Assessment of Circadian Rhythms of Both Skin Temperature and Motor Activity in Infants During the First 6 Months of Life

The authors developed a method useful for home measurement of temperature, activity, and sleep rhythms in infants under normal-living conditions during their first 6 mos of life. In addition, parametric and nonparametric tests for assessing circadian system maturation in these infants were compared. Anthropometric parameters plus ankle skin temperature and activity were evaluated in 10 infants by means of two data loggers, Termochron iButton (DS1291H, Maxim Integrated Products, Sunnyvale, CA) for temperature and HOBO Pendant G (Hobo Pendant G Acceleration, UA-004-64, Onset Computer Corporation, Bourne, MA) for motor activity, located in special baby socks specifically designed for the study. Skin temperature and motor activity were recorded over 3 consecutive days at 15 days, 1, 3, and 6 mos of age. Circadian rhythms of skin temperature and motor activity appeared at 3 mos in most babies. Mean skin temperature decreased significantly by 3 mos of life relative to previous measurements (p = .0001), whereas mean activity continued to increase during the first 6 mos. For most of the parameters analyzed, statistically significant changes occurred at 3–6 mos relative to 0.5–1 mo of age. Major differences were found using nonparametric tests. Intradaily variability in motor activity decreased significantly at 6 mos of age relative to previous measurements, and followed a similar trend for temperature; interdaily stability increased significantly at 6 mos of age relative to previous measurements for both variables; relative amplitude increased significantly at 6 mos for temperature and at 3 mos for activity, both with respect to previous measurements. A high degree of correlation was found between chronobiological parametric and nonparametric tests for mean and mesor and also for relative amplitude versus the cosinor-derived amplitude. However, the correlation between parametric and nonparametric equivalent indices (acrophase and midpoint of M5, interdaily stability and Rayleigh test, or intradaily variability and P1/Pultradian) despite being significant, was lower for both temperature and activity. The circadian function index (CFI index), based on the integrated variable temperature-activity, increased gradually with age and was statistically significant at 6 mos of age. At 6 mos, 90% of the infants' rest period coincided with the standard sleep period of their parents, defined from 23:00 to 07:00 h (dichotomic index I < O; when I < O = 100%, there is a complete coincidence between infant nocturnal rest period and the standard rest period), whereas at 15 days of life the coincidence was only 75%. The combination of thermometry and actimetry using data loggers placed in infants' socks is a reliable method for assessing both variables and also sleep rhythms in infants under ambulatory conditions, with minimal disturbance. Using this methodological approach, circadian rhythms of skin temperature and motor activity appeared by 3 mos in most babies. Nonparametric tests provided more reliable information than cosinor analysis for circadian rhythm assessment in infants. (Author correspondence: elvirada@um.es)

[1]  Thomas Reilly,et al.  Strong association of the rest-activity rhythm with well-being in demented elderly women. , 2007, The American journal of geriatric psychiatry : official journal of the American Association for Geriatric Psychiatry.

[2]  J. A. Madrid,et al.  Circadian rhythm of wrist temperature in normal-living subjects A candidate of new index of the circadian system , 2008, Physiology & Behavior.

[3]  E. Haffen Mesure des rythmes circadiens , 2009 .

[4]  M. Wailoo,et al.  Factors affecting the development of night time temperature rhythms. , 1992, Archives of disease in childhood.

[5]  Hein A.M. Daanen,et al.  Evaluation of wireless determination of skin temperature using iButtons , 2006, Physiology & Behavior.

[6]  Kurt Lushington,et al.  The relationship between insomnia and body temperatures. , 2008, Sleep medicine reviews.

[7]  D. Swaab,et al.  Skin temperature and sleep-onset latency: Changes with age and insomnia , 2007, Physiology & Behavior.

[8]  D. Kripke,et al.  The role of actigraphy in the evaluation of sleep disorders. , 1995, Sleep.

[9]  B. Taylor,et al.  Bed-sharing and the infant’s thermal environment in the home setting , 2004, Archives of Disease in Childhood.

[10]  G. Atkinson,et al.  The difference between activity when in bed and out of bed. I. Healthy subjects and selected patients. , 1996, Chronobiology international.

