Sarcopenia and cognitive impairment: a data analysis based on European population databases

doi:10.12307/2026.768

Abstract

Abstract: BACKGROUND: In recent years, multiple epidemiological studies have suggested a potential pathological link between sarcopenia and cognitive impairment. However, due to methodological limitations in traditional observational studies and difficulties in controlling confounding factors, their genetic-level causal relationship has not yet been fully elucidated.
OBJECTIVE: To systematically analyze the causal relationship and underlying pathogenesis between sarcopenia and cognitive impairment in European populations using Mendelian randomization methods.
METHODS: This study utilized genome-wide association study (GWAS) summary statistics for sarcopenia-related phenotypes (whole-body fat-free mass, hand grip strength, and walking pace) from the UK Biobank, as well as GWAS summary data for cognitive function from the IEU database. After stringent quality control steps, including threshold screening and linkage disequilibrium removal, a bidirectional Mendelian randomization analysis was conducted. The forward analysis treated sarcopenia-related traits as exposure factors and cognitive function as the outcome variable, while the reverse analysis swapped their causal directions. The inverse-variance weighted method served as the primary analytical approach, supplemented by the weighted median method, MR-Egger regression, and robust adjusted profile score for validation. To ensure the robustness of the findings, the study further performed heterogeneity tests and a series of sensitivity analyses.
RESULTS AND CONCLUSION: (1) The results of the forward causal analysis using the inverse variance-weighted Mendelian randomization method indicated that total fat-free mass (odds ratio=1.091, 95% confidence interval: 1.001–1.188, P=0.045), left handgrip strength (odds ratio=1.283, 95% confidence interval: 1.077–1.527, P=0.005), right handgrip strength (odds ratio=1.220, 95% confidence interval: 1.022–1.456, P=0.027), and walking speed (odds ratio=3.069, 95% confidence interval: 1.997–4.717, P < 0.001) were all significantly positively correlated with cognitive function. (2) The results of the reverse causal analysis showed that cognitive function was only significantly positively associated with walking speed (odds ratio=1.023, 95% confidence interval: 1.004–1.043, P=0.014), with no significant association found for total fat-free mass or handgrip strength. (3) Sensitivity analyses indicated some heterogeneity in the study; however, horizontal pleiotropy was not observed. Research findings demonstrate a causal relationship between sarcopenia and cognitive impairment, suggesting that sarcopenia may serve as a predictive indicator for cognitive impairment and providing a theoretical basis for early clinical screening. Furthermore, this study, based on an international public database, offers new evidence for the association between sarcopenia and cognitive impairment in the Chinese population, which holds significant reference value for the early screening and prevention of these two conditions.

Key words: sarcopenia, cognitive impairment, bidirectional Mendelian randomization, causal relationship, muscle-brain axis, muscle mass, walking speed

CLC Number:

Yin Xingxiao, Peng Hao, Song Yanping, Yao Na, Shen Zhen, Jiang Yang, Chen Hongbo, Huang Li, Song Yueyu, Li Yanqi, Chen Qigang. Sarcopenia and cognitive impairment: a data analysis based on European population databases[J]. Chinese Journal of Tissue Engineering Research, 2026, 30(28): 7388-7395.

