Anthropometric evaluation of side, sex and age by radiological examination of the normal ankle joint among adult Egyptian population

Wael Amin Nasr El-Din (Department of Anatomy, College of Medicine and Medical Science, Arabian Gulf University, Manama, Bahrain) (Department of Human Anatomy and Embryology, Faculty of Medicine, Suez Canal University, Ismailia, Egypt)
Mona Hassan Mohammed Ali (Department of Human Anatomy and Embryology, Faculty of Medicine, Suez Canal University, Ismailia, Egypt)
Gisma Ahmed Madani (Department of Anatomy, Faculty of Medicine, National University - Sudan, Khartoum, Sudan)
Islam Omar Abdel Fattah (Department of Human Anatomy and Embryology, Faculty of Medicine, Suez Canal University, Ismailia, Egypt)

Arab Gulf Journal of Scientific Research

ISSN: 1985-9899

Article publication date: 12 December 2023

Issue publication date: 28 November 2024

357

Abstract

Purpose

Sex and age estimation is important, particularly when information about the deceased is unavailable. There are limited radiological studies investigating side, sex and age differences in normal ankle morphometric parameters. The authors’ goal was to evaluate different ankle joint morphometric measurements and document variations among Egyptians.

Design/methodology/approach

A prospective study was conducted throughout 23 months on 203 (100 males and 103 females) adult Egyptians, aged between 20-69 years old, who were referred for a plain x-ray of bilateral normal ankle joints.

Findings

Ankle parameters showed no statistical difference between both sides, except for tarsal width (TaW) which was significantly higher on right than left side (26.92 ± 2.66 vs 26.18 ± 2.65 mm). Males showed significantly higher morphometric values except for anteroposterior gap (APG) and talus height (TaH) which were significantly higher in females (2.29 ± 0.80 vs 1.80 ± 0.61 mm and 13.01 ± 1.68 vs 11.87 ± 1.91 mm, respectively). There was significant increase in tibial arc length, APG, distance of level of MTiTh from anterior limit of mortise, distance of level of MTiTh from vertex of mortise, sagittal distance between tibial and talar vertices and sagittal radius of trochlea tali arc in old age group compared to young one. A significant decrease in tibial width, malleolar width, TaW and TaH was noted in old age group compared to young one.

Originality/value

Ankle joints of both sides are mostly symmetrical; however, there are significant differences in most morphometric values due to sex and age factors. These findings may be essential during side, sex and age determination.

Keywords

Citation

Nasr El-Din, W.A., Mohammed Ali, M.H., Madani, G.A. and Abdel Fattah, I.O. (2024), "Anthropometric evaluation of side, sex and age by radiological examination of the normal ankle joint among adult Egyptian population", Arab Gulf Journal of Scientific Research, Vol. 42 No. 4, pp. 1555-1576. https://doi.org/10.1108/AGJSR-05-2023-0207

Publisher

:

Emerald Publishing Limited

Copyright © 2023, Wael Amin Nasr El-Din, Mona Hassan Mohammed Ali, Gisma Ahmed Madani and Islam Omar Abdel Fattah

License

Published in Arab Gulf Journal of Scientific Research. Published by Emerald Publishing Limited. This article is published under the Creative Commons Attribution (CC BY 4.0) licence. Anyone may reproduce, distribute, translate and create derivative works of this article (for both commercial and non-commercial purposes), subject to full attribution to the original publication and authors. The full terms of this licence may be seen at http://creativecommons.org/licences/by/4.0/legalcode


Introduction

Estimation of sex and age is more reliable in the case of an available complete skeleton for analysis (Abdel Moneim, Abdel Hady, Abdel Maaboud, Fathy, & Hamed, 2008). Nevertheless, in forensic cases, human skeletal remains are often damaged or incomplete, especially in a crime investigation or a mass disaster (Alkass et al., 2010). In addition, it is highly accepted that skeletal morphometric parameters vary among different populations; thus, each population should have its own specific standards to allow more improvement in the accuracy of identification (Hayes, Tochigi, & Saltzman, 2006; Kuo et al., 2008; Khanasuk, Itiravivong, Tangpronprasert, & Virulsri, 2011; Kwon et al., 2014; Uzuner et al., 2018; Garg et al., 2022; Ghalawat, Sharma, Singh, & Malik, 2022).

Frequently, the skull, pelvis and long bones are damaged or absent, so the prediction of sex or age should be directed toward other parts of the skeleton. Nevertheless, the accuracy level of identification from other skeletal elements depends on their degree of difference (Abdel Moneim et al., 2008). For example, in previous studies, foot skeletal components have been used for sex assessment, such as metacarpal bones (Zanella & Brown, 2003), and calcaneus and talus (Introna, Di Vella, Ampobasso, & Dragone, 1997). However, the availability of knowledge about the geographical origin or the ethnic group of the victim for the anthropologist is important before sex and age determination (Abdel Moneim et al., 2008). Similarly, little data are available regarding the morphological variability of the human ankle regarding age and sexual dimorphism (Angthong et al., 2020).

The measurement methods used for ankle morphometry are widely varying (Khanasuk et al., 2011). Cadaveric specimens, radiographs, and computerized tomography images are mostly applied to obtain detailed ankle morphometric parameters (Han et al., 2019).

Therefore, the purpose of the current study was to document the morphometric parameters of the human ankle joint obtained by x-ray radiographs regarding side, sex and age-based differences among Egyptians.

Methods

Study design

A prospective study was conducted on 203 subjects who met the criteria, including 100 males and 103 females with ages ranging from 20-69 years old. These cases were referred to the Radiology Department of Suez Canal University Hospital from the Orthopedic and Physiotherapy Clinics to perform ankle joint plain x-ray radiographs in the period between January 2020 and December 2021. This study was approved by the Research Ethics Committee of the Faculty of Medicine, Suez Canal University (approval No. 5046#). In addition, informed consent from the enrolled subjects was obtained. Only Egyptian subjects whose parents and grandparents are Egyptians with normal ankle joints were included in this study, while patients with a history of ankle joint surgery, fracture, tumor, inflammation, deformation or congenital anomaly were excluded from the study. Furthermore, low-quality radiographs were not utilized in this study.

Plain x-ray procedures

Ankle radiographs were obtained by using a radiographic image unit (GE Healthcare, Chicago, IL) set to 60 kVp and 6.3 mA at a distance of 110 cm. In anteroposterior radiographs, subjects stood with equal weight-bearing on both inverted feet, whereas in lateral views, subjects stood with equal weight-bearing on a support fixture and the cassette was held between both feet with the medial and lateral malleoli placed on each side of the cassette (Kwon et al., 2014).

While taking x-ray radiographs, a metal rod with a known actual length was placed beside the ankle joint to use it for calibration during the morphometric analysis of the radiographic images. To ensure accurate calibration, this metal rod was applied at an angle of 90° to the horizontal ground surface.

All measurements were performed using ImageJ® software (Wayne Rasband NIH, Bethesda, MA, USA) by only one well-trained investigator to reduce the inter-observer bias. This investigator carried out the study measurements three times with at least a one-month interval between each to ensure minimal intra-observer bias and high repeatability of the morphometric procedures. The mean of these three measurements of each parameter was recorded.

Morphometric parameters

Radiographs were displayed on a picture archiving and communication system software program to perform the morphometric analysis of the components of the ankle joint (Stagni, Leardini, Ensini, & Cappello, 2005; Yurttas et al., 2018) which are shown in Figure 1 and Table 1.

