On the development of sleep states in the first weeks of life

T. Wielek; R. Del Giudice; A. Lang; M. Wislowska; P. Ott; M. Schabus

doi:10.1371/journal.pone.0224521

On the development of sleep states in the first weeks of life

T. Wielek
, R. Del Giudice
, A. Lang
, M. Wislowska
, P. Ott
, M. Schabus

Information Technologies and Digitalisation

Laboratory for Sleep, Cognition and Consciousness Research, University of Salzburg
Centre for Cognitive Neuroscience, University of Salzburg
Department of Health Sciences, Università degli Studi di Milano

Research output: Contribution to journal › Article › peer-review

Abstract

Human newborns spend up to 18 hours sleeping. The organization of their sleep differs immensely from adult sleep, and its quick maturation and fundamental changes correspond to the rapid cortical development at this age. Manual sleep classification is specifically challenging in this population given major body movements and frequent shifts between vigilance states; in addition various staging criteria co-exist. In the present study we utilized a machine learning approach and investigated how EEG complexity and sleep stages evolve during the very first weeks of life. We analyzed 42 full-term infants which were recorded twice (at week two and five after birth) with full polysomnography. For sleep classification EEG signal complexity was estimated using multi-scale permutation entropy and fed into a machine learning classifier. Interestingly the baby's brain signal complexity (and spectral power) revealed developmental changes in sleep in the first 5 weeks of life, and were restricted to NREM ("quiet") and REM ("active sleep") states with little to no changes in state wake. Data demonstrate that our classifier performs well over chance (i.e., >33% for 3-class classification) and reaches almost human scoring accuracy (60% at week-2, 73% at week- 5). Altogether, these results demonstrate that characteristics of newborn sleep develop rapidly in the first weeks of life and can be efficiently identified by means of machine learning techniques.

Original language	English
Pages (from-to)	e0224521
Journal	PLoS ONE
Volume	14
Issue number	10
DOIs	https://doi.org/10.1371/journal.pone.0224521
Publication status	Published - 29 Oct 2019

Keywords

article
classifier
controlled study
electroencephalogram
entropy
human
infant
newborn
nonREM sleep
polysomnography
brain
electroencephalography
female
machine learning
male
physiology
procedures
REM sleep
sleep
sleep stage
wakefulness
Brain
Electroencephalography
Female
Humans
Infant, Newborn
Machine Learning
Male
Polysomnography
Sleep
Sleep Stages
Sleep, REM
Wakefulness

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10.1371/journal.pone.0224521

https://www.scopus.com/inward/record.uri?eid=2-s2.0-85074283319&doi=10.1371%2fjournal.pone.0224521&partnerID=40&md5=0a3f7c600974a7ccd4ebda7065b29bbd

Cite this

@article{00b3b46e61ad410daf21ec2ed951c31b,

title = "On the development of sleep states in the first weeks of life",

abstract = "Human newborns spend up to 18 hours sleeping. The organization of their sleep differs immensely from adult sleep, and its quick maturation and fundamental changes correspond to the rapid cortical development at this age. Manual sleep classification is specifically challenging in this population given major body movements and frequent shifts between vigilance states; in addition various staging criteria co-exist. In the present study we utilized a machine learning approach and investigated how EEG complexity and sleep stages evolve during the very first weeks of life. We analyzed 42 full-term infants which were recorded twice (at week two and five after birth) with full polysomnography. For sleep classification EEG signal complexity was estimated using multi-scale permutation entropy and fed into a machine learning classifier. Interestingly the baby's brain signal complexity (and spectral power) revealed developmental changes in sleep in the first 5 weeks of life, and were restricted to NREM ({"}quiet{"}) and REM ({"}active sleep{"}) states with little to no changes in state wake. Data demonstrate that our classifier performs well over chance (i.e., >33\% for 3-class classification) and reaches almost human scoring accuracy (60\% at week-2, 73\% at week- 5). Altogether, these results demonstrate that characteristics of newborn sleep develop rapidly in the first weeks of life and can be efficiently identified by means of machine learning techniques.",

