The lockdowns and restrictions associated with the COVID-19 have created a seismic shift in where work is done. Prior to the pandemic, approximately 20% of individuals were working from home while during the pandemic, more than 70% of individuals worked from home. While it is unlikely that such a large percent of the population will remain working from home, the vast support from workers for such work arrangements and the potential increase in productivity means that there will likely be a revision of the work place with more individuals working from a home office environment than have done so in the past. One unintended aspect of working from home is a reduction in light exposure, especially in the contrast between the daytime and evening. Offices converted from bedrooms, basements, and kitchens are often illuminated in the recommended 50-100 lux range, as opposed to the approximately 500 lux of most offices. While this light intensity is sufficient to work or read by, it may be insufficient to maintain adequate mental and physical health. In addition to light allowing us to consciously perceive the world around us, light can also induce a variety of changes in physiology that can impact our health, notably inducing shifts in the timing of circadian rhythms, suppressing the onset of melatonin production, and increasing alertness with subsequent changes to sleep latency and architecture. These changes in sleep and circadian rhythms have been associated with a variety of pathologies including increased risk of metabolic, psychiatric, cognitive, and cardiovascular disorders, in addition to overall longevity. Development of an adequate prophylactic countermeasure for the circadian desynchrony to which home office workers are exposed is a critical step in maintaining the health of these individuals. There are two main studies. The first study (Years 1-2) will be an in-laboratory determination of the threshold of light needed to minimize the negative impact of nocturnal light exposure. The second study (Years 3-4) will be a field study applying this threshold to determine if whether in situ use of this light intensity during the day improves health and safety among home office workers. Current CT.gov represents the second part of this study i.e. "Study 2: The impact of daytime light intensity in home workplaces on health and well-being of remote workers. In study 2, investigators will examine a series of participants (N=36), each of whom will participate in a five-week experiment. Each participant will have a screening visit at their home. The study will be conducted over five successive one-week periods with two cohorts of participants experiencing the same series of lighting interventions. All data collection will be performed during the working days (Monday - Friday) when participants are exposed to the lighting in their home offices.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
OTHER
Masking
DOUBLE
The bright lighting condition will administer the light intensity as determined from the finding of Study 1. Bright lighting condition will last for two weeks (Weeks 2-3 or 4-5), be limited to the 10 workdays, and be active for 8 hours per day.
The placebo condition will expose participants to 150 lux, a light level that is equivalent to average room lighting. Placebo lighting condition will last for two weeks (Weeks 2-3 or 4-5), be limited to the 10 workdays, and be active for 8 hours per day. The placebo lighting condition will be applied to minimize the bias and false improvements that might occur due to experiencing new lighting conditions and devices.
Change in Nocturnal Sleep Duration (in minutes) as measured by actigraphy
Nocturnal Sleep Duration (in minutes) will be measured by Actigraphy. Longer sleep duration corresponds to improved sleep outcomes.
Time frame: 24 hours everyday up to week 5
Change in Percent Sleep Efficiency (total sleep time divided by time in bed) measured by actigraphy
Percent Sleep Efficiency measured by actigraphy. Higher percentage corresponds to higher sleep quality.
Time frame: 24 hours everyday up to week 5
Change in the minutes of wake after sleep onset measured by actigraphy
The investigators will measure patients total time awake between initial sleep onset and the final morning awakening in minutes.
Time frame: Everyday up to week 5]
Change in the Subjective Sleep quality as measured by a single Likert-like question qualitatively
This is included in the consensus sleep diary and consists of 1 question that is scaled from 1 to 7, with higher score corresponds to poor quality sleep.
Time frame: everyday up to 5 weeks
Change in working memory as assessed by fractal 2-back score
Fractal 2-back score is based on number of correct responses. Higher test scores indicates better performance of working memory
Time frame: Once on the last day of week 1, 3, and 5
Change in working Memory as assessed by Visual Object Learning Task (VOLT) score
Participants first memorize a set of 3-dimensional Euclidean shapes. During recall, participants are to distinguish between the initial shapes mixed with ten distractor shapes. Score is based on number of correct responses.
Time frame: Once on the last day of week 1, 3, and 5
Change in median reaction time on Psychomotor Vigilance test
Psychomotor vigilance test(PVT) measures alertness and vigilant attention and is considered to be the gold standard measure of neurobehavioral effects of circadian misalignment and sleep loss. Shorter median reaction times corresponds to more attentive state.
Time frame: Once on the last day of week 1, 3, and 5
Change in Balloon Analogue Risk Task (BART) score
Participants inflate balloons of unknown popping probability to obtain the highest reward. Each pump increases the potential reward. The potential reward is lost if the balloon pops. Scores are calculated by adding the number of pumps for unexploded balloons, with higher scores reflecting greater risk-taking. Range varies - explosions are at a random point between 1 and 128 pumps.
Time frame: Once on the last day of week 1, 3, and 5
Change in subjective alertness as assessed by Stanford Sleepiness Scale (SSS)
SSS is a s self-reported Likert-type sleepiness scale which assess mental and physical sedation and sleepiness, respectively, at that moment and time. SSS only consists of 1 question that is scaled from 1 to 7, with 7 being a higher or worse score (i.e. more sleepy and sedated)
Time frame: Once on the last day of week 1, 3, and 5
Change in reaction time on Motor Praxis Task (MPT)
Participants are to quickly touch ever-shrinking boxes. Each time a new box appears in a different location on the screen. Shorter reaction time corresponds to higher sensory motor speed.
Time frame: Once on the last day of week 1, 3, and 5
Change in measure of abstraction: score on abstract matching test
Participants select pairs of shapes that fit with another shape. Higher number of correct responses corresponds to higher measure of abstraction.
Time frame: Once on the last day of week 1, 3, and 5
Change in the spatial orientation: score on line orientation test
Participants are shown two lines at different angles, and are to rotate one line incrementally until it is parallel to the other. Higher scores corresponds to better spatial orientation.
Time frame: Once on the last day of week 1, 3, and 5
Change in complex scanning and visual tracking: score on Digit Symbol Substitution Task (DSST)
Participants touch the number paired to the symbol that matches the current target symbol. Higher score corresponds to better complex scanning and visual tracking capability.
Time frame: Once on the last day of week 1, 3, and 5
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