Evaluation of asymmetry

Percent directional asymmetry (%DA) was used for the assessment of the directional asymmetry in the tibial and talar measured parameters. It was calculated as follows:

%DA =(RL)/(1/2(R+L))×100%
Where (L) is the left-side measurement, while (R) is the right-side measurement. The percent above zero means that there are right-side asymmetries, whereas the percent below zero means that there are left-side asymmetries.

A quantitative measure of directional asymmetry in each parameter was calculated by the percent absolute asymmetries (%AAs) to evaluate the degree of asymmetry, irrespective of its directionality, as follows:

%AA =(MaxMin)/(1/2(Max+Min))×100%
Where (Max) is the maximum measurement, while (Min) is the minimum measurement (Auerbach & Ruff, 2006).

Statistical analysis

Data analysis was performed using Statistical Package for Social Sciences (SPSS) software version 27.0 for Windows (IBM Corp., Armonk, NY, USA). Data were expressed as means and standard deviations (SD), in addition to the maximal and minimal values. A paired sample Student's t-test was used to compare the means of morphometric values according to side variability. On the other hand, to test the sexual dimorphism, an unpaired t-test was performed. One-way analysis of variance (ANOVA) with Tukey post-hoc test was used to test the levels of statistical significance of the morphometric data according to the ages of the study subjects.

Regarding the %DAs and %AAs, their values were tested for normality using the Shapiro-Wilk test, which demonstrated the non-normal (non-parametric) distribution of their data. So, we evaluated the significance of the %DAs and %AAs using the Mann-Whitney U-test which is the non-parametric equivalent of the two-sample t-test.

Pearson’s correlation coefficient was performed to evaluate the relations between different study variables. The difference between the data was considered significant when the two-tailed p value was ≤0.05. The intraclass correlation coefficient (ICC) was used to assess rating reliability by comparing the variability of the three values of each parameter recorded by the same investigator. ICC values were interpreted as follows: poor reliability <0.50; moderate reliability: 0.50-0.75; good reliability: 0.75-0.90 and excellent reliability >0.90 (Koo & Li, 2016).

Results

The numbers of male and female subjects according to the age groups were expressed in Table 2. The ICC values of all parameters ranged from 0.920-0.970, indicating excellent intra-observer reliability of all recorded measurements (Table 3). According to the side of the ankle joints, only TaW of the right side was significantly higher than the left (26.92 ± 2.66 vs 26.18 ± 2.65 mm) (p = 0.005). On the contrary, there was no statistical difference between other tibial or talar morphometric parameters on both sides of the ankle joints (Tables 4 and 5).

The evaluation of asymmetry revealed that there were right-sided asymmetries in all parameters except for TiAL, SRTi and TaAL in males and for TiAL, SRTi, TaAL and Taw in females where there were left-sided asymmetries (Tables 6 and 7). However according to the %AA assessment, only APG and TiW exhibited a significant asymmetrical directional bias comparing the males and females (p = 0.042 and 0.048, respectively) (Tables 8 and 9).

Regarding the sex, MTiTh, MDV, TiW, MalW, SRTi, TaAL, TaW, SDTaTi and SRTa were significantly higher in males than females (p < 0.001, <0.001, <0.001, <0.001, <0.001, = 0.024, <0.001, <0.001 and < 0.001, respectively), while APG and TaH were significantly higher in females than males (p < 0.001 for both). Nevertheless, there was no statistically significant difference between both sexes according to TiAL, APA and MDA (p = 0.080, = 0.946 and = 0.143, respectively) (Figure 2) (Tables 10 and 11).

When age is considered, the values of TiAL, APG, APA, MDA, MDV, SDTaTi and SRTa were significantly higher in subjects aged between 60-69 years as compared to those aged between 20-29 years, while TiW, MalW, TaW and TaH were significantly lower in subjects aged between 60-69 years when compared to those aged between 20-29 years. Whereas there was no statistically significant difference between these two age groups according to MTiTh, SRTi and TaAL values (Figure 3) (Tables 12–15).

Pearson’s correlation between the age and APA was positively high (n = 203, r = 0.600, p < 0.001), while this correlation was negatively high between the age and TaH (n = 203, r = −0.531, p < 0.001). On the other hand, MDA and SDTaTi were positively moderately correlated with age (n = 203, r = 0.487 and 0.361, p = 0.165 and < 0.001, respectively); nevertheless, the correlation between age and TaAL was moderately negative (n = 203, r = −0.329, p < 0.001). The other tibial and talar parameters were weakly correlated with age (the coefficient was smaller than 0.3 or greater than −0.3) (Figure 4).

According to the correlation among different study morphometric parameters, there were moderately significant positive correlations between TiW and Taw values (n = 406, r = 0.654, p < 0.001), and between APA and MDA values (n = 406, r = 0.615, p < 0.001). On the other hand, the correlations between other parameters were weak (Table 16).

Discussion

Part of forensic investigations may be implicated in identifying a decedent. Such identification is sometimes difficult, particularly when the human remains of the victim are fragmented, decomposed or mutilated (Rich, Dean, & Cheung, 2003).

As commonly reported, the most useful anatomic structures used for subject identification are the pelvis (Fornai et al., 2021), long bones (Kiskira, Eliopoulos, Vanna, & Manolis, 2022), skull (Cappella et al., 2022), teeth (Soundarya, Jain, Shetty, & Akshatha, 2021), chest (Kalbouneh et al., 2021), and lumbar spine (Bozdag et al., 2021). However, these elements may be unavailable due to their loss or destruction, so other body regions could be useful for that, such as the foot and ankle (Rich et al., 2003).

Due to their protected nature in footwear, the feet and ankles usually escape the effects of trauma other than the rest of the body. Additionally, footwear not only slows down the process of disarticulation but also helps in the retention and preservation of foot and ankle bones. Furthermore, footwear adds a degree of protection from taphonomic alteration, e.g. animal scavenging, thus preserving the integrity of the pedal skeleton (Davies, Hackman, & Black, 2014).

Despite the use of the ankle joint in forensic investigations, which has been previously involved in medical and forensic literature (Steele et al., 1976; Singh et al., 1975; Rich, 2000; Rich et al., 2002), only a few studies have investigated the geometrical measurements of the ankle joint, and the common techniques for these measurements were plain x-ray, CT scan and MRI (Khanasuk et al., 2011).

As previously reported by Stagni et al. (2005) in Italy, all measured ankle morphometric values were higher than our reported results. Also, according to Kwon et al. (2014), all ankle parameters in the Korean population were higher than our results except for MTiTh (39.3 mm), TaAL (35.3 mm) and TaH (10.5 mm) which were lower than the values of the current study (40.9, 37.4 and 12.5 mm, respectively). In contrast, ankle joint measurements were lower than our ones with a Thai study conducted by Khanasuk et al. (2011), except for TiW (29.3 mm) and TaW (28.0 mm) which were higher than the results of the present study (28.3 and 26.6 mm, respectively).

Kuo et al. (2014) in Taiwan concluded that ankle measurements are higher than our results regarding APG (3.6 vs 2.1 mm), APA (7.4 vs 3.6°), MTiTh (42.0 vs 40.9 mm), MDA (11.4 vs 10.9 mm), MalW (63.1 vs 59.3 mm) and SDTaTi (4.5 vs 2.4 mm), while lower for TiAL (28.4 vs 28.9 mm) and TaH (11.9 vs 12.5 mm) values.

In accordance with our results, an American study by Hayes et al. (2006) reported that the mean SRTa was 20.7 mm which is slightly lower than that of the present study (21.1 mm ± 1.3 mm) (Table 17). In another study performed by Fessy, Carret, and Béjui (1997) in France, TiAL and TaAL were slightly higher than our results (30.8 vs 28.9 and 38.5 vs 37.4 mm, respectively).

The presence of bilateral asymmetry is considered normal in the human body. This may be attributable to both genetic and environmental factors (Krishan & Kanchan, 2016). In addition, the additional stress and strain on the dominant side of the body could also increase the incidence of this asymmetry (Gutnik et al., 2015).

A previous study conducted by Islam et al. (2014) using CT scan images for assessment concluded that there are small percent differences between the morphometric parameters of the left and right talus bones, supporting the fact that the tali of both sides are geometrically symmetrical based on the measurement of talus bone surface area and volume. The same results, but based on gross cadaveric assessment, were previously reported by Angthong et al. (2020) who reported that there are no statistical differences between left and right tali morphometric values, also according to both surface area and volume; however, they found that the talar dome height, middle trochlear width and posterior trochlear width of the right side were significantly higher than those of the left. In the present study, tali on both sides were symmetrical except for TaW of the right side which, was higher than the left (26.92 vs 26.18 mm). On the other hand, no statistical difference was found in this study between all other morphometric parameters of the left and right ankle joints.

Starting from the age of puberty, sex differences become apparent in bone growth. So, men develop greater bone size and higher bone mass compared to women. Recent findings attributed to the traditional concept of sex hormones are the chief regulators of this sexual dimorphism of the skeleton (Callewaert, Sinnesael, Gielen, Boonen, & Vanderschueren, 2010).

In the current study, MTiTh, MDV, TiW, MalW, SRTi, TaAL, TaW, SDTaTi and SRTa were significantly higher in males, while only APG and TaH were higher in females. According to APG, these results are in agreement with the findings of an Italian study by Stagni et al. (2005) who found that only APG and APA were significantly higher in females than males (2.7 vs 2.6 mm and 5.5 vs 4.7°, respectively). Furthermore, in accordance with our results, higher values of SRTa, MTiTh, TiW, MalW and TaW in male subjects were recorded by Khanasuk et al. (2011) in Thailand.

Kuo et al. (2014) in Taiwan and Uzuner et al. (2018) in Turkey found that MalW values were also higher in males. In contrast, both Khanasuk et al. (2011) and Kuo et al. (2014) reported that TiAL values are similar in both sexes, while the current study showed no statistical difference between male and female values according to TiAL (Table 17). As noted, the wide variability of values of ankle joint parameters among various studies could be due to different methods of evaluation.

Advances in medicine promoted increased life spans that led to the increased development of extensive lower extremity alteration due to significant musculoskeletal system changes that occur with aging, especially in post-menopausal women. For example, with age, bones lose their strength and rigidity; in addition, they become more brittle. Furthermore, joints and surrounding soft tissue become less flexible and weaker (Lee & Mulder, 2009).

In this study, TiAL, APG, APA, MDA, MDV, SDTaTi and SRTa were significantly higher in old age as compared to subjects aged 20-29 years, and significantly higher TiW, MalW, TaW and TaH values were noted in the subjects aged 20-29 years compared to those aged 60-69 years, indicating that ankle joint measurements are highly affected by age.

In addition to different methods of evaluation, the different number of involved subjects or different enrolled populations according to their ethnicity, age and sex could be the cause of the variability of the results of various studies.

Conclusion

The findings of this study among Egyptians recorded valuable details of morphometric ankle parameters that may be helpful during the identification of the side, sex and age in unknown subjects, especially when other more reliable body regions for this identification are lost or damaged.

Figures

Radiographs of the ankle joint showing the measured morphometric parameters

Figure 1

Radiographs of the ankle joint showing the measured morphometric parameters

Radiographs of ankle joints of adult male and female aged 35 years old showing a comparison between their morphometric values

Figure 2

Radiographs of ankle joints of adult male and female aged 35 years old showing a comparison between their morphometric values

Radiographs of ankle joints showing a comparison between two males of 28 and 68 years old according to their morphometric values

Figure 3

Radiographs of ankle joints showing a comparison between two males of 28 and 68 years old according to their morphometric values

Scatter plots showing the correlations between age and the different anthropometric parameters

Figure 4

Scatter plots showing the correlations between age and the different anthropometric parameters

Measured morphometric parameters of the ankle joint

(A) Lateral view (sagittal projection) parameters
1Tibial arc length (TiAL) (mm)Distance between the most anterior (A) and the most posterior (B) points of the arc of the tibial mortise
2Sagittal radius of the tibial mortise (SRTi) (mm)Radius of the circle fitting the tibial mortise profile
3Antero-posterior gap (APG) (mm)Distance between the points (A) and (B) along the longitudinal axis of the tibia
4Antero-posterior inclination angle of the tibial mortise (APA) (degrees)Inclination angle between the A-B connecting line and the tibial antero-posterior axis
5Maximal tibial thickness (MTiTh) (mm)Distance between the most tibial anterior point (C) and the corresponding posterior point (D)
6Distance of level of MTiTh from the anterior limit of the mortise (MDA) (mm)Longitudinal distance between (A) and (C) points along the tibia
7Distance of level of MTiTh from the vertex of the mortise (MDV) (mm)Longitudinal distance between the vertex of tibial mortise (V1) and the point (C)
8Trochlea tali length (TaAL) (mm)Length of the line connecting the most anterior (E) and the most posterior (F) points of the trochlea tali sagittal arc
9Sagittal radius of the trochlea tali arc (SRTa) (mm)Radius of the circle fitting the trochlea tali arc points
10Talus height (TaH) (mm)Length of the longitudinal line connecting the vertex of trochlea tali (V2) and the line connecting the most anterior (E) and the most posterior (F) points of the trochlea tali sagittal arc
11Sagittal distance between tibial and talar vertices (SDTaTi) (mm)Distance between the vertex of the tibial mortise (V1) and trochlea tali vertex (V2)
(B) Anteroposterior view (frontal projection) parameters
1Tibial width (TiW) (mm)Length of the internal line fitting between the two malleoli (between the G and H points)
2Malleolar width (MalW) (mm)Length of the line connecting the most medial point of the medial malleolus (K) and the most lateral point of the lateral malleolus (J)
3Tarsal width (TaW) (mm)Length of the line along the top of talar articular surface extending between the most medial (M) and the most lateral points (L) of the talar articular profile

Source(s): Table by authors

Distribution of individuals according to age and sex

Age groupSexNMeanSD
20-29Male1724.242.60
Female2224.772.83
30-39Male2533.842.65
Female2334.302.73
40-49Male2244.682.74
Female2144.292.76
50-59Male1954.742.92
Female1854.222.72
60-69Male1764.472.59
Female1963.952.67
TotalMale10044.392.70
Female10344.312.74

Note(s): Abbreviations: N, number; SD, standard deviation

Source(s): Table by authors

The ICC values of the studied parameters

ParameterICC of the left measurementsICC of the right measurements
TiAL0.9670.964
APG0.9420.951
APA0.9680.943
MTiTh0.9630.923
MDA0.9200.931
MDV0.9590.949
TiW0.9600.952
MalW0.9710.970
SRTi0.9820.948
TaAL0.9450.945
TaW0.9650964
TaH0.9340.959
SDTaTi0.9530.921
SRTa0.9680.970

Note(s): The intra-observer reliability was evaluated using the intraclass correlation coefficient (ICC)

Source(s): Table by authors

Relation among tibial parameters according to the side

ParameterLeft ankle (n = 203)Right ankle (n = 203)Total (n = 406)p value
MeanSDMinMaxMeanSDMinMaxMeanSDMinMax
TiAL (mm)29.003.6820.4038.6528.793.6921.0140.1428.903.6820.4040.140.564
APG (mm)2.040.630.844.222.070.850.245.942.050.750.245.940.626
APA (degrees)3.441.461.107.953.711.501.048.063.581.481.048.060.065
MTiTh (mm)40.793.3634.2849.5740.913.2734.1848.6040.853.3134.1849.570.736
MDA (mm)10.654.615.1224.1310.924.625.2624.9910.794.615.1224.990.546
MDV (mm)4.891.412.038.285.071.352.587.904.981.382.038.280.180
TiW (mm)28.132.0122.5932.9428.441.8922.9734.8028.291.9522.5934.800.112
MalW (mm)59.044.7948.0567.6059.614.9446.3368.4759.334.8746.3368.470.229
SRTi (mm)22.992.4716.8229.9922.801.8718.1827.8522.892.1916.8229.990.373

Note(s): Values are presented as means, SD, minimum (Min) and maximum (Max). Statistical analysis was performed by paired student's t-test

Source(s): Table by authors

Relation among talar parameters according to the side

ParameterLeft ankle (n = 203)Right ankle (n = 203)Total (n = 406)p value
MeanSDMinMaxMeanSDMinMaxMeanSDMinMax
TaAL (mm)37.632.4629.3144.7137.232.6931.1545.8337.432.5929.3145.830.118
TaW (mm)26.182.6520.3333.2926.922.6622.0232.7826.552.6820.3333.290.005
TaH (mm)12.421.837.6316.9312.471.948.0116.1612.451.897.6316.930.784
SDTaTi (mm)2.400.651.014.552.480.651.004.892.440.651.004.890.221
SRTa (mm)21.091.2217.9624.7121.111.3517.6924.9221.101.2817.6924.920.863

Note(s): Values are presented as means, SD, minimum (Min) and maximum (Max). Statistical analysis was performed by paired student's t-test

Source(s): Table by authors

%DAs of tibial parameters according to the sex

ParameterMale (n = 100)Female (n = 103)Total (n = 203)p value
MeanSDMeanSDMeanSD
TiAL−0.790.09−0.660.07−0.730.070.692
APG1.660.131.310.111.480.160.693
APA7.571.277.551.217.561.230.661
MtiTh1.010.090.330.020.670.070.700
MDA2.490.292.520.312.500.280.528
MDV3.740.323.460.353.600.370.183
TiW1.200.141.090.111.150.160.139
MalW0.940.060.960.080.950.070.391
SRTi−0.840.07−0.820.1−0.830.090.298

Note(s): Values are presented as means and SD. Statistical analysis was performed by Mann–Whitney U-test

Source(s): Table by authors

%DAs of talar parameters according to the sex

ParameterMale (n = 100)Female (n = 103)Total (n = 203)p value
MeanSDMeanSDMeanSD
TaAL−1.060.06−1.210.08−1.140.080.132
TaW2.770.19−6.490.42−1.860.180.003
TaH0.340.040.460.070.400.090.693
SDTaTi3.010.533.600.563.310.620.349
SRTa0.090.010.100.010.090.010.731

Note(s): Values are presented as means and SD. Statistical analysis was performed by Mann–Whitney U-test

Source(s): Table by authors

%AAs of tibial parameters according to the sex

ParameterMale (n = 100)Female (n = 103)Total (n = 203)p value
MeanSDMeanSDMeanSD
TiAL0.570.050.670.070.620.060.275
APG1.520.181.130.131.320.160.042
APA1.300.131.520.161.410.180.211
MTiTh0.370.050.240.060.300.040.318
MDA1.000.011.310.021.160.030.073
MDV1.030.041.150.051.090.060.627
TiW0.430.070.230.030.330.190.048
MalW0.310.050.370.050.340.060.762
SRTi0.390.040.450.060.420.050.184

Note(s): Values are presented as means and SD. Statistical analysis was performed by Mann–Whitney U-test

Source(s): Table by authors

%AAs of talar parameters according to the sex

ParameterMale (n = 100)Female (n = 103)Total (n = 203)p value
MeanSDMeanSDMeanSD
TaAL0.390.030.430.060.410.050.729
TaW0.490.050.300.020.390.040.182
TaH0.690.060.640.080.670.070.829
SDTaTi1.150.071.540.091.350.070.491
SRTa0.340.030.290.040.320.040.695

Note(s): Values are presented as means and SD. Statistical analysis was performed by Mann–Whitney U-test

Source(s): Table by authors

Relation among tibial parameters according to the sex

ParameterMale (n = 200)Female (n = 206)Total (n = 406)p value
MeanSDMinMaxMeanSDMinMaxMeanSDMinMax
TiAL (mm)Left29.333.6821.3837.9728.674.1019.3039.0728.903.6820.4040.140.080
Right29.103.6921.0137.8328.484.3519.3538.73
Total29.223.0020.4036.8428.584.2320.7240.14
APG (mm)Left1.790.610.734.022.280.711.425.842.050.750.245.94<0.001
Right1.820.730.525.172.310.841.705.33
Total1.800.610.243.962.290.801.055.94
APA (degrees)Left3.431.451.095.313.441.701.128.023.581.481.048.060.946
Right3.701.471.135.123.711.781.078.11
Total3.571.101.105.423.581.791.048.06
MTiTh (mm)Left42.263.5234.0749.6739.051.8933.8243.0340.853.3134.1849.57<0.001
Right42.693.3333.9849.3239.181.7133.9842.85
Total42.633.5134.1849.5739.121.9034.2843.72
MDA (mm)Left10.322.325.1015.3210.985.935.0624.2610.794.615.1224.990.143
Right10.582.405.3615.9711.265.955.1425.03
Total10.452.475.2615.3711.125.985.1224.99
MDV (mm)Left5.251.382.548.054.541.332.017.574.981.382.038.28<0.001
Right5.451.342.738.344.701.302.167.94
Total5.351.352.658.284.621.322.037.89
TiW (mm)Left28.912.4522.3634.6127.351.1124.2530.5328.291.9522.5934.80<0.001
Right29.262.3822.7534.9827.651.0524.6330.87
Total29.092.3122.5934.8027.511.0624.4130.76
MalW (mm)Left61.194.2750.4468.3156.954.3646.2667.2159.334.8746.3368.47<0.001
Right61.774.3450.0768.7457.504.4646.7267.79
Total61.484.3150.1168.4757.234.4546.3367.68
SRTi (mm)Left23.822.2317.9229.9822.172.0815.3727.3122.892.1916.8229.99<0.001
Right23.622.0821.6128.6721.991.8818.5326.17
Total23.722.1018.7929.9922.081.9616.8227.24

Note(s): Values are presented as means, SD, minimum (Min) and maximum (Max). Statistical analysis was performed by unpaired student's t-test

