Validation of Objectively and Subjectively Measured Physical Activity Against Energy Expenditure in Older Adults

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Background Physical inactivity has been estimated to cause 5.3 million deaths per year globally and is identified as one of the most important modifiable risk factors for chronic diseases, functional loss and disability. To correctly identify and study physical inactivity in old age, reliable assess...

Background Physical inactivity has been estimated to cause 5.3 million deaths per year globally and is identified as one of the most important modifiable risk factors for chronic diseases, functional loss and disability. To correctly identify and study physical inactivity in old age, reliable assessment tools are crucial in both research and clinical settings. Recent technological advancements in wearable activity monitors have led to a growing number of large, population-based studies using accelerometers to measure physical activity, sedentary behavior (in terms of overall volume, intensity and pattern), and sleep among older adults. However, the wide use of accelerometers also brings challenges when comparing the results across different studies that use different brands and models, various assessment protocols (e.g. anatomic locations, sampling frequency), data processing procedures and report different outcomes. Different accelerometer set-ups (i.e. brand, model, body position, initialization protocol, etc.) may challenge the interpretation of health-enhancing effect of physical activity and detrimental effect of sedentary behavior simply because of methodological issues. Accelerometers measure acceleration, defined as the change in velocity over time (?v/t), which quantifies the volume and intensity of movement. In addition, acceleration is a vector quantity with components of magnitude and direction, which can be used to identify the position of accelerometer in relation to gravity. Therefore, accelerometer could also be used to distinguish posture (e.g. sitting, standing, lying down) depending on the site of placement. Since raw acceleration signals are difficult to interpret, they are typically "translated" by calibration studies to physiological outcomes (e.g. energy expenditure, oxygen consumption) or behavioral categories (e.g. sitting, walking, running). Through regression modelling, calibration studies often produce point estimates of energy expenditure from accelerometer counts or establish a range of accelerometer counts for different physical activity intensity levels. This range of accelerometer counts is referred to as "cut-points" for different intensities of physical activity. Before the use of accelerometers, physical activity and sedentary behavior has been primarily assessed with questionnaires. Even as the scale of accelerometer studies are growing rapidly, questionnaires are still considered an important assessment method when assessing physical activity and sedentary behavior in large-scale studies. Some accelerometers and questionnaires have been validated by objectively measured energy expenditure. But for physical activity questionnaires, the validity against objective methods (e.g. accelerometry, heart rate monitor and double-labelled water) were found to be moderate at best and very few validation studies focused on older adults. In order to bridge and interpret data from questionnaires to accelerometers among older adults, there is a need to validate existing physical activity and sedentary behavior questionnaires with energy expenditure in this population. Energy expenditure has earlier been used to validate accelerometers and physical activity questionnaires metrics. Nevertheless, several issues remain unsolved: (1) despite the correlation between these methods has been reported to be high in few studies, the agreement is generally low especially in populations with altered metabolic states such as obese and overweight individuals; (2) while the total volume of physical activity is a clear metric which is presumably positively correlated with total daily energy expenditure, intensity of physical activity in older adults may be affected by a number of physiological determinants such as cardiovascular and neuromuscular function, inflammation status and malnutrition. Resting metabolic rate (RMR) and maximum physiological capacity (e.g. maximum oxygen update (VO2 max) typically decrease with age, which may be particular important as the same daily activities would likely be "more intense" to an older person compared to a younger person; (3) despite that numerous activity monitors provide similar metrics (e.g. counts/minutes), the physiological implication can be highly different depending on what such metrics stand for. For example, despite the output from accelerometers placed on wrist and on the hip may be identical (counts/minutes), the different magnitude of acceleration may have a completely different physiological relationship when assessed by physiological metrics (e.g. energy, oxygen uptake). Such diverse physiological impact according to the anatomical placement of accelerometers requires a rigorous harmonization of metrics from the accelerometers coupled with energy expenditure in representative activities at different intensities. To date, validation studies with accelerometers worn on multiple body positions are scarce and not all studies uses energy expenditure as the reference. One way to disentangle the physiological meaning of physical activity and sedentary behavior is to anchor accelerometer output to objective measurements of physiological capacity such as VO2 max, oxygen uptake during semi-standardized activities performed at self-selected pace and overall energy expenditure during free-living conditions collected over a representative period of time. This will contribute to a deeper understanding and accurate interpretation of the accelerometer data among community-dwelling older adults and to provide more specific accelerometry-based