Intra-observer and Inter-observer Reliability in Direct Anthropometry
Abstract
This study aimed to evaluate the reliability factors, and identify causes of error in direct anthropometry method. After training three beginner anthropometrists and following the instructions of anthropometric standards, 48 body dimensions of 42 male students were measured three times. In other words, the physical dimensions of each subject were measured for 9 times. All participants were wearing uniforms during anthropometry, with bare feet. Differences in values of Repeated Measurement Test were explored using SPSS software version 11. The same software was employed to evaluate, through calculating ICC index, the correlation between anthropometrists. Inter-observer repeated measurement test showed significant difference in the measurements taken in 3, 7 and 1 dimension(s) by the three anthropometrists. The average measurement was significantly different at 16 dimensions; this, however, showed no difference at 32 dimensions. Measurements taken by anthropometrist 1 had ICC values of 0.26 (Min) and 0.99 (Max) these values were 0.48 (Min) and 1.00 (Max) for anthropometrist 2 and 0.23 (Min) and 0.98 (Max) for antropometrist 3. The maximum and minimum values of ICC index in all three anthropometrists were respectively close to and above 0.98, and lower than 0.5. High value of ICC in the measured dimensions indicated high reliability of repeated measurements. The decreasing value of some indexes can be attributed to such factors as random error, poor design of measurements tool (which in turn leads to random error), the long time devoted to measurement process, high number of dimension measured, changes in posture of subjects and deviation from the standard position.
Ulijaszek SJ, Kerr DA. Anthropometric measurement error and the assessment of nutritional status. Br J Nutr 1999; 82(03):165- 77.
Kouchi M, Mochimaru M. Errors in landmarking and the evaluation of the accuracy of traditional and 3D anthropometry. Applied Ergonomics. 2011; 42(3):518-27.
Norton KI, Olds T. Anthropometrica: a textbook of body measurement for sports and health courses: NewSouth Publishing; 1996.
Karwowski W. International encyclopedia of ergonomics and human factors. Vol. 3: Taylor & Francis US; 2006.
Micozzi MS. Applications of anthropometry to epidemiologic studies of nutrition and cancer. American Journal of Human Biology 1990; 2(6):727-39.
Clarke G, Whittemore AS. Prostate cancer risk in relation to anthropometry and physical activity: the National Health and Nutrition Examination Survey I Epidemiological Follow-Up Study. Cancer Epidemiology Biomarkers & Prevention 2000; 9(9):875-81.
Geeta A, Jamaiyah H, Safiza M, Khor G, Kee C, Ahmad A, et al. Reliability, technical error of measurements and validity of instruments for nutritional status assessment of adults in Malaysia. Singapore Medical Journal 2009; 50(10):1013.
Sadeghi NH, Heidaripour M. Kansei engineering and ergonomic design of products. Int J Occ Hyg 2011; 3(2), 81-84.
Mirmohammadi SJ, Mehrparvar AH, Jafari S, Mostaghaci M. An Assessment of the Anthropometric Data of Iranian University Students. Int J Occ Hyg 2011; 3(2), 85-89.
Onis M. Reliability of anthropometric measurements in the WHO Multicentre Growth Reference Study. Acta Paediatrica 2006; 95(S450):38-46.
Bruton A, Conway JH, Holgate ST. Reliability: what is it, and how is it measured? Physiotherapy 2000; 86(2):94-9.
Martin Bland J, Altman D. Statistical methods for assessing agreement between two methods of clinical measurement. The lancet 1986; 327(8476):307-10.
Harris EF, Smith RN. Accounting for measurement error: a critical but often overlooked process. Archives of Oral Biology. 2009; 54:S107-S17.
Saw S, Ng T. The design and assessment of questionnaires in clinical research. Singapore Medical Journal 2001; 42(3):131.
Atkinson G, Nevill AM. Statistical methods for assessing measurement error (reliability) in variables relevant to sports medicine. Sports Medicine 1998; 26(4):217-38.
Chehrei A, Haghdoost AA, Fereshtehnejad SM, et al. Statistical method in medical science researches using SPSS software. 1st ed, Pejvak Elm Arya Publishing Co.,Tehran, Iran,2011.[Persian]
Lewsey J. Medical Statistics: A Guide to Data Analysis and Critical Appraisal. Annals of The Royal College of Surgeons of England 2006; 88(6):603.
Jamaiyah H, Geeta A, Safiza M, Khor G, Wong N, Kee C, et al. Reliability, technical error of measurements and validity of length and weight measurements for children under two years old in Malaysia. Med J Malays 2010; 65:131-7.
Mwangome MK, Fegan G, Mbunya R, Prentice AM, Berkley JA. Reliability and accuracy of anthropometry performed by community health workers among infants under 6 months in rural Kenya. Trop Med Int Health 2012; 17(5):622-9.
Jamaiyah H Jr, Geeta A, Safiza MN, Wong NF, Kee CC, Ahmad AZ, et al. Reliability and technical error of Calf Circumference and Mid-half Arm Span measurements for nutritional status assessment of elderly persons in Malaysia. Malaysian Journal of Nutrition 2008. 14(2): p. 137-150.
Nordhamn K, Södergren E, Olsson E, Karlström B, Vessby B and Berglund L, et al. Reliability of anthropometric measurements in overweight and lean subjects: consequences for correlations between anthropometric and other variables. Int J Obes 2000. 24: p. 652-657.
| Files | ||
| Issue | Vol 5 No 2 (2013) | |
| Section | Original Article(s) | |
| Published | 2015-10-11 | |
| Keywords | ||
| Measurements errors Reliability Direct anthropometrical | ||
| Rights and permissions | |
|
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License. |