Source(s): Table by authors

Relation among talar parameters according to the sex

Parameter Male (n = 200)Female (n = 206)Total (n = 406)p value
MeanSDMinMaxMeanSDMinMaxMeanSDMinMax
TaAL (mm)Left37.922.4130.6745.6637.392.2228.7244.6737.432.5929.3145.830.024
Right37.522.6930.9545.7136.942.4628.9644.46
Total37.722.7331.6545.8337.142.4129.3142.42
TaW (mm)Left27.782.5320.0533.6525.781.4921.2129.6126.552.6820.3333.29<0.001
Right28.562.7120.1632.9724.161.5421.9328.69
Total28.192.6420.3333.2924.971.5221.2828.84
TaH (mm)Left11.851.877.3215.6312.981.628.1616.11 1.897.6316.93<0.001
Right11.891.967.7615.2113.041.718.3316.02
Total11.871.917.6315.5713.011.688.2116.9312.45
SDTaTi (mm)Left2.620.641.314.742.180.560.954.07 0.651.004.89<0.001
Right2.700.671.294.912.260.590.114.12
Total2.660.661.284.892.220.571.004.072.44
SRTa (mm)Left21.441.3917.9724.8820.761.0917.7623.59 1.2817.6924.92<0.001
Right21.461.5617.5324.9520.780.9917.5123.78
Total21.451.4117.9124.9220.771.0417.6923.6921.10

Note(s): Values are presented as means, SD, minimum (Min) and maximum (Max). Statistical analysis was performed by unpaired student's t-test

Source(s): Table by authors

Relation among the male tibial parameters according to the age groups

Parameter20-29 (n = 39)30-39 (n = 48)40-49 (n = 43)50-59 (n = 37)60-69 (n = 36)
Mean ± SDMean ± SDMean ± SDMean ± SDMean ± SD
TiAL (mm)Left28.02 ± 1.7129.92 ± 2.88a28.79 ± 4.29a,b27.81 ± 2.33b32.13 ± 4.95a,b,c,d
Right27.84 ± 1.6229.80 ± 1.62a28.59 ± 4.40a,b27.67 ± 2.19b31.63 ± 4.8 a,b,c,d
Total27.93 ± 1.6229.86 ± 2.83a28.69 ± 4.29a,b27.74 ± 2.41b31.88 ± 4.79a,b,c,d
APG (mm)Left0.95 ± 0.271.61 ± 0.57a1.62 ± 0.41a1.66 ± 1.16a3.01 ± 0.59a,b,c,d
Right1.01 ± 0.311.63 ± 0.62a1.70 ± 0.52a1.72 ± 1.25a3.09 ± 0.61a,b,c,d
Total0.98 ± 0.261.62 ± 0.57a1.66 ± 0.62a1.69 ± 1.26a3.05 ± 4.86a,b,c,d
APA (degrees)Left1.92 ± 0.393.26 ± 0.11a4.05 ± 0.66a,b4.12 ± 0.68a,b4.32 ± 2.01a,b
Right2.14 ± 0.522.52 ± 0.83a4.33 ± 0.71a,b4.44 ± 0.79a,b4.60 ± 2.32a,b
Total2.03 ± 0.432.89 ± 0.97a4.19 ± 0.66a,b4.28 ± 0.78a,b4.46 ± 2.17a,b
MTiTh (mm)Left43.66 ± 3.3941.28 ± 2.99a40.70 ± 1.60a43.92 ± 3.97b,c43.21 ± 1.52b,c
Right43.80 ± 3.9541.36 ± 3.08a40.88 ± 1.78a44.10 ± 4.11b,c43.37 ± 1.64b,c
Total43.73 ± 3.9741.32 ± 3.11a40.79 ± 1.79a44.01 ± 4.05b,c43.29 ± 1.54b,c
MDA (mm)Left8.43 ± 1.398.33 ± 2.916.28 ± 0.99a,b12.39 ± 1.03a,b,c16.22 ± 6.13a,b,c,d
Right8.61 ± 1.618.45 ± 2.376.52 ± 0.87a,b12.69 ± 1.26a,b,c16.58 ± 5.72a,b,c,d
Total8.52 ± 1.578.39 ± 2.836.40 ± 0.98a,b12.54 ± 1.16a,b,c16.40 ± 5.91a,b,c,d
MDV (mm)Left5.53 ± 1.194.81 ± 1.56a4.86 ± 0.80a,b5.00 ± 1.06c6.05 ± 0.79a,b,c,d
Right5.67 ± 1.445.03 ± 1.71a5.10 ± 0.62a,b5.24 ± 1.35c6.21 ± 0.93a,b,c,d
Total5.60 ± 1.364.92 ± 1.62a4.98 ± 1.12a,b5.12 ± 1.19c6.13 ± 0.84a,b,c,d
TiW (mm)Left28.66 ± 1.5130.01 ± 1.88a29.61 ± 0.86a,b29.17 ± 2.31b,c26.95 ± 1.05a,b,c,d
Right28.90 ± 1.5630.31 ± 1.97a30.05 ± 1.02a,b30.05 ± 2.06b,c27.19 ± 1.31a,b,c,d
Total28.78 ± 1.5230.16 ± 1.98a29.83 ± 3.09a,b29.61 ± 2.11b,c27.07 ± 1.15a,b,c,d
MalW (mm)Left62.25 ± 5.6962.12 ± 3.7359.43 ± 3.16a,b64.83 ± 4.43a,b,c57.50 ± 4.38a,b,c,d
Right62.81 ± 5.8162.62 ± 3.5960.05 ± 2.98a,b65.39 ± 4.19a,b,c57.80 ± 4.11a,b,c,d
Total62.53 ± 5.6662.37 ± 3.6359.74 ± 3.08a,b65.11 ± 4.22a,b,c57.65 ± 4.24a,b,c,d
SRTi (mm)Left23.80 ± 1.5024.70 ± 1.63a25.12 ± 2.73a22.12 ± 1.69a,b,c23.26 ± 1.66b,c,d
Right23.62 ± 1.4624.54 ± 1.58a24.9 ± 2.99a22.04 ± 1.61a,b,c23.10 ± 1.59b,c,d
Total23.71 ± 1.5324.62 ± 1.58a25.01 ± 2.81a22.08 ± 1.67a,b,c23.18 ± 1.61b,c,d

Note(s): Values are mean ± SD. ap < 0.05 vs 20–29 age group, bp < 0.05 vs 30–39 age group, cp < 0.05 vs 40–49 age group and dp < 0.05 vs 50–59 age group. Statistical analysis was performed by ANOVA, followed by Tukey’s post hoc test

