Literature DB >> 35388552

Circadian rest-activity misalignment in critically ill medical intensive care unit patients.

Prerna Gupta1, Jennifer L Martin2,3, Atul Malhotra4, Jaclyn Bergstrom5, Michael A Grandner6, Biren B Kamdar4.   

Abstract

Circadian alignment of rest-activity rhythms is an essential biological process that may be vulnerable to misalignment in critically ill patients. We evaluated circadian rest-activity rhythms in critically ill patients and their association with baseline (e.g. age) and clinical (e.g. mechanical ventilation status) variables, along with intensive care unit light-dark cycles. Using wrist actigraphy, we collected 48-hr activity and light exposure data from critically ill patients in a tertiary care medical intensive care unit. We evaluated circadian rest-activity rhythms using COSINOR and non-parametric circadian rhythm analysis models, and stratified these data across baseline and clinical variables. We used linear regression to evaluate the association of circadian rest-activity and light-dark exposure rhythms. In COSINOR and non-parametric circadian rhythm analysis analyses, the 34 medical intensive care unit patients completing 48-hr actigraphy recordings exhibited mean MESOR (mean activity levels of a fitted curve) and amplitudes of 0.50 ± 0.32 and 0.20 ± 0.19 movements per 30-s epoch, with high interdaily variability. Patients who were older, mechanically ventilated, sedated, restrained and with higher organ failure scores tended to exhibit greater circadian rest-activity misalignment, with three of 34 (9%) patients exhibiting no circadian rhythmicity. Circadian light-dark exposure misalignment was observed as well and was associated with rest-activity misalignment (p = 0.03). Critically ill patients in our MICU experienced profound circadian rest-activity misalignment, with mostly weak or absent rhythms, along with circadian light-dark exposure misalignment. Potentially modifiable factors contributing to rest-activity misalignment (i.e. mechanical ventilation, restraints, low daytime light levels) highlight possible targets for future improvement efforts.
© 2022 European Sleep Research Society.

Entities:  

Keywords:  actigraphy; circadian rhythms; critical care; light-dark cycle

Mesh:

Year:  2022        PMID: 35388552      PMCID: PMC9489597          DOI: 10.1111/jsr.13587

Source DB:  PubMed          Journal:  J Sleep Res        ISSN: 0962-1105            Impact factor:   5.296


  15 in total

1.  Feasibility of Continuous Actigraphy in Patients in a Medical Intensive Care Unit.

Authors:  Biren B Kamdar; Daniel J Kadden; Sitaram Vangala; David A Elashoff; Michael K Ong; Jennifer L Martin; Dale M Needham
Journal:  Am J Crit Care       Date:  2017-07       Impact factor: 2.228

2.  Use of actigraphy to characterize inactivity and activity in patients in a medical ICU.

Authors:  Prerna Gupta; Jennifer L Martin; Dale M Needham; Sitaram Vangala; Elizabeth Colantuoni; Biren B Kamdar
Journal:  Heart Lung       Date:  2020-02-24       Impact factor: 2.210

3.  Actigraphy-Derived Daily Rest-Activity Patterns and Body Mass Index in Community-Dwelling Adults.

Authors:  Elizabeth M Cespedes Feliciano; Mirja Quante; Jia Weng; Jonathan A Mitchell; Peter James; Catherine R Marinac; Sara Mariani; Susan Redline; Jacqueline Kerr; Suneeta Godbole; Alicia Manteiga; Daniel Wang; J Aaron Hipp
Journal:  Sleep       Date:  2017-12-01       Impact factor: 5.849

4.  The impact of daytime light exposures on sleep and mood in office workers.

Authors:  Mariana G Figueiro; Bryan Steverson; Judith Heerwagen; Kevin Kampschroer; Claudia M Hunter; Kassandra Gonzales; Barbara Plitnick; Mark S Rea
Journal:  Sleep Health       Date:  2017-04-23

5.  Methodological issues for studying the rest-activity cycle and sleep disturbances: a chronobiological approach using actigraphy data.

Authors:  Giovanna Calogiuri; Andi Weydahl; Franca Carandente
Journal:  Biol Res Nurs       Date:  2011-08-05       Impact factor: 2.522

6.  Variation in actigraphy-estimated rest-activity patterns by demographic factors.

Authors:  Jonathan A Mitchell; Mirja Quante; Suneeta Godbole; Peter James; J Aaron Hipp; Catherine R Marinac; Sara Mariani; Elizabeth M Cespedes Feliciano; Karen Glanz; Francine Laden; Rui Wang; Jia Weng; Susan Redline; Jacqueline Kerr
Journal:  Chronobiol Int       Date:  2017-06-26       Impact factor: 2.877

7.  Accelerometer-Measured Physical Activity and Sedentary Behavior in Relation to All-Cause Mortality: The Women's Health Study.

Authors:  I-Min Lee; Eric J Shiroma; Kelly R Evenson; Masamitsu Kamada; Andrea Z LaCroix; Julie E Buring
Journal:  Circulation       Date:  2017-11-06       Impact factor: 29.690

8.  Noise and Light Pollution in the Hospital: A Call for Action.

Authors:  Biren B Kamdar; Jennifer L Martin; Dale M Needham
Journal:  J Hosp Med       Date:  2017-09-06       Impact factor: 2.899

Review 9.  Circadian Disruption in Critical Illness.

Authors:  Aesha M Jobanputra; Matthew T Scharf; Ioannis P Androulakis; Jag Sunderram
Journal:  Front Neurol       Date:  2020-08-11       Impact factor: 4.003

10.  Sleep and Circadian Rhythms in Survivors of Acute Respiratory Failure.

Authors:  Pei-Lin Yang; Teresa M Ward; Robert L Burr; Vishesh K Kapur; Susan M McCurry; Michael V Vitiello; Catherine L Hough; Elizabeth C Parsons
Journal:  Front Neurol       Date:  2020-02-14       Impact factor: 4.003
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