This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Hillman NH, Kallapur SG, Jobe AH. Physiology of transition from intrauterine to extrauterine life. Clin Perinatol 2012; 39:769–783.HillmanNHKallapurSGJobeAHPhysiology of transition from intrauterine to extrauterine life201239769783Search in Google Scholar
Mulkey SB, du Plessis A. The critical role of the central autonomic nervous system in fetal-neonatal transition. Semin Pediatr Neurol 2018; 28:29–37.MulkeySBdu PlessisAThe critical role of the central autonomic nervous system in fetal-neonatal transition2018282937Search in Google Scholar
Słabuszewska-Jóźwiak A, Szymański JK, Ciebiera M, Sarecka-Hujar B, Jakiel G. Pediatrics Consequences of Caesarean Section - A Systematic Review and Meta-Analysis. Int J Environ Res Public Health 2020; 17 (21):8031. doi:10.3390/ijerph17218031. PMID: 33142727; PMCID: PMC7662709.Słabuszewska-JóźwiakASzymańskiJKCiebieraMSarecka-HujarBJakielGPediatrics Consequences of Caesarean Section - A Systematic Review and Meta-Analysis20201721803110.3390/ijerph1721803133142727PMC7662709Open DOISearch in Google Scholar
Longin E, Gerstner T, Schaible T, Lenz T, König S. Maturation of the autonomic nervous system: Differences in heart rate variability in premature vs. term infants. J Perinat Med 2006; 34 (4):303–308.LonginEGerstnerTSchaibleTLenzTKönigSMaturation of the autonomic nervous system: Differences in heart rate variability in premature vs. term infants2006344303308Search in Google Scholar
Patural H, Pichot V, Flori S, Giraud A, Franco P, Pladys P, Beuchée A, Frédéric R, Barthelemy JC. Autonomic maturation from birth to 2 years: normative values. Heliyon 2019; 5 (3):e01300.PaturalHPichotVFloriSGiraudAFrancoPPladysPBeuchéeAFrédéricRBarthelemyJCAutonomic maturation from birth to 2 years: normative values201953e01300Search in Google Scholar
Aldosky HYY, Bari DS: Electrodermal Activity: Simultaneous Recordings. In: El-Azazy M, Mim M, Annus P (eds). Electrochem Impedance Spectrosc. London: IntechOpen; 2019, pp 1–16.AldoskyHYYBariDSElectrodermal Activity: Simultaneous RecordingsIn:El-AzazyMMimMAnnusP(eds).LondonIntechOpen2019116Search in Google Scholar
Dawson ME, Schell AM, Filion DL. The electrodermal system. In: Cacioppo JT, Tassinary LG, Berntson GG (eds). Handbook of Psychophysiology. Fourth Edition. Cambridge: Cambridge University Press; 2016, pp 217–243.DawsonMESchellAMFilionDLThe electrodermal systemIn:CacioppoJTTassinaryLGBerntsonGG(eds).Fourth EditionCambridgeCambridge University Press2016217243Search in Google Scholar
Hernes KG. Skin conductance changes during the first year of life in full-term infants. Pediatr Res 2002; 52 (6):837–843.HernesKGSkin conductance changes during the first year of life in full-term infants2002526837843Search in Google Scholar
Harpin VA, Rutter N. Development of emotional sweating in the newborn infant. Arch Dis Child 1982; 57 (9):691–695.HarpinVARutterNDevelopment of emotional sweating in the newborn infant1982579691695Search in Google Scholar
Mulkey SB, Kota S, Govindan RB et al. The effect of labor and delivery mode on electrocortical and brainstem autonomic function during neonatal transition. Sci Rep 2019; 9:11020. https://doi.org/10.1038/s41598-019-47306-1MulkeySBKotaSGovindanRBThe effect of labor and delivery mode on electrocortical and brainstem autonomic function during neonatal transition2019911020https://doi.org/10.1038/s41598-019-47306-1Search in Google Scholar
Fowles DC. The Measurement of Electrodermal Activity in Children. In: Schmidt LA, Segalowitz SJ (eds). Developmental Psychophysiology: Theory, Systems, and Methods. Cambridge: Cambridge University Press; 2007, pp 286–316.FowlesDCThe Measurement of Electrodermal Activity in ChildrenIn:SchmidtLASegalowitzSJ(eds).CambridgeCambridge University Press2007286316Search in Google Scholar
Posada-Quintero HF, Florian JP, Orjuela-Canon AD, Aljama-Corrales T, Charleston-Villalobos S, Chon KH. Power Spectral Density Analysis of Electrodermal Activity for Sympathetic Function Assessment. Ann Biomed Eng 2016; 44 (10):3124–3135.Posada-QuinteroHFFlorianJPOrjuela-CanonADAljama-CorralesTCharleston-VillalobosSChonKHPