pain based on CT imaging data.Methods:Sixty patients with LDH admitted to Department of Neurosurgery, 900 th Hospital of PLA Joint Logistic Team from January 2012 to February 2023 were included. According to clinical symptoms, they were divided into lower limb pain group and lumbocrural pain group ( n=30). 3D CT images of the psoas major muscles in the 2 groups were reconstructed; the longest transverse axis perpendicular to the longitudinal axis of the psoas major muscle was chosen as the cross-sectional area, and the maximum psoas major muscle cross-sectional area was calculated; maximum psoas major muscle cross-sectional area index (PI max) was defined as ratio of maximum psoas major muscle cross-sectional area and L 5 vertebral cross-sectional area. PI max difference between lower limb pain group and lumbocrural pain group was compared; PI max difference among patients with different pain degrees (visual analog scale [VAS] scores) or pain courses was further compared in both lower limb pain group and lumbocrural pain group. Pearson correlation was used to analyze the correlations of PI max with pain degree and pain course in the 2 groups. Results:PI max in lower limb pain group was significantly larger than that in lumbocrural pain group (0.62±0.05 vs. 0.54±0.04, t=7.320, P<0.001). PI max in patients with severe pain from both lower limb pain group and lumbocrural pain group was significantly smaller than that in patients with moderate pain (0.61±0.05 vs. 0.65±0.04, t=2.422, P=0.022; 0.53±0.03 vs. 0.58±0.04, t=3.502, P=0.002). PI max in patients with short pain course from both lower limb pain group and lumbocrural pain group was significantly larger than that in patients with long pain course (0.64±0.05 vs. 0.59±0.04, t=2.570, P=0.016; 0.57±0.04 vs. 0.53±0.03, t=2.941, P=0.007). Pearson correlation showed that PI max was negatively correlated with pain degree and pain course in LDH patients from both groups ( P<0.05). Conclusion:Atrophy of psoas major muscles in LDH patients is aggravated with increased pain degree and pain course.
ABSTRACT
In the present study, we examined the sex-related differences and cross-sectional age-related changes in the cross-sectional area of the psoas major muscle. The cross-sectional area was corrected for fat-free mass (FFM-corrected), which was calculated as the 2/3rd power of the total fat-free mass. A total of 240 adults (114 men, 126 women, age: 20-81 years) were included in the study. The cross-sectional area of the psoas major muscle was measured by 0.2T magnetic resonance imaging (MRI), and the total fat-free mass was measured by air displacement plethysmography. We demonstrated that the FFM-corrected cross-sectional area of the psoas major muscle was greater in males than females across all age groups. Furthermore, we examined the mean FFM-corrected cross-sectional area of the psoas major muscle across different age groups and demonstrated that it decreased with age. Our findings, when combined with previous results, show a peak in the 20s, which declined with age. Our study revealed sex-related differences and cross-sectional age-related changes in the FFM-corrected cross-sectional area of the psoas major muscle. Our findings also suggest that it is important to define reference values and ranges that take into account age- and sex-related differences when assessing the psoas major muscle by FFM-corrected cross-sectional area.
ABSTRACT
The purpose of this study was to examine the relationships between running performance and the cross–sectional area of the psoas major, peak oxygen uptake, and running economy in male junior long–distance runners. The subjects were 37 male junior athletes who achieved good records in interscholastic athletic competition during 5 years (2011–2015). Their seasonal best times in a 5,000 m race (5,000m–SB) were 14:04.11 ± 0:07.25 (13:53.64–14:16.15). In a multiple regression analysis, 5,000m–SB was statistical significantly correlated with the cross–sectional area of psoas major (16.0 ± 1.7 cm<sup>2</sup>) measured on magnetic resonance imaging and peak oxygen uptake (4.25 ± 0.36 l min<sup>-1</sup> [76.9 ± 5.8 ml min<sup>-1</sup> kg<sup>-1</sup>]) during a lactate curve test comprising five stages. However, 5,000m–SB was not related to oxygen uptake at the work–load which was less than the load at the lactate threshold estimated by using the lactate curve test results. These results suggest that a high volume of the psoas major, the largest hip–flexor muscle, and peak oxygen uptake are among the important factors for junior long–distance runner performance.
ABSTRACT
Dynamic postural control ability is necessary for fall prevention in our daily lives. It has been suggested that dynamic postural control ability is highly related to the muscles in the trunk as well as the lower limbs for the keep and move of the body. In this study, we reveal relationship between dynamic postural control ability and abdominal area. Subjects including 31 middle-aged people consist of 12 men and 19 women (mean age 60.0±7.6 years). We measured visceral fat area and cross-sectional area of the trunk muscle using abdominal computed tomography scan. The unstable tilt board is used for measuring dynamic postural control ability. Through multiple regression analysis, it is possible to relate dynamic postural control ability from gender, visceral fat, and deep trunk muscle such as psoas major muscle on abdominal computed tomography scan. It is considered that dynamic postural control ability involved not only increasing the volume of deep trunk muscle but also decreasing the amount of visceral fat.
ABSTRACT
Femoral nerve is used for nerve block in several surgeries and is vulnerable to compression in tight ilio-psoas compartment. The knowledge of origin and variations of femoral nerve in iliac fossa is important for anatomists, anesthetists and surgeons to prevent iatrogenic femoral nerve palsy. We dissected 32 human cadavers to study the anatomy of the femoral nerve. We dissected the lumbar plexus bilaterally; dissected the psoas major muscle to see formation of the femoral nerve. We measured the length of the femoral nerve from its formation to inguinal ligament; and recorded variations of the femoral nerve with digital photography. The average length of the femoral nerve was 144 mm. Anatomical variations of the femoral nerve were found in 25% lumbar plexuses. These variations included abnormally long L2 root, early division of the femoral nerve, origin of lateral cutaneous nerve of thigh from the femoral nerve, origin of nerve to pectineus from the femoral nerve in iliac fossa, splitting of the femoral nerve into two slips by psoas major or accessory slips of iliacus muscle. The aim of this study was to highlight variations in branching pattern of the femoral nerve in iliac fossa for appropriate exposure of the femoral nerve.