recommendations for physical activity, especially for the oldest population. Objectives The aims of this methodological study are to: develop hip-, wrist-, thigh-, and low back- worn accelerometer cut-points for different intensities of physical activity based on energy expenditure during semi-standardized daily tasks for the 80+ year-olds. validate accelerometry at the wrist, hip, thigh, and low back for estimating energy expenditure in free-living conditions, measured by the gold standard of energy expenditure, double-labelled water (DLW). validate existing physical activity and sedentary behavior questionnaires against gold standard of energy expenditure (DLW) in free-living conditions in the 80+ year-olds. Recruitment and data collection procedures The investigators will conduct a cross-sectional study with two modes of data collection: 1) in the laboratory; and 2) in the field. Participants will be recruited through two pathways: 1)(Pathway A) invited personally during the routine preventive home-visits performed by the Municipality of Odense ; (Pathway B)or 2) invited through a letter to community-dwelling older citizens who lives in the Municipality of Odense. Those who show interest to participate will then receive detailed written information about the project and will be invited to a medical screening after signing an informed consent. The entire testing procedure will span across 14 days as urine samples for DLW method is needed on Day 1 and Day 14. In between, participants will be invited to attend one for lab test for measuring energy expenditure during semi-standardized functional tasks. Statistical considerations and data management A detailed data management plan will be followed in the collection, entering, and analysis of data. In the laboratory examination day, all measurement devices will be synchronized before the measurement begins. Sample size Assuming that different accelerometers can capture same physical activity behaviour, in a test for agreement between two raters using the Kappa statistic, a sample size of 95 subjects achieves 80% power to detect a true Kappa value of 0.70 when there are 3 categories with frequencies equal to 0.01, 0.20, and 0.79. (representing estimated percentage of time spent in moderate-to-vigorous activity, light activity, and sedentary behavior in this population). This power calculation is based on an alpha of 0.05. Creation of a research biobank A research biobank (blood, urine, and saliva samples) will be created for the described project. The blood samples will be destroyed no later than 5 years after the project is ending. Blood samples will be taking at the facilities of the University (SDU). An authorized nurse or biomedical laboratory scientist will be in charge of obtaining blood samples from the participants. The biobank will be stored at SDU. In total, 8 urine samples will be obtained from each participant during the entire project period. Urine samples will be frozen and sent to USA for analysis. The urine samples will be anonymized and stored in the research biobank until the end of the project, when the samples will be destroyed. A trained project personnel will be in charge of collecting urine samples from the subjects. In this protocol, University of Southern Denmark acts as the controller of the biological materials collected (urine samples). Data processing agreements will be made between SDU and the University of Wisconsin, USA; and between SDU and University of California, Berkeley. The US processor shall comply with Danish law governing protection of personal data. Ethical considerations The research activities of this study will be carried out in accordance with the Declaration of Helsinki. All subjects will receive the pamphlets from The National Committee on Health Research Ethics regarding personal rights when participating in a health research project and aspects to consider before deciding to participate. This study will involve older adults, who are considered vulnerable individuals. It is important to acknowledge and respect participants' autonomy, i.e., they have to be able to decide by themselves their participation in the study with the right to withdraw at any stage. Moreover, a communication strategy suitable for this population will be applied to prevent any risk of enhancing vulnerability and stigmatization of the older adults. This project will generate valuable and novel knowledge about how do objectively measure physical activity measured by different accelerometers on the same individual correlate with energy expenditure among in +80-year-old community-dwelling citizens; and whether these patterns differ according to protein level. These knowledges that can be used to optimize and target the preventive and treatment strategies for malnourished older adults hence offer a benefit for the individual older adult and for the health care sector. Thus, the investigators believe that the benefits from the study is greater than the limited discomforts that may follow participation. Subjects are covered by the Danish Patient Insurance Association and can thus receive insurance of financial compensation in case any damage occurs while participating in the research project. This information will be given to participants both verbally and written (in the pamphlets from The National Committee on Health Research Ethics) during recruitment. All personal data will become anonymized and handled with full confidentiality in compliance with the Personal Data Processing Act. The procedure of personal data processing will be reported to the Danish Data Protection Agency in University of Southern Denmark. In this study protocol, only the anonymized urine and saliva samples will be sent abroad for analysis (details described earlier) with no linkage to any other personal data (e.g. CPR number, address, telephone number etc..). Participants will not receive any compensation for their participation in the study.

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