Source(s): Table by authors

Relation among the male talar parameters according to the age groups

Parameter20-29 (n = 39)30-39 (n = 48)40-49 (n = 43)50-59 (n = 37)60-69 (n = 36)
Mean ± SDMean ± SDMean ± SDMean ± SDMean ± SD
TaAL (mm)Left37.74 ± 1.8940.43 ± 1.91a36.60 ± 1.97a,b36.21 ± 2.68a,b37.87 ± 2.66b,c,d
Right37.52 ± 1.9440.15 ± 1.75a36.36 ± 1.71a,b36.87 ± 2.39a,b37.45 ± 2.64b,c,d
Total37.63 ± 1.8140.29 ± 1.84a36.48 ± 1.87a,b36.54 ± 2.54a,b37.66 ± 2.65b,c,d
TaW (mm)Left28.11 ± 2.7329.25 ± 2.89a28.17 ± 1.37b28.43 ± 2.0525.14 ± 1.21a,b,c,d
Right28.65 ± 2.8530.05 ± 3.01a28.99 ± 1.48b29.27 ± 2.4425.84 ± 1.42a,b,c,d
Total28.38 ± 2.7729.63 ± 2.98a28.51 ± 1.42b28.88 ± 2.3325.52 ± 1.34a,b,c,d
TaH (mm)Left12.57 ± 2.0413.80 ± 0.74a11.61 ± 1.32a,b10.67 ± 0.84a,b,c10.62 ± 1.85a,b,c
Right12.67 ± 2.0913.78 ± 0.79a11.63 ± 1.21a,b10.69 ± 0.89a,b,c10.66 ± 1.91a,b,c
Total12.62 ± 2.0613.79 ± 0.79a11.62 ± 1.27a,b10.68 ± 0.86a,b,c10.64 ± 1.85a,b,c
SDTaTi (mm)Left2.28 ± 0.512.60 ± 0.35a2.23 ± 0.41b2.96 ± 0.68a,b,c2.95 ± 0.69a,b,c
Right2.36 ± 0.572.76 ± 0.43a2.31 ± 0.49b3.04 ± 0.77a,b,c3.11 ± 0.79a,b,c
Total2.32 ± 0.532.68 ± 0.35a2.27 ± 0.46b3.00 ± 0.74a,b,c3.03 ± 0.77a,b,c
SRTa (mm)Left21.22 ± 0.8321.31 ± 0.6720.35 ± 0.88a,b21.63 ± 1.55c22.67 ± 1.17a,b,c,d
Right21.26 ± 0.9121.31 ± 0.6920.39 ± 0.85a,b21.69 ± 1.61c22.69 ± 1.15a,b,c,d
Total21.24 ± 0.8421.31 ± 0.6720.37 ± 0.85a,b21.66 ± 1.57c22.68 ± 1.16a,b,c,d

Note(s): Values are mean ± SD. ap < 0.05 vs 20–29 age group, bp < 0.05 vs 30–39 age group, cp < 0.05 vs 40–49 age group and dp < 0.05 vs 50–59 age group. Statistical analysis was performed by ANOVA, followed by Tukey’s post hoc test

Source(s): Table by authors

Relation among the female tibial parameters according to the age groups

Parameter20-29 (n = 39)30-39 (n = 48)40-49 (n = 43)50-59 (n = 37)60-69 (n = 36)
Mean ± SDMean ± SDMean ± SDMean ± SDMean ± SD
TiAL (mm)Left27.38 ± 1.7129.92 ± 2.88a28.15 ± 4.29a,b27.17 ± 2.33b31.49 ± 4.95a,b,c,d
Right27.20 ± 1.6228.52 ± 1.62a27.95 ± 4.40a,b27.03 ± 2.19b30.99 ± 4.8 a,b,c,d
Total27.29 ± 1.6429.22 ± 2.86a28.05 ± 4.25a,b27.10 ± 2.48b31.24 ± 4.72a,b,c,d
APG (mm)Left1.44 ± 0.272.10 ± 0.57a2.11 ± 0.41a2.15 ± 1.16a3.50 ± 0.59a,b,c,d
Right1.50 ± 0.312.12 ± 0.62a2.19 ± 0.52a2.21 ± 1.25a3.58 ± 0.61a,b,c,d
Total1.47 ± 0.272.11 ± 0.59a2.15 ± 0.61a2.18 ± 1.22a3.54 ± 1.88a,b,c,d
APA (degrees)Left1.93 ± 0.393.27 ± 0.11a4.06 ± 0.66a,b4.13 ± 0.68a,b4.33 ± 2.01a,b
Right2.15 ± 0.522.53 ± 0.83a4.34 ± 0.71a,b4.45 ± 0.79a,b4.61 ± 2.32a,b
Total2.04 ± 0.472.90 ± 0.94a4.20 ± 0.64a,b4.29 ± 0.79a,b4.47 ± 2.15a,b
MTiTh (mm)Left40.15 ± 3.3937.77 ± 2.99a37.19 ± 1.60a40.41 ± 3.97b,c39.71 ± 1.52b,c
Right40.29 ± 3.9537.85 ± 3.08a37.37 ± 1.78a40.59 ± 4.11b,c39.87 ± 1.64b,c
Total40.22 ± 3.9537.81 ± 3.19a37.28 ± 1.82a40.50 ± 4.01b,c39.79 ± 1.53b,c
MDA (mm)Left9.10 ± 1.399.00 ± 2.916.95 ± 0.99a,b13.06 ± 1.03a,b,c16.89 ± 6.13a,b,c,d
Right9.28 ± 1.619.12 ± 2.377.19 ± 0.87a,b13.36 ± 1.26a,b,c17.25 ± 5.72a,b,c,d
Total9.19 ± 1.549.06 ± 2.877.07 ± 1.02a,b13.21 ± 1.14a,b,c17.07 ± 5.84a,b,c,d
MDV (mm)Left4.80 ± 1.194.08 ± 1.56a4.13 ± 0.80a,b4.27 ± 1.06c5.32 ± 0.79a,b,c,d
Right4.94 ± 1.444.30 ± 1.71a4.37 ± 0.62a,b4.51 ± 1.35c5.48 ± 0.93a,b,c,d
Total4.87 ± 1.374.19 ± 1.69a4.25 ± 1.11a,b4.39 ± 1.14c5.40 ± 0.86a,b,c,d
TiW (mm)Left27.08 ± 1.5128.43 ± 1.88a28.03 ± 0.86a,b27.59 ± 2.31b,c25.37 ± 1.05a,b,c,d
Right27.32 ± 1.5628.73 ± 1.97a28.47 ± 1.02a,b28.47 ± 2.06b,c25.61 ± 1.31a,b,c,d
Total27.20 ± 1.5528.58 ± 1.96a28.25 ± 3.04a,b28.03 ± 2.18b,c25.49 ± 1.17a,b,c,d
MalW (mm)Left58.00 ± 5.6957.87 ± 3.7355.18 ± 3.16a,b60.58 ± 4.43a,b,c53.25 ± 4.38a,b,c,d
Right58.56 ± 5.8158.37 ± 3.5955.80 ± 2.98a,b61.14 ± 4.19a,b,c53.55 ± 4.11a,b,c,d
Total58.28 ± 5.6458.12 ± 3.6755.49 ± 3.09a,b60.86 ± 4.26a,b,c53.40 ± 4.22a,b,c,d
SRTi (mm)Left22.16 ± 1.5023.06 ± 1.63a23.48 ± 2.73a20.48 ± 1.69a,b,c21.62 ± 1.66b,c,d
Right21.98 ± 1.4622.90 ± 1.58a23.26 ± 2.99a20.40 ± 1.61a,b,c21.46 ± 1.59b,c,d
Total22.07 ± 1.5422.98 ± 1.59a23.37 ± 2.84a20.44 ± 1.62a,b,c21.54 ± 1.67b,c,d

Note(s): Values are mean ± SD. ap < 0.05 vs 20–29 age group, bp < 0.05 vs 30–39 age group, cp < 0.05 vs 40–49 age group and dp < 0.05 vs 50–59 age group. Statistical analysis was performed by ANOVA, followed by Tukey’s post hoc test