keywords = "article, classifier, controlled study, electroencephalogram, entropy, human, infant, newborn, nonREM sleep, polysomnography, brain, electroencephalography, female, machine learning, male, physiology, procedures, REM sleep, sleep, sleep stage, wakefulness, Brain, Electroencephalography, Female, Humans, Infant, Newborn, Machine Learning, Male, Polysomnography, Sleep, Sleep Stages, Sleep, REM, Wakefulness",

author = "T. Wielek and \{Del Giudice\}, R. and A. Lang and M. Wislowska and P. Ott and M. Schabus",

note = "Cited By :12 Export Date: 14 December 2023 CODEN: POLNC Correspondence Address: Wielek, T.; Laboratory for Sleep, Austria; email: [email protected] Funding details: Y-777 Funding details: Austrian Science Fund, FWF, W1233-G17 Funding text 1: The study was supported by a grant from the Austrian Science Fund FWF (Y-777). TW, AL, MW, were additionally supported by the Doctoral College ''Imaging the Mind'' (FWF; W1233-G17). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. References: Iber, C., Ancoli-Israel, S., Chesson, A., Quan, S., (2007) The AASM Manual for the Scoring of Sleep and Associated Events: Rules Terminology and Technical Specifications, , American Academy of Sleep Medicine. Westchester: American Academy of Sleep Medicine;; Grigg-Damberger, M.M., The visual scoring of sleep in infants 0 to 2 months of age (2016) J Clin Sleep Med., 12 (3), pp. 429-445. , https://doi.org/10.5664/jcsm.5600, PMID: 26951412; Ellingson, R.J., Electroencephalograms of normal, full-term newborns immediately after birth with observations on arousal and visual evoked responses (1958) Electroencephalogr Clin Neurophysiol., 10 (1), pp. 31-50. , https://doi.org/10.1016/0013-4694(58)90101-9, PMID: 13512217; Whitehead, K., Pressler, R., Fabrizi, L., Characteristics and clinical significance of delta brushes in the EEG of premature infants (2017) Clin Neurophysiol Pract., 2, pp. 12-18. , https://doi.org/10.1016/j.cnp.2016.11.002, PMID: 30214965; Anders, T.F., Emde, T., Parmelee, A., (1971) A Manual of Standardized Terminology, Techniques and Criteria for Scoring States of Sleep and Wakefulness in Newborn Infants., , Los Angeles, CA: UCLA Brain Information Service, NINDS Neurological information Network; Scholle, S., Sch{\"a}fer, T., Atlas of states of sleep and wakefulness in infants and children (1999) Somnologie- Schlafforschung und Schlafmedizin., 3 (4), pp. 163-241; Anders, T.F., Keener, M.A., Kraemer, H., Sleep-wake state organization, neonatal assessment and development in premature infants during the first year of life. II (1985) Sleep, 8 (3), pp. 193-206. , https://doi.org/10.1093/sleep/8.3.193, PMID: 4048735; Borghese, I.F., Minard, K.L., Thoman, E.B., Sleep rhythmicity in premature infants: Implications for development status (1995) Sleep, 18 (7), pp. 523-530. , https://doi.org/10.1093/sleep/18.7.523, PMID: 8552921; Gertner, S., Greenbaum, C.W., Sadeh, A., Dolfin, Z., Sirota, L., Ben-Nun, Y., Sleep-wake patterns in preterm infants and 6 month's home environment: Implications for early cognitive development (2002) Early Hum Dev., 68 (2), pp. 93-102. , https://doi.org/10.1016/s0378-3782(02)00018-x, PMID: 12113995; Freudigman, K.A., Thoman, E.B., Infant sleep during the first postnatal day: An opportunity for assessment of vulnerability (1993) Pediatrics, 92 (3), pp. 373-379. , PMID: 7689726; Crowell, D.H., Brooks, L.J., Colton, T., Corwin, M.J., Hoppenbrouwers, T.T., Hunt, C.E., Infant polysomnography: Reliability (1997) Sleep, 20 (7), pp. 553-560. , Collaborative Home Infant Monitoring Evaluation (CHIME) Steering Committee, PMID: 9322271; Satomaa, A.L., Saarenpaa-Heikkila, O., Paavonen, E.J., Himanen, S.L., The adapted American Academy of Sleep Medicine sleep scoring criteria in one month old infants: A means to improve