Figures/Tables 4

2.1 单核苷酸多态性的选择和验证研究基于质量控制标准筛选单核苷酸多态性位点，并通过暴露因素与结局变量的匹配分析进行遗传变异选择。以F统计量> 10作为判断标准，确保所选单核苷酸多态性具有足够的强度以有效降低潜在偏倚的影响。正向分析结果显示：在全身无脂肪质量与认知功能的关联性分析中，经过P值筛选和去除连锁不平衡处理后，共纳入556个单核苷酸多态性位点；经暴露因素与结局变量的效应等位基因对齐后保留498个单核苷酸多态性；进一步剔除回文单核苷酸多态性后剩余431个位点；最终通过MR-PRESSO方法检验并排除异常值，确定427(29.874 < F < 779.566)个单核苷酸多态性位点纳入最终分析。在左手握力与认知功能的关联性分析中，经过P值筛选和去除连锁不平衡处理后，共纳入157个单核苷酸多态性位点；经暴露因素与结局变量的效应等位基因对齐后保留143个单核苷酸多态性；进一步剔除回文单核苷酸多态性后剩余126个位点；最终通过MR-PRESSO方法检验并排除异常值，确定124(29.778 < F < 191.541)个单核苷酸多态性位点纳入最终分析。在右手握力与认知功能的关联性分析中，经过P值筛选和去除连锁不平衡处理后，共纳入176个单核苷酸多态性位点；经暴露因素与结局变量的效应等位基因对齐后保留157个单核苷酸多态性；进一步剔除回文单核苷酸多态性后剩余136个位点；最终通过MR-PRESSO方法检验并排除异常值，确定134(29.896 < F < 231.736)个单核苷酸多态性位点纳入最终分析。在步行速度与认知功能的关联性分析中，经过P值筛选和去除连锁不平衡处理后，共纳入57个单核苷酸多态性位点；经暴露因素与结局变量的效应等位基因对齐后保留49个单核苷酸多态性；进一步剔除回文单核苷酸多态性后剩余46个位点；最终通过MR-PRESSO方法检验并排除异常值，确定46(29.791 < F < 101.566)个单核苷酸多态性位点纳入最终分析。反向分析结果表明：在认知功能与全身无脂肪质量的关联性分析中，经过P值筛选和去除连锁不平衡处理后，共纳入12个单核苷酸多态性位点；经暴露因素与结局变量的效应等位基因对齐后保留12个单核苷酸多态性；进一步剔除回文单核苷酸多态性后剩余10个位点；最终通过MR-PRESSO方法检验并排除异常值，确定9(24.637 < F < 29.915)个单核苷酸多态性位点纳入最终分析。在认知功能与左手握力的关联性分析中，经过P值筛选和去除连锁不平衡处理后，共纳入12个单核苷酸多态性位点；经暴露因素与结局变量的效应等位基因对齐后保留12个单核苷酸多态性；进一步剔除回文单核苷酸多态性后剩余10个位点；最终通过MR-PRESSO方法检验并排除异常值，确定9(24.637 < F < 29.915)个单核苷酸多态性位点纳入最终分析。在认知功能与右手握力的关联性分析中，经过P值筛选和去除连锁不平衡处理后，共纳入12个单核苷酸多态性位点；经暴露因素与结局变量的效应等位基因对齐后保留12个单核苷酸多态性；进一步剔除回文单核苷酸多态性后剩余12个位点；最终通过MR-PRESSO方法检验并排除异常值，确定10(24.637 < F < 31.143)个单核苷酸多态性位点纳入最终分析。在认知功能与步行速度的关联性分析中，经过P值筛选和去除连锁不平衡处理后，共纳入12个单核苷酸多态性位点；经暴露因素与结局变量的效应等位基因对齐后保留12个单核苷酸多态性；进一步剔除回文单核苷酸多态性后剩余12个位点；最终通过MR-PRESSO方法检验并排除异常值，确定10(24.637 < F < 31.143)个单核苷酸多态性位点纳入最终分析。 2.2 肌少症相关特征与认知障碍之间的因果关系逆方差加权法结果显示，全身无脂肪质量(OR=1.091，95%CI：1.001-1.188，P=0.045)、左手握力OR=1.283，95%CI：1.077-1.527，P=0.005)、右手握力(OR=1.220，95%CI：1.022-1.456，P=0.027)和步行速度(OR=3.069，95%CI：1.997-4.717，P < 0.001)均与认知功能呈显著正相关。为进一步验证结果的可靠性，研究采用多种补充分析方法进行稳健性检验。在全身无脂肪质量与认知功能的关联分析中，虽然MR-Egger回归法、加权中位数法和稳健调整轮廓评分法未达到统计学显著性水平(P > 0.05)，但3种方法所得效应值的方向与逆方差加权法一致，提示该结果具有稳健性。在握力与认知功能的关联分析中，MR-Egger回归法和加权中位数法未发现显著关联，但稳健调整轮廓评分法的分析结果与逆方差加权法一致(P < 0.05)。对于步行速度与认知功能的关联，虽然MR-Egger回归法未得出显著结果，但加权中位数法和稳健调整轮廓评分法的分析均支持这一正向关联(P < 0.05)，进一步验证了研究结论的可靠性，见表2。敏感性分析结果显示：Cochran’s Q检验提示存在异质性(全身无脂肪质量：Q=537.792，P < 0.001；左手握力：Q=151.822，P=0.039；右手握力：Q=181.340，P=0.003；步行速度：Q=79.253，P=0.001)，故采用随机效应模型解释这一结果。MR-Egger截距检验和MR-PRESSO全局检验显示不存在多效性(P > 0.05)，见表3。此外，留一法敏感性分析显示，肌少症相关特征与认知功能之间的因果关联不受单个单核苷酸多态性的影响，见图1。 2.3 认知障碍与肌少症相关特征之间的因果关系为了探究认知障碍与肌少症的因果关系，研究进行了反向孟德尔随机化分析。逆方差加权法结果表明，认知功能与步行速度之间存在显著的正向因果关系(OR=1.023，95%CI：1.004-1.043，P=0.014)，该结果得到加权中位数法和稳健调整轮廓评分法的一致性验证(P均< 0.05)。然而，认知功能与全身无脂肪质量、左右手握力之间未发现统计学意义的因果关联，见表4。在敏感性分析方面，Cochran’s Q检验结果显示研究不存在异质性(全身无脂肪质量：Q=12.146，P=0.144；左手握力：Q=11.325，P=0.183；右手握力：Q=12.976，P=0.163；步行速度：Q=12.119，P=0.206)；MR-Egger截距检验和MR-PRESSO全局检验均未发现水平多效性证据( P > 0.05)，见表3。此外，通过留一法敏感性分析证实，研究结果不受单个单核苷酸多态性的影响，表明因果关系具有稳健性，见图2。"

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