Source(s): Table by authors

Relation among the female talar parameters according to the age groups

Parameter20-29 (n = 39)30-39 (n = 48)40-49 (n = 43)50-59 (n = 37)60-69 (n = 36)
Mean ± SDMean ± SDMean ± SDMean ± SDMean ± SD
TaAL (mm)Left37.16 ± 1.8939.85 ± 1.91a36.02 ± 1.97a,b35.63 ± 2.68a,b37.29 ± 2.66b,c,d
Right36.94 ± 1.9439.57 ± 1.75a35.78 ± 1.71a,b36.29 ± 2.39a,b36.87 ± 2.64b,c,d
Total37.05 ± 1.8539.71 ± 1.83a35.90 ± 1.82a,b35.96 ± 2.53a,b37.08 ± 2.63b,c,d
TaW (mm)Left24.90 ± 2.7326.02 ± 2.89a24.89 ± 1.37b25.25 ± 2.0521.94 ± 1.21a,b,c,d
Right25.44 ± 2.8526.82 ± 3.01a25.71 ± 1.48b26.09 ± 2.4422.64 ± 1.42a,b,c,d
Total25.17 ± 2.7426.42 ± 2.92a25.30 ± 1.45b25.67 ± 2.3922.29 ± 1.31a,b,c,d
TaH (mm)Left13.71 ± 2.0414.94 ± 0.74a12.75 ± 1.32a,b11.81 ± 0.84a,b,c11.76 ± 1.85a,b,c
Right13.81 ± 2.0914.92 ± 0.79a12.77 ± 1.21a,b11.83 ± 0.89a,b,c11.80 ± 1.91a,b,c
Total13.76 ± 2.0414.93 ± 0.74a12.76 ± 1.25a,b11.82 ± 0.89a,b,c11.78 ± 1.88a,b,c
SDTaTi (mm)Left1.84 ± 0.512.16 ± 0.35a1.79 ± 0.41b2.52 ± 0.68a,b,c2.51 ± 0.69a,b,c
Right1.92 ± 0.572.32 ± 0.43a1.87 ± 0.49b2.60 ± 0.77a,b,c2.67 ± 0.79a,b,c
Total1.88 ± 0.562.24 ± 0.38a1.83 ± 0.43b2.56 ± 0.71a,b,c2.59 ± 0.72a,b,c
SRTa (mm)Left20.54 ± 0.8320.63 ± 0.6719.67 ± 0.88a,b20.95 ± 1.55c21.98 ± 1.17a,b,c,d
Right20.58 ± 0.9120.63 ± 0.6919.71 ± 0.85a,b21.01 ± 1.61c22.00 ± 1.15a,b,c,d
Total20.56 ± 0.8520.63 ± 0.6919.69 ± 0.81a,b20.98 ± 1.53c21.99 ± 1.12a,b,c,d

Note(s): Values are mean ± SD. ap < 0.05 vs 20–29 age group, bp < 0.05 vs 30–39 age group, cp < 0.05 vs 40–49 age group and dp < 0.05 vs 50–59 age group. Statistical analysis was performed by ANOVA, followed by Tukey’s post hoc test

Source(s): Table by authors

Relationships among the studied morphometric variables

TiALAPGAPAMTiThMDAMDVTiWMalWSRTiTaALTaWTaHSDTaTiSRTa
TiAL1−0.0230.406**0.396**0.425**0.111*−0.123*−0.113*0.251**0.275**−0.0620.219**0.113*0.015
APG−0.02310.299**−0.0790.218**0.205**−0.091−0.138**−0.187**−0.104*−0.0860.035−0.137**−0.226**
APA0.406**0.299**10.452**0.615**0.0410.001−0.148**<0.0010.108*0.012−0.121*0.128**0.019
MTiTh0.396**−0.0790.452**10.262**0.358**−0.069−0.151**−0.0780.146**−0.172**−0.270**0.259**0.488**
MDA0.425**0.218**0.615**0.262**10.418**−0.005−0.128**−0.268**0.168**−0.142**−0.174**0.233**0.329**
MDV0.111*0.205**0.0410.358**0.418**10.0440.083−0.083−0.0360.082−0.222**0.140**0.186**
TiW−0.123*−0.0910.001−0.069−0.0050.04410.427**0.0630.375**0.654**0.0800.158**0.163**
MalW−0.113*−0.138**−0.148**0-.151**−0.128**0.0830.427**10.0550.0550.499**−0.214**0.0960.043
SRTi0.251**−0.187**<0.001−0.078−0.268**−0.0830.0630.05510.238**0.241**0.234**−0.076−0.099*
TaAL0.275**−0.104*0.108*0.146**0.168**−0.0360.375**0.0550.238**10.210**0.485**0.0710.162**
TaW−0.062−0.0860.0120-.172**−0.142**0.0820.654**0.499**0.241**0.210**10.0120.056−0.044
TaH0.219**0.035−0.121*−0.270**−0.174**−0.222**0.080−0.214**0.234**0.485**0.0121−0.206**−0.282**
SDTaTi.113*−0.137**0.128**0.259**0.233**0.140**0.158**0.096−0.0760.0710.056−0.206**10.351**
SRTa0.015−0.226**0.0190.488**0.329**0.186**0.163**0.043−0.099*0.162**−0.044−0.282**0.351**1

Note(s): **. Correlation is significant at the 0.01 level (two-tailed)

*. Correlation is significant at the 0.05 level (two-tailed)

Source(s): Table by authors

Comparison between the findings of the current and previous studies

AuthorStagni et al. (2005)Hayes et al. (2006)Khanasuk et al. (2011)Kuo et al. (2014)Kwon et al. (2014)Uzuner et al. (2018)Present study
Year of publication2005200620112014201420182022
CountryItalyUnited statesThailandTaiwanKoreaTurkeyEgypt
Method of assessmentPlain x-rayMulti-detector CT scanMRICadaveric CT scanPlain x-rayPlain x-rayPlaine x-ray
Number of subjectsM = 23
F = 13
M = 11
F = 10
M = 11
F = 21
M = 32
F = 26
M = 57
F = 43
M = 134
F = 140
M = 100
F = 103
Age of subjects (year old)15-7630-5020-6018-8510-8520-69
MFTTTMFTTMFMFT
Mean of studied arametersTiAL33.128.031.426.129.426.128.429.229.228.628.9
APG2.62.72.73.92.93.64.21.82.32.1
APA4.75.55.06.16.67.48.23.63.63.6
MTiTh42.238.341.436.242.540.842.039.442.639.140.9
MDA12.210.411.511.810.511.412.410.511.110.8
MDV9.37.78.74.52.94.010.05.44.65.0
TiW33.628.631.929.331.133.829.929.127.528.3
MalW71.063.569.058.564.559.963.167.666.658.161.527.259.3
SRTi27.323.526.123.323.722.122.9
TaAL43.637.941.731.732.731.232.335.341.237.737.737.137.4
TaW31.528.330.428.021.519.420.930.528.225.026.6
TaH11.511.811.910.511.913.012.5
SDTaTi4.74.04.52.72.22.4
SRTa24.521.123.420.718.120.521.420.821.521.520.821.1

Note(s): Abbreviations: M, male; F, female; T, total. All measurement parameters are by mm except for APA id by degrees

Source(s): Table by authors

Declaration of interest: No conflicts of interest.

References

Abdel Moneim, W. M., Abdel Hady, R. H., Abdel Maaboud, R. M., Fathy, H. M., & Hamed, A. M. (2008). Identification of sex depending on radiological examination of foot and patella. The American Journal of Forensic Medicine and Pathology, 29(2), 136140.

Alkass, K., Buchholz, B. A., Ohtani, S., Yamamoto, T., Druid, H., & Spalding, K. L. (2010). Age estimation in forensic sciences: Application of combined aspartic acid racemization and radiocarbon analysis. Molecular and Cellular Proteomics, 9(5), 10221030.

Angthong, C., Rajbhandari, P., Veljkovic, A., Piyaphanee, A., Stufkens, S. A. S., & Wibowo, R. (2020). Morphometric geometric differences between right and left human tali: A cadaveric study of fluctuating asymmetry via systematic measurement and three-dimensional scanning. PLoS One, 15(4), e0232012.

