Meiring, Rebecca Mary2014-08-252014-08-252014-08-25http://hdl.handle.net/10539/15244Osteoporosis is a disease that may be pre-determined from the condition of bone health during youth. In South Africa, the situation is quite unique in that the population of black people has a reduced fracture rate compared to white people. As lifestyle and dietary patterns change with urbanisation and there is a shift towards westernised diets and sedentary behaviour in youth, fractures in elderly South African blacks may become more prevalent. With these rapid lifestyle changes, it will become increasingly important to prioritise osteoporosis and its related conditions as a major public health concern in South Africa. Very few of the factors influencing osteoporosis have been well studied in children of different ethnic groups. Physical activity in childhood, especially in the prepubertal years, confers residual benefits to the adult skeleton. In this thesis, the associations between ethnicity, history of participation in physical activity and skeletal health were explored in a sample of pre-/early pubertal children from South Africa who participated in four different studies. Furthermore, a novel aspect of the thesis was the use of peripheral quantitative computed tomography (pQCT) to investigate the mechanistic role that physical activity plays on bone health in this unique population. First the use of an existing physical activity questionnaire for the assessment of bone loading had to be validated in a sample of black and white boys and girls (n=38). A bone loading algorithm was used to calculate a peak bone strain score (PBSS) from the physical activity questionnaire. Therefore a bone specific physical activity questionnaire (B3Q) was used in subsequent studies. The PBSS was shown to be reliable and reproducible with significant (p<0.001) intraclass correlation coefficients. There were significant correlations between PBSS and moderate (r=0.38; p=0.02), vigorous (r=0.36; p=0.03) and combined moderate to vigorous intensity activity counts (r=0.38; p=0.02) as measured by accelerometry. The ability of the PBSS algorithm to classify children into high or low weight bearing groups was in moderate agreement with accelerometer derived combined moderate and vigorous activity counts (κ=0.42; p=0.008). PBSS was significantly correlated to body size adjusted bone mineral content at all sites scanned by DXA (r=0.43-0.57; p<0.05). Positive correlations were observed between PBSS and area, density and strength at the radius and tibia (r=0.40-0.64; p<0.05). At the radial metaphysis, significant correlations between moderate activity (r=0.46; p=0.005) and combined moderate and vigorous activity counts (r=0.42; p=0.01) were seen for bone strength. No associations were seen between accelerometer measured physical activity and bone outcomes at the tibial diaphysis. Multiple regression analysis showed that the PBSS was a better predictor of bone mass and structure than was accelerometry. The next study sought to determine whether children who were classified as being high bone loaders for the past two years would present with greater bone mass and strength regardless of their ethnicity. Sixty six children [black boys, 10.4(1.4) yrs, n=15; black girls, 10.1(1.2) yrs, n=27; white boys, 10.1(1.1) yrs, n=7; white girls, 9.6(1.3) yrs, n=17] reported on all their physical activities over the past two years in the interviewer administered bone specific physical activity questionnaire (B3Q). Children were classified as being either high or low bone loaders based on the cohort’s median peak bone strain score estimated from the B3Q. In the low bone loading group, black children had greater femoral neck bone mineral content (BMC) (2.9 (0.08)g) than white children (2.4 (0.11)g; p=0.05). There were no ethnic differences in the high bone loaders for femoral neck BMC. At the cortical sites, the black low bone loaders had a greater radius area (97.3 (1.3) vs 88.8 (2.6) mm2 ; p=0.05) and a greater tibia total area (475.5 (8.7) vs. 397.3 (14.0) mm2 ; p=0.001) and strength (1633.7 (60.1) vs. 1271.8 (98.6) mm3 ; p=0.04) compared to the white low bone loaders. These measures were not different between the black low and high bone loaders or between the black and white high bone loaders. Ethnic differences in bone area and strength apparent between children classified as having a lower bone loading physical activity history appear to have been attenuated when children partaking in high bone loading physical activities were compared. Greater levels of mechanical loading seemed to have no apparent benefits in black children. Cross-sectional studies in black and white pre-pubertal children have observed significant ethnic differences in structural bone outcomes as measured by pQCT but there are a limited number of intervention studies that have been conducted in black children. The cortical bone of black and white children may respond differently to mechanical forces, yet no physical activity interventions and their effects on bone structure in black children have been done. The aim of the third study was to determine whether a weight-bearing physical activity intervention improves measures of bone mass, structure and strength in pre-pubertal black children. Children (9.7 ± 1.1 years) were randomised into an exercise (EX; n=12) and control (CON; n=11) group. The EX children performed a 20-week weightbearing exercise program performed twice a week for 45 minutes per session, while CON children continued their regular activities. Changes in tibial trabecular volumetric bone density, area and strength were greater in the EX than the CON group (all p<0.01). At the cortical site of the tibia, the change in bone density was greater in the EX group than the CON group (all p<0.05). The greater change in tibial periosteal circumference in the EX groups also resulted in a greater change in cortical thickness of the tibia compared to the CON group (p<0.05). The final study assessed whether rates of bone accrual differed over one year between high and low bone loaders and also between black and white South African children. Forty seven children (18 boys, 29 girls) were followed up after one year. High bone loaders tended to have greater baseline BMC at all sites measured by DXA but the difference was only significant at the femoral neck (p=0.03). At the follow up visit, femoral neck BMC remained significantly higher in the high compared to the low bone loaders (p=0.003). Bone strength index (BSI) at the follow up visit was significantly greater in the high bone loaders compared to the low bone loaders (p=0.05). Although there was a trend for the high bone loaders to have greater indices of density and area at the 65% tibia compared to the low bone loaders, this was not significantly different at baseline or at follow up. High bone loaders had greater relative changes in whole body BMC (p=0.002), tibial cortical area (p=0.03), cortical density (p=0.04) and cortical thickness (p=0.03) compared to low bone loaders. There were no significant differences in DXA bone outcomes between black and white children at baseline and follow up. At baseline, total density at the 4% radius was greater in black than in white children (p<0.001) but total density at the follow up visit was not significantly different between black and white children (p=0.06). Trabecular density was greater in the black than in the white children at baseline (p=0.01) as well as at follow up (p=0.04). BSI at baseline was greater in the black than in the white children (p=0.05) but this significance disappeared at follow up. Similar to the 4% radius, cortical density at baseline was significantly greater in the black compared to the white children at the 65% radius (p=0.01) and at the 65% tibia (p=0.04). In conclusion, the PBSS algorithm from the B 3Q can be used to reliably and accurately collect data on previous participation in weight bearing exercise and is able to classify children as being either high or low bone loaders. It appears that in order for White children to reach the same bone mass/health levels as Black children, they may need to participate in higher levels of weight-bearing physical activity. Ethnic differences in bone area and strength apparent between children classified as having a lower bone loading physical activity history appear to have been attenuated when children partaking in high bone loading physical activities were compared. The associations may indicate that a strong environmental influence (i.e. high participation in physical activity) may offer similar or even superior benefits to bone over genetic (ethnic) influences. The use of pQCT appears to be sufficiently sensitive in detecting bone structural changes in response to mechanical loading interventions. As such, pQCT measures were able to determine the efficacy of a weight bearing physical activity intervention on trabecular and cortical sites in black children, and, similar to what has previously been observed in white and Asian children, our knowledge on the attainment of bone in response to an exercise intervention in black children is deepened. Moreover, the bone accrual that occurs in a population of black and white children from a low-middle income country may also differ between ethnicities and may reflect an environmental influence that modifies existing paradigms on physical activity and bone health in children. The promotion of weightbearing physical activity should occur in all youth, to oppose the possible lifestyle induced risks for developing osteoporosis in adulthood.enBone and BonesBone Development--in infancy & childhoodA comparive study into the bone health of South African pre-pubertal children who participate in physical activites with various amounts of skeletal loadingThesis