[11]  M. Mirmiran,et al.  Development of fetal and neonatal sleep and circadian rhythms. , 2003, Sleep medicine reviews.

[12]  J. Waterhouse,et al.  The circadian rhythm of core temperature: Effects of physical activity and aging , 2007, Physiology & Behavior.

[13]  Manuel Campos,et al.  A New Integrated Variable Based on Thermometry, Actimetry and Body Position (TAP) to Evaluate Circadian System Status in Humans , 2010, PLoS Comput. Biol..

[14]  P. Fleming,et al.  The physiology of sleep in infants , 2008, Archives of Disease in Childhood.

[15]  D F Swaab,et al.  Bright light therapy: improved sensitivity to its effects on rest-activity rhythms in Alzheimer patients by application of nonparametric methods. , 1999, Chronobiology international.

[16]  E. V. van Someren,et al.  Fragmentation of the rest‐activity rhythm correlates with age‐related cognitive deficits , 2009, Journal of sleep research.

[17]  T. Deboer,et al.  Technologies of sleep research , 2007, Cellular and Molecular Life Sciences.

[18]  C. Tuffnell,et al.  Oscillations of body temperature at night. , 1992, Archives of disease in childhood.

[19]  E. Someren,et al.  Age-associated difference in circadian sleep–wake and rest–activity rhythms , 2002, Physiology & Behavior.

[20]  D. Boivin,et al.  The regulation of central and peripheral circadian clocks in humans , 2009, Obesity reviews : an official journal of the International Association for the Study of Obesity.

[21]  J. Mortola Hypoxia and circadian patterns , 2007, Respiratory Physiology & Neurobiology.

[22]  A. Sadeh,et al.  The role of actigraphy in sleep medicine. , 2002, Sleep medicine reviews.

[23]  Patricio Peirano,et al.  Sleep-wake states and their regulatory mechanisms throughout early human development. , 2003, The Journal of pediatrics.

[24]  S. Rivkees Developing circadian rhythmicity in infants. , 2003, Pediatric endocrinology reviews : PER.

[25]  F. Cherikh,et al.  Ontogenèse des rythmes circadiens chez l’humain , 2009 .

[26]  L. Menna-Barreto,et al.  Comparative analysis of rhythmic parameters of the body temperature in humans measured with thermistors and digital thermometers , 2006 .

[27]  A. Lezcano,et al.  Estudio transversal español de crecimiento 2008. Parte I: valores de peso y longitud en recién nacidos de 26-42 semanas de edad gestacional , 2008 .

[28]  M. Smolensky,et al.  ETHICS AND METHODS FOR BIOLOGICAL RHYTHM RESEARCH ON ANIMALS AND HUMAN BEINGS , 2010, Chronobiology international.

[29]  V. Parraguez,et al.  Perinatal neuroendocrine regulation. Development of the circadian time-keeping system , 2002, Molecular and Cellular Endocrinology.

[30]  P. Buckley,et al.  Actigraphy Correctly Predicts Sleep Behavior in Infants Who Are Younger than Six Months, When Compared with Polysomnography , 2005, Pediatric Research.

[31]  R. Horne,et al.  The use of actigraphy for assessment of the development of sleep/wake patterns in infants during the first 12 months of life , 2007, Journal of sleep research.

[32]  D. Mason,et al.  Measuring Circadian Rhythms , 1992, Western journal of nursing research.

[33]  E. Someren Sleep propensity is modulated by circadian and behavior-induced changes in cutaneous temperature , 2004 .

[34]  I. McMillen,et al.  Development of Circadian Sleep-Wake Rhythms in Preterm and Full-Term Infants , 1991, Pediatric Research.

[35]  D. Kennaway Programming of the fetal suprachiasmatic nucleus and subsequent adult rhythmicity , 2002, Trends in Endocrinology & Metabolism.

[36]  A. Wirz-Justice,et al.  EEG and subjective sleepiness during extended wakefulness in seasonal affective disorder: circadian and homeostatic influences , 2000, Biological Psychiatry.

[37]  D. Yeste Fernández,et al.  [Spanish cross-sectional growth study 2008. Part I: weight and height values in newborns of 26-42 weeks of gestational age]. , 2008, Anales de pediatria.