comparability? (2016) Clin Neurophysiol., 127 (2), pp. 1410-1418. , https://doi.org/10.1016/j.clinph.2015.08.013, PMID: 26520455; Ma, Y., Shi, W., Peng, C.K., Yang, A.C., Nonlinear dynamical analysis of sleep electroencephalography using fractal and entropy approaches (2018) Sleep Med Rev., 37, pp. 85-93. , https://doi.org/10.1016/j.smrv.2017.01.003, PMID: 28392169; Jordan, D., Stockmanns, G., Kochs, E.F., Pilge, S., Schneider, G., Electroencephalographic order pattern analysis for the separation of consciousness and unconsciousness: An analysis of approximate entropy, permutation entropy, recurrence rate, and phase coupling of order recurrence plots (2008) Anesthesiology, 109 (6), pp. 1014-1022. , https://doi.org/10.1097/ALN.0b013e31818d6c55, PMID: 19034098; Miskovic, V., MacDonald, K.J., Rhodes, L.J., Cote, K.A., Changes in EEG multiscale entropy and power-law frequency scaling during the human sleep cycle (2018) Hum Brain Mapp.; Shen, Y., Olbrich, E., Achermann, P., Meier, P.F., Dimensional complexity and spectral properties of the human sleep EEG. Electroencephalograms (2003) Clin Neurophysiol., 114 (2), pp. 199-209. , https://doi.org/10.1016/s1388-2457(02)00338-3, PMID: 12559226; Olofsen, E., Sleigh, J.W., Dahan, A., Permutation entropy of the electroencephalogram: A measure of anaesthetic drug effect (2008) Br J Anaesth., 101 (6), pp. 810-821. , https://doi.org/10.1093/bja/aen290, PMID: 18852113; Burioka, N., Miyata, M., Cornelissen, G., Halberg, F., Takeshima, T., Kaplan, D.T., Approximate entropy in the electroencephalogram during wake and sleep (2005) Clin EEG Neurosci., 36 (1), pp. 21-24. , https://doi.org/10.1177/155005940503600106, PMID: 15683194; Bruce, E.N., Bruce, M.C., Vennelaganti, S., Sample entropy tracks changes in electroencephalogram power spectrum with sleep state and aging (2009) J Clin Neurophysiol., 26 (4), pp. 257-266. , https://doi.org/10.1097/WNP.0b013e3181b2f1e3, PMID: 19590434; Nicolaou, N., Georgiou, J., The use of permutation entropy to characterize sleep electroencephalograms (2011) Clin EEG Neurosci., 42 (1), pp. 24-28. , https://doi.org/10.1177/155005941104200107, PMID: 21309439; Janjarasjitt, S., Scher, M.S., Loparo, K.A., Nonlinear dynamical analysis of the neonatal EEG time series: The relationship between sleep state and complexity (2008) Clin Neurophysiol., 119 (8), pp. 1812-1823. , https://doi.org/10.1016/j.clinph.2008.03.024, PMID: 18486543; Wislowska, M., Giudice, R.D., Lechinger, J., Wielek, T., Heib, D.P., Pitiot, A., Night and day variations of sleep in patients with disorders of consciousness (2017) Sci Rep., 7 (1), p. 266. , https://doi.org/10.1038/s41598-017-00323-4, PMID: 28325926; McIntosh, A.R., Kovacevic, N., Itier, R.J., Increased brain signal variability accompanies lower behavioral variability in development (2008) PLoS Comput Biol., 4 (7), p. e1000106. , https://doi.org/10.1371/journal.pcbi.1000106, PMID: 18604265; Waschke, L., Wostmann, M., Obleser, J., States and traits of neural irregularity in the age-varying human brain (2017) Sci Rep., 7 (1), p. 17381. , https://doi.org/10.1038/s41598-017-17766-4, PMID: 29234128; Zhang, D., Ding, H., Liu, Y., Zhou, C., Ding, H., Ye, D., Neurodevelopment in newborns: A sample entropy analysis of electroencephalogram (2009) Physiol Meas., 30 (5), pp. 491-504. , https://doi.org/10.1088/0967-3334/30/5/006, PMID: 19369713; Sterman, M.B., Harper, R.M., Havens, B., Hoppenbrouwers, T., McGinty, D.J., Hodgman, J.E., Quantitative analysis of infant EEG development during quiet sleep (1977) Electroencephalogr Clin Neurophysiol., 43 (3), pp. 371-385. , https://doi.org/10.1016/0013-4694(77)90260-7, PMID: 70338; Scher, M.S., Neurophysiological assessment of brain function and maturation. 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year = "2019",

