Neumeyer Ann M, Cano Sokoloff Natalia, McDonnell Erin, Macklin Eric A, McDougle Christopher J, Misra Madhusmita
Lurie Center for Autism, Massachusetts General Hospital, Lexington, MA 02421, United States; Harvard Medical School, Boston, MA 02115, United States.
Lurie Center for Autism, Massachusetts General Hospital, Lexington, MA 02421, United States.
Bone. 2017 Apr;97:139-146. doi: 10.1016/j.bone.2017.01.009. Epub 2017 Jan 11.
Boys with autism spectrum disorder (ASD) have lower areal bone mineral density (aBMD) than typically developing controls (TDC). Studies of volumetric BMD (vBMD) and bone microarchitecture provide information about fracture risk beyond that provided by aBMD but are currently lacking in ASD.
To assess ultradistal radius and distal tibia vBMD, bone microarchitecture and strength estimates in adolescent boys with ASD compared to TDC.
DESIGN/METHODS: Cross-sectional study of 34 boys (16 ASD, 18 TDC) that assessed (i) aBMD at the whole body (WB), WB less head (WBLH), hip and spine using dual X-ray absorptiometry (DXA), (ii) vBMD and bone microarchitecture at the ultradistal radius and distal tibia using high-resolution peripheral quantitative CT (HRpQCT), and (iii) bone strength estimates (stiffness and failure load) using micro-finite element analysis (FEA). We controlled for age in all groupwise comparisons of HRpQCT and FEA measures. Activity questionnaires, food records, physical exam, and fasting levels of 25(OH) vitamin D and bone markers (C-terminal collagen crosslinks and N-terminal telopeptide (CTX and NTX) for bone resorption, N-terminal propeptide of Type 1 procollagen (P1NP) for bone formation) were obtained.
ASD participants were slightly younger than TDC participants (13.6 vs. 14.2years, p=0.44). Tanner stage, height Z-scores and fasting serum bone marker levels did not differ between groups. ASD participants had higher BMI Z-scores, percent body fat, IGF-1 Z-scores, and lower lean mass and aBMD Z-scores than TDC at the WB, WBLH, and femoral neck (P<0.1). At the radius, ASD participants had lower trabecular thickness (0.063 vs. 0.070mm, p=0.004), compressive stiffness (56.7 vs. 69.7kN/mm, p=0.030) and failure load (3.0 vs. 3.7kN, p=0.031) than TDC. ASD participants also had 61% smaller cortical area (6.6 vs. 16.4mm, p=0.051) and thickness (0.08 vs. 0.22mm, p=0.054) compared to TDC. At the tibia, ASD participants had lower compressive stiffness (183 vs. 210kN/mm, p=0.048) and failure load (9.4 vs. 10.8kN, p=0.043) and 23% smaller cortical area (60.3 vs. 81.5mm, p=0.078) compared to TDC. A lower proportion of ASD participants were categorized as "very physically active" (20% vs. 72%, p=0.005). Differences in physical activity, calcium intake and IGF-1 responsiveness may contribute to group differences in stiffness and failure load.
Bone microarchitectural parameters are impaired in ASD, with reductions in bone strength estimates (stiffness and failure load) at the ultradistal radius and distal tibia. This may result from lower physical activity and calcium intake, and decreased IGF-1 responsiveness.
患有自闭症谱系障碍(ASD)的男孩的骨矿物质密度(aBMD)低于正常发育的对照组(TDC)。对体积骨密度(vBMD)和骨微结构的研究提供了有关骨折风险的信息,这些信息超出了aBMD所提供的范围,但目前在ASD研究中尚缺乏。
评估与TDC相比,患有ASD的青春期男孩的尺骨远端和胫骨远端的vBMD、骨微结构和强度估计值。
设计/方法:对34名男孩(16名ASD,18名TDC)进行横断面研究,评估(i)使用双能X线吸收法(DXA)测量全身(WB)、去除头部的全身(WBLH)、髋部和脊柱的aBMD;(ii)使用高分辨率外周定量CT(HRpQCT)测量尺骨远端和胫骨远端的vBMD和骨微结构;(iii)使用微有限元分析(FEA)估计骨强度(刚度和破坏载荷)。在HRpQCT和FEA测量的所有组间比较中,我们对年龄进行了控制。获取了活动问卷、食物记录、体格检查以及25(OH)维生素D和骨标志物(用于骨吸收的C端胶原交联和N端肽(CTX和NTX),用于骨形成的I型前胶原N端前肽(P1NP))的空腹水平。
ASD参与者比TDC参与者略年轻(13.6岁对14.2岁,p = 0.44)。两组之间的 Tanner 分期、身高Z评分和空腹血清骨标志物水平没有差异。在WB、WBLH和股骨颈处,ASD参与者的BMI Z评分、体脂百分比、IGF-1 Z评分更高,而瘦体重和aBMD Z评分低于TDC(P<0.1)。在桡骨处,ASD参与者的小梁厚度(0.063对0.070mm,p = 0.004)、压缩刚度(56.7对69.7kN/mm,p = 0.030)和破坏载荷(3.0对3.7kN,p = 0.031)低于TDC。与TDC相比,ASD参与者的皮质面积(6.6对16.4mm,p = 0.051)和厚度(0.08对0.22mm,p = 0.054)也小61%。在胫骨处,与TDC相比,ASD参与者的压缩刚度(183对210kN/mm,p = 0.048)和破坏载荷(9.4对10.8kN,p = 0.043)较低,皮质面积小23%(60.3对81.5mm,p = 0.078)。被归类为“非常活跃”的ASD参与者比例较低(20%对72%,p = 0.005)。身体活动、钙摄入量和IGF-1反应性的差异可能导致刚度和破坏载荷的组间差异。
ASD患者的骨微结构参数受损,尺骨远端和胫骨远端的骨强度估计值(刚度和破坏载荷)降低。这可能是由于身体活动和钙摄入量较低以及IGF-1反应性降低所致。