ABSTRACT
The purpose of this study was to investigate sex differences in the muscle volume (MV) of the iliopsoas, psoas major, and iliacus muscles, normalized by fat free mass (FFM), in the elderly. The subjects were 15 males and 15 females 65 years of age or over. Serial transverse 1.5T magnetic images (10 mm slice) of each subject were taken between the 12<sup>th</sup> thoracic vertebrae and the lesser trochanter. FFM was measured with a bioelectrical impedance analyzer. The mean MV of each muscle on the right and left sides were calculated and used for regression analysis of the relationship between MV and FFM.A significant correlation was observed between MV and FFM of the iliacus in both sexes (p<0.01), but not between the MV and FFM of the psoas major. MV normalized by FFM and cross-sectional area (CSA) normalized by FFM<sup>2/3</sup> showed significantly greater values for the psoas major in the males than in the females (p<0.001), but there was no sex difference in the MV or CSA normalized by FFM of the iliacus.These results suggest that elderly males tend to have a greater muscle volume and cross-sectional area of the iliopsoas than elderly females, and that these sex differences are attributable to differences in the psoas major.
ABSTRACT
The aim of this study is to establish a new dynamic model for balance keeping control in upright standing; and to deduce the underlying possible control mechanism of central neuronal system with a special concern on the roles of pelvis and its muscles. The dynamic model including five joints, i. e. two ankles, two hips and one lumbosacral making up a multi-link system being driven by two pairs of muscles, the psoas major (PM) and glutaeus medius (GM). In coronal section, experimental data shows the ankle and lumbosacral sway in almost the same amplitude, whereas their phase difference is approximately equal to π. The results indicate that the trunk is keeping perpendicularly to horizon during the standing process. By defining the model's physical parameters, assuming that the corrective torque needed for balance keeping process is regulated by PID (stands for proportional, integral and derivative) control, the body sway can be simulated. The simulation result is quite consistent with the experimental data suggests that the pelvis is one of the most important structure in balance keeping, moreover, the dynamics of the present proposed balance keeping model is a quite useful model for analyzing the posture sway.
ABSTRACT
In order to clarify the effect of exercise on the walking performance and the muscle volume in lower limbs, elderly athletes long continuing to be trained and untrained elderly were compared with regard to their muscle cross-sectional area (CSA) of m. psoas major, thigh muscle and crus muscle and their walking ability. The subjects used consisted of thirty-six 80's-aged male and 70's-aged female elderly athletes and twenty-four elders having no regular exercise (control male group : CM, control female group : CF) . The elderly athletes were further divided into two groups in accordance with their results of Japan Fitness Test (high performance male group : HPM, low performance male group : LPM, high performance female group : HPF, low performance female group : LPF) . The walking performance was evaluated by analyzing their walking speed, stride-length and step rate during walking along a 15 m-strip of passage at normal and fast paces using videotaping. The muscle CSA was determined at m. psoas major, thigh muscle (extensors and flexors) and crus muscle (m. tibialis anterior and m. triceps surae) using MRI. As for the walking speed and stride-length at the normal pace, only HPM and HPF showed significantly higher values than CM and CF (male : p<0.05, female : p<0.01) . Meanwhile at the faster pace, HPF and LPF showed significantly higher values than CF in female (HPF : p<0.01, LPF : p<0.05) and in the case of males, only HPM have a higher value only of the walking speed than CM (p<0.05) . The CSA of m. psoas major in HPM and HPF significantly higher than that in CM and CF (all p<0.05), while in CSAs of knee extensor muscles and m. triceps surae, the statistical differences were not consistent among male and female groups. The results suggested that greater muscle mass of m. psoas major could influence higher walking speed in elderly people, and might be affected by regular exercise training.
ABSTRACT
The purpose of this study was to investigate the hypothesis that the reduction in walking ability is due to muscle atrophy in the lower limb muscles with aging using equational structure modeling as well as investigate the influence of muscle on walking ability. The subjects consisted of 127 persons (57 males and 70 females) aged 20-84 year, who were grouped into 6 age brackets of 20-39, 40-49, 50-59, 60-69, 70-74, and 75 or older. Using MRI, muscle cross-sectional area was measured on psoas major and thigh muscle (divided into extensor and flexor) . For walking patterns, each subject walked along a 7-m walking passage at normal speed for VTR-recording of the motion. The resulting pictures were used to analyze stride length, trunk inclination and walking speeds. Walking speeds showed a statistically significant decrease in value from the 50's age group in males and the 60's age group in females when compared with the 20-39 age bracket (p<0.05) . In males, a significant co-relationship was observed only between the muscle cross-sectional area of thigh extensor and walking speed (p<0.01) while in females, a significant co-relationship was found between the muscle cross-sectional area of psoas major (p<0.001) /thigh muscle extensor (p<0.01) and walking speed. These results indicate that the muscle atrophy with aging in psoas major and thigh muscle extensor is a factor responsible for the decrease in walking speed. Meanwhile, a difference in sex was observed between the muscle cross-sectional area of psoas major and walking speed. It was considered that the muscle atrophy rate of the female's psoas major being higher than the male's influenced this. Furthermore, it was suggested possibility that the decline of walking ability is due to decreased muscle mass of the lower limbs with aging.