Auerbach, B. M., & Ruff, C. B. (2006). Limb bone bilateral asymmetry: Variability and commonality among modern humans. Journal of Human Evolution, 50(2), 203218.

Bozdag, M., & Karaman, G. (2021). Virtual morphometry of the first lumbar vertebrae for estimation of sex using computed tomography data in the Turkish population. Cureus, 13(7), e16597.

Callewaert, F., Sinnesael, M., Gielen, E., Boonen, S., & Vanderschueren, D. (2010). Skeletal sexual dimorphism: Relative contribution of sex steroids, GH–IGF1, and mechanical loading. Journal of Endocrinology, 207(2), 127134.

Cappella, A., Bertoglio, B., Di Maso, M., Mazzarelli, D., Affatato, L., Stacchiotti, A., … Cattaneo, C. (2022). Sexual dimorphism of cranial morphological traits in an Italian sample: A population-specific logistic regression model for predicting sex. Biology (Basel), 11(8), 1202.

Davies, C. M., Hackman, L., & Black, S. M. (2014). The foot in forensic human identification: A review. Foot (Edinb), 24(1), 3136.

Fessy, M. H., Carret, J. P., & Béjui, J. (1997). Morphometry of the talocrural joint. Surgical and Radiologic Anatomy, 19(5), 299302.

Fornai, C., Webb, N. M., Urciuoli, A., Krenn, V. A., Corron, L. K., & Haeusler, M. (2021). New insights on hip bone sexual dimorphism in adolescents and adults using deformation-based geometric morphometrics. Journal of Anthropological Sciences, 99, 117134.

Garg, S., Verma, U., Suri, A., Aulakh, K. K., Aneja, P. S., & Kaur, N. (2022). Morphometric analysis and types of articular facets on human dry tali and calcanei of north Indian origin. Biomedicine, 42(1), 2832.

Ghalawat, N., Sharma, J., Singh, S., & Malik, V. S. (2022). Morphometric measurements of calcaneum in North Indian population. EUREKA: Health Sciences, 2, 2328.

Gutnik, B., Skurvydas, A., Zuoza, A., Zuoziene, I., Mickevičienė, D., Alekrinskis, A., & Nash, D. (2015). Evaluation of bilateral asymmetry between upper limb masses in right-handed young adults of both sexes. Perceptual and Motor Skills, 120(3), 804815.

Han, Q., Liu, Y., Chang, F., Chen, B., Zhong, L., & Wang, J. (2019). Measurement of talar morphology in northeast Chinese population based on three-dimensional computed tomography. Medicine (Baltimore), 98(37), e17142.

Hayes, A., Tochigi, Y., & Saltzman, C. L. (2006). Ankle morphometry on 3D-CT images. Iowa Orthopedic Journal, 16, 14.

Introna, F. J. R., Di Vella, G., Ampobasso, C. P., & Dragone, M. (1997). Sex determination by discriminant analysis of calcanei measurements. Journal of Forensic Sciences, 42(4), 725728.

Islam, K., Dobbe, A., Komeili, A., Duke, K., El-Rich, M., Dhillon, S., … Jomha, N. M. (2014). Symmetry analysis of talus bone: A geometric morphometric approach. Bone and Joint Research, 3(5), 139145.

Kalbouneh, H., Mubarak, N., Daradkeh, S., Ashour, O., Alkhatib, A. M., Suboh, L., … Alsalem, M. (2021). Estimation of sex based on metrics of the sternum in a contemporary Jordanian population: A computed tomographic study. Medicine (Baltimore), 100(49), e28169.

Khanasuk, Y., Itiravivong, P., Tangpronprasert, P., & Virulsri, C. (2011). Ankle morphometry for development of ankle prosthesis. Chulalongkorn Medical Journal, 55(3), 193205.

Kiskira, C., Eliopoulos, C., Vanna, V., & Manolis, S. K. (2022). Biometric sex assessment from the femur and tibia in a modern Greek population. Legal Medicine (Tokyo), 59, 102126.

Koo, T. K., & Li, M. Y. (2016). A guideline of selecting and reporting intraclass correlation coefficients for reliability research. Journal of Chiropractic Medicine, 15(2), 155163.

Krishan, K., & Kanchan, T. (2016). Forensic and Anthropological Application of Body Asymmetry: A Comment on Gutnik et al. (2015). Perceptual and Motor Skills, 122(2), 578582.

Kuo, C. C., Lee, G. Y., Chang, C. M., Hsu, H. C., Leardini, A., & Lu T. W. (2008). Ankle morphometry in the Chinese population. Journal of Foot and Ankle Research, 1(Suppl 1), O11.

Kuo, C. C., Lu, H. L., Leardini, A., Lu, T. W., Kuo, M. Y., & Hsu, H. C. (2014). Three-dimensional computer graphics-based ankle morphometry with computerized tomography for total ankle replacement design and positioning. Clinical Anatomy, 27(4), 659668.

Kwon, D. G., Sung, K. H., Chung, C. Y., Park, M. S., Lee, S. H., Kim, T. W., … Lee, K. M. (2014). Preliminary findings of morphometric analysis of ankle joint in Korean population. The Journal of Foot and Ankle Surgery, 53(1), 37.

Lee, D. K., & Mulder, G. D. (2009). Foot and ankle surgery: Considerations for the geriatric patient. Journal of the American Board of Family Medicine, 22(3), 316324.

Rich, J. (2000). Increasing the identification potential from human foot remains. Journal of Forensic Sciences, 45(2), 505506.

Rich, J., Tatarek, N. E., Powers, R. H., Brogdon, B. G., Lewis, B. J., & Dean, D. E. (2002). Using pre- and post-surgical foot and ankle radiographs for identification. Journal of Forensic Sciences, 47(6), 13191322.

Rich, J., Dean, D. E., & Cheung, Y. Y. (2003). Forensic implications of the foot and ankle. The Journal of Foot and Ankle Surgery, 42(4), 221225.

Singh, S., & Singh, S. P. (1975). Identification of sex from tarsal bones. Acta Anatomica (Basel), 93(4), 568573.

Soundarya, N., Jain, V. K., Shetty, S., & Akshatha, B. K. (2021). Sexual dimorphism using permanent maxillary and mandibular incisors, canines and molars: An odontometric analysis. Journal of Oral and Maxillofacial Pathology, 25(1), 183188.

Stagni, R., Leardini, A., Ensini, A., & Cappello, A. (2005). Ankle morphometry evaluated using a new semi-automated technique based on X-ray pictures. Clinical Biomechanics (Bristol, Avon), 20(3), 307311.

Steele, D. G. (1976). The estimation of sex on the basis of the talus and calcaneus. American Journal of Physical Anthropology, 45(3 pt. 2), 581588.

Uzuner, M. B., Sargon, M. F., Geneci, F., Ocak, M., Sancak, T., Demiryürek, D., … Erden, K. (2018). The relation between ankle morphology and osteochondritis dissecans of talus. Acta Orthopaedica Belgica, 84(2), 229234.

Yurttas, Y., Kilic, C., Akpancar, S., Celikkanat, S., Hanifi Gemci, M. … & Kilic, E. (2018). The relation between ankle morphology and osteochondritis dissecans of talus. Acta Orthopædica Belgica, 84(2), 229234.

Zanella, V. P., & Brown, T. M. (2003). Testing the validity of metacarpal use in sex assessment of human skeletal remains. Journal of Forensic Sciences, 48(1), 1720.

Corresponding author

Wael Amin Nasr El-Din can be contacted at: waela@agu.edu.bh

Related articles