month = oct,

day = "29",

doi = "10.1371/journal.pone.0224521",

language = "English",

volume = "14",

pages = "e0224521",

journal = "PLoS ONE",

issn = "1932-6203",

publisher = "Public Library of Science",

number = "10",

}

TY - JOUR

T1 - On the development of sleep states in the first weeks of life

AU - Wielek, T.

AU - Del Giudice, R.

AU - Lang, A.

AU - Wislowska, M.

AU - Ott, P.

AU - Schabus, M.

N1 - Cited By :12 Export Date: 14 December 2023 CODEN: POLNC Correspondence Address: Wielek, T.; Laboratory for Sleep, Austria; email: [email protected] Funding details: Y-777 Funding details: Austrian Science Fund, FWF, W1233-G17 Funding text 1: The study was supported by a grant from the Austrian Science Fund FWF (Y-777). TW, AL, MW, were additionally supported by the Doctoral College ''Imaging the Mind'' (FWF; W1233-G17). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. References: Iber, C., Ancoli-Israel, S., Chesson, A., Quan, S., (2007) The AASM Manual for the Scoring of Sleep and Associated Events: Rules Terminology and Technical Specifications, , American Academy of Sleep Medicine. Westchester: American Academy of Sleep Medicine;; Grigg-Damberger, M.M., The visual scoring of sleep in infants 0 to 2 months of age (2016) J Clin Sleep Med., 12 (3), pp. 429-445. , https://doi.org/10.5664/jcsm.5600, PMID: 26951412; Ellingson, R.J., Electroencephalograms of normal, full-term newborns immediately after birth with observations on arousal and visual evoked responses (1958) Electroencephalogr Clin Neurophysiol., 10 (1), pp. 31-50. , https://doi.org/10.1016/0013-4694(58)90101-9, PMID: 13512217; Whitehead, K., Pressler, R., Fabrizi, L., Characteristics and clinical significance of delta brushes in the EEG of premature infants (2017) Clin Neurophysiol Pract., 2, pp. 12-18. , https://doi.org/10.1016/j.cnp.2016.11.002, PMID: 30214965; Anders, T.F., Emde, T., Parmelee, A., (1971) A Manual of Standardized Terminology, Techniques and Criteria for Scoring States of Sleep and Wakefulness in Newborn Infants., , Los Angeles, CA: UCLA Brain Information Service, NINDS Neurological information Network; Scholle, S., Schäfer, T., Atlas of states of sleep and wakefulness in infants and children (1999) Somnologie- Schlafforschung und Schlafmedizin., 3 (4), pp. 163-241; Anders, T.F., Keener, M.A., Kraemer, H., Sleep-wake state organization, neonatal assessment and development in premature infants during the first year of life. II (1985) Sleep, 8 (3), pp. 193-206. , https://doi.org/10.1093/sleep/8.3.193, PMID: 4048735; Borghese, I.F., Minard, K.L., Thoman, E.B., Sleep rhythmicity in premature infants: Implications for development status (1995) Sleep, 18 (7), pp. 523-530. , https://doi.org/10.1093/sleep/18.7.523, PMID: 8552921; Gertner, S., Greenbaum, C.W., Sadeh, A., Dolfin, Z., Sirota, L., Ben-Nun, Y., Sleep-wake patterns in preterm infants and 6 month's home environment: Implications for early cognitive development (2002) Early Hum Dev., 68 (2), pp. 93-102. , https://doi.org/10.1016/s0378-3782(02)00018-x, PMID: 12113995; Freudigman, K.A., Thoman, E.B., Infant sleep during the first postnatal day: An opportunity for assessment of vulnerability (1993) Pediatrics, 92 (3), pp. 373-379. , PMID: 7689726; Crowell, D.H., Brooks, L.J., Colton, T., Corwin, M.J., Hoppenbrouwers, T.T., Hunt, C.E., Infant polysomnography: Reliability (1997) Sleep, 20 (7), pp. 553-560. , Collaborative Home Infant Monitoring Evaluation (CHIME) Steering Committee, PMID: 9322271; Satomaa, A.L., Saarenpaa-Heikkila, O., Paavonen, E.J., Himanen, S.L., The adapted American Academy of Sleep Medicine sleep scoring criteria in one month old infants: A means to improve comparability? (2016) Clin Neurophysiol., 127 (2), pp. 1410-1418. , https://doi.org/10.1016/j.clinph.2015.08.013, PMID: 26520455; Ma, Y., Shi, W., Peng, C.K., Yang, A.C., Nonlinear dynamical analysis of sleep electroencephalography using fractal and entropy approaches (2018) Sleep Med Rev., 37, pp. 85-93. , https://doi.org/10.1016/j.smrv.2017.01.003, PMID: 28392169; Jordan, D., Stockmanns, G., Kochs, E.F., Pilge, S., Schneider, G., Electroencephalographic order pattern analysis for the separation of consciousness and unconsciousness: An analysis of approximate entropy, permutation entropy, recurrence rate, and phase coupling of order recurrence plots (2008) Anesthesiology, 109 (6), pp. 1014-1022. , https://doi.org/10.1097/ALN.0b013e31818d6c55, PMID: 19034098; Miskovic, V., MacDonald, K.J., Rhodes, L.J., Cote, K.A., Changes in EEG multiscale entropy and power-law frequency scaling during the human sleep cycle (2018) Hum Brain Mapp.; Shen, Y., Olbrich, E., Achermann, P., Meier, P.F., Dimensional complexity and spectral properties of the human sleep EEG. Electroencephalograms (2003) Clin Neurophysiol., 114 (2), pp. 199-209. , https://doi.org/10.1016/s1388-2457(02)00338-3, PMID: 12559226; Olofsen, E., Sleigh, J.W., Dahan, A., Permutation entropy of the electroencephalogram: A measure of anaesthetic drug effect (2008) Br J Anaesth., 101 (6), pp. 810-821. , https://doi.org/10.1093/bja/aen290, PMID: 18852113; Burioka, N., Miyata, M., Cornelissen, G., Halberg, F., Takeshima, T., Kaplan, D.T., Approximate entropy in the electroencephalogram during wake and sleep (2005) Clin EEG Neurosci., 36 (1), pp. 21-24. , https://doi.org/10.1177/155005940503600106, PMID: 15683194; Bruce, E.N., Bruce, M.C., Vennelaganti, S., Sample entropy tracks changes in electroencephalogram power spectrum with sleep state and aging (2009) J Clin Neurophysiol., 26 (4), pp. 257-266. , https://doi.org/10.1097/WNP.0b013e3181b2f1e3, PMID: 19590434; Nicolaou, N., Georgiou, J., The use of permutation entropy to characterize sleep electroencephalograms (2011) Clin EEG Neurosci., 42 (1), pp. 24-28. , https://doi.org/10.1177/155005941104200107, PMID: 21309439; Janjarasjitt, S., Scher, M.S., Loparo, K.A., Nonlinear dynamical analysis of the neonatal EEG time series: The relationship between sleep state and complexity (2008) Clin Neurophysiol., 119 (8), pp. 1812-1823. , https://doi.org/10.1016/j.clinph.2008.03.024, PMID: 18486543; Wislowska, M., Giudice, R.D., Lechinger, J., Wielek, T., Heib, D.P., Pitiot, A., Night and day variations of sleep in patients with disorders of consciousness (2017) Sci Rep., 7 (1), p. 266. , https://doi.org/10.1038/s41598-017-00323-4, PMID: 28325926; McIntosh, A.R., Kovacevic, N., Itier, R.J., Increased brain signal variability accompanies lower behavioral variability in development (2008) PLoS Comput Biol., 4 (7), p. e1000106. , https://doi.org/10.1371/journal.pcbi.1000106, PMID: 18604265; Waschke, L., Wostmann, M., Obleser, J., States and traits of neural irregularity in the age-varying human brain (2017) Sci Rep., 7 (1), p. 17381. , https://doi.org/10.1038/s41598-017-17766-4, PMID: 29234128; Zhang, D., Ding, H., Liu, Y., Zhou, C., Ding, H., Ye, D., Neurodevelopment in newborns: A sample entropy analysis of electroencephalogram (2009) Physiol Meas., 30 (5), pp. 491-504. , https://doi.org/10.1088/0967-3334/30/5/006, PMID: 19369713; Sterman, M.B., Harper, R.M., Havens, B., Hoppenbrouwers, T., McGinty, D.J., Hodgman, J.E., Quantitative analysis of infant EEG development during quiet sleep (1977) Electroencephalogr Clin Neurophysiol., 43 (3), pp. 371-385. , https://doi.org/10.1016/0013-4694(77)90260-7, PMID: 70338; Scher, M.S., Neurophysiological assessment of brain function and maturation. 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PY - 2019/10/29

