Is Tau Protein Linked to Mobility Function?

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Impaired mobility is strongly linked to cognitive function and vice versa. Cognitive functions are strongly associated with mobility function, most commonly assessed using gait speed. In the Health ABC Study, Digit Symbol Substitution Test (DSST) and Modified Mini Mental Status (3MS) scores were sig...

Impaired mobility is strongly linked to cognitive function and vice versa. Cognitive functions are strongly associated with mobility function, most commonly assessed using gait speed. In the Health ABC Study, Digit Symbol Substitution Test (DSST) and Modified Mini Mental Status (3MS) scores were significantly associated with gait speed and gait speed decline. Poor lower extremity performance predicts faster age-related cognitive decline and increased incidence of mild cognitive impairment (MCI) and dementia. This study will explore the role of tau protein as the neuropathologic basis for these associations. Brain imaging markers may be the link between cognitive measures and gait. White matter disease is commonly measured by quantifying white matter (WM) lesion load, which is associated with small vessel ischemic disease. More subtle microstructural changes can be observed by calculating fractional anisotropy (FA) from diffusion tensor imaging (DTI). Aging is accompanied by changes in cortical volume, white matter microstructure and an increased prevalence of WM lesions. WM lesions have been strongly implicated in declining physical function. These brain changes are associated with impaired balance, slower movement speeds, slower chair stand times and increased falls risk.Recently, Aâ accumulation in the brain has also been linked to slow gait. This finding suggests a pathologic mechanism linking Alzheimer s disease processes to gait impairments. However, Aâ accumulation itself may not be the critical neuropathic change. In recent studies of Aâ42 and phosphorylated tau protein in cerebral spinal fluid, it has been found that low Aâ42 levels themselves are not associated with impaired cognition, but that elevated tau levels are also required. If the process of cognitive impairment parallels the process of gait impairment, it might be that tau levels are more important correlates of gait changes. To the investigators' knowledge the relationship between CSF tau levels and mobility has never been explored. PET ligands for brain tau have recently become available, but the relationship between brain tau accumulation and gait has yet to be determined. In this study, investigators will relate gait characteristics to CSF Aâ42 and phosphorylated tau levels, and perform brain PET imaging in a subset to related tau protein accumulation to gait characteristics for the first time. Both mobility impairment and Alzheimers disease (AD) occur in the context of the aging vascular system. Over the past 15 years, it has been recognized that abnormalities of thoracic aortic stiffness are associated with the development of abnormalities in small vessels supplying the brain and kidneys. As the aorta stiffens, the propagation speed of the systolic flow wave increases through the aortic lumen. (Stiffness within the thoracic aorta can be accomplished through measurement of aortic pulse wave velocity.) In hypertensive patients, aortic archway pulse wave velocity has been associated with increases in left ventricular mass as well as lacunar brain infarcts independent of age, sex, and the duration of hypertension. In the Multi-Ethnic Dallas Heart Study aortic arch pulse wave velocity is an independent predictor of white matter hyper-intensities. In those with diabetes, increasing aortic stiffness contributes to the development of small vessel microvascular dysfunction which is associated with deep white matter atrophy as well as cognitive decline. Recently, a stiffness mismatch between the thoracic aorta and small vessels within the cerebral microcirculation has been described. This mismatch impacts microvascular pulsatility and appears to diminish diffusion anisotrophy between the cerebral spinal fluid and the CNS microcirculation. This observation may contribute to retained amyloid type protein in those with AD.

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