Y1 - 2019/10/29

N2 - Human newborns spend up to 18 hours sleeping. The organization of their sleep differs immensely from adult sleep, and its quick maturation and fundamental changes correspond to the rapid cortical development at this age. Manual sleep classification is specifically challenging in this population given major body movements and frequent shifts between vigilance states; in addition various staging criteria co-exist. In the present study we utilized a machine learning approach and investigated how EEG complexity and sleep stages evolve during the very first weeks of life. We analyzed 42 full-term infants which were recorded twice (at week two and five after birth) with full polysomnography. For sleep classification EEG signal complexity was estimated using multi-scale permutation entropy and fed into a machine learning classifier. Interestingly the baby's brain signal complexity (and spectral power) revealed developmental changes in sleep in the first 5 weeks of life, and were restricted to NREM ("quiet") and REM ("active sleep") states with little to no changes in state wake. Data demonstrate that our classifier performs well over chance (i.e., >33% for 3-class classification) and reaches almost human scoring accuracy (60% at week-2, 73% at week- 5). Altogether, these results demonstrate that characteristics of newborn sleep develop rapidly in the first weeks of life and can be efficiently identified by means of machine learning techniques.

AB - Human newborns spend up to 18 hours sleeping. The organization of their sleep differs immensely from adult sleep, and its quick maturation and fundamental changes correspond to the rapid cortical development at this age. Manual sleep classification is specifically challenging in this population given major body movements and frequent shifts between vigilance states; in addition various staging criteria co-exist. In the present study we utilized a machine learning approach and investigated how EEG complexity and sleep stages evolve during the very first weeks of life. We analyzed 42 full-term infants which were recorded twice (at week two and five after birth) with full polysomnography. For sleep classification EEG signal complexity was estimated using multi-scale permutation entropy and fed into a machine learning classifier. Interestingly the baby's brain signal complexity (and spectral power) revealed developmental changes in sleep in the first 5 weeks of life, and were restricted to NREM ("quiet") and REM ("active sleep") states with little to no changes in state wake. Data demonstrate that our classifier performs well over chance (i.e., >33% for 3-class classification) and reaches almost human scoring accuracy (60% at week-2, 73% at week- 5). Altogether, these results demonstrate that characteristics of newborn sleep develop rapidly in the first weeks of life and can be efficiently identified by means of machine learning techniques.

KW - article

KW - classifier

KW - controlled study

KW - electroencephalogram

KW - entropy

KW - human

KW - infant

KW - newborn

KW - nonREM sleep

KW - polysomnography

KW - brain

KW - electroencephalography

KW - female

KW - machine learning

KW - male

KW - physiology

KW - procedures

KW - REM sleep

KW - sleep

KW - sleep stage

KW - wakefulness

KW - Brain

KW - Electroencephalography

KW - Female

KW - Humans

KW - Infant, Newborn

KW - Machine Learning

KW - Male

KW - Polysomnography

KW - Sleep

KW - Sleep Stages

KW - Sleep, REM

KW - Wakefulness

UR - https://www.mendeley.com/catalogue/0fe77df9-bfe4-3a53-8a04-d81b590e7ed9/

U2 - 10.1371/journal.pone.0224521

DO - 10.1371/journal.pone.0224521

M3 - Article

C2 - 31661522

SN - 1932-6203

VL - 14

SP - e0224521

JO - PLoS ONE

JF - PLoS ONE

IS - 10

ER -

On the development of sleep states in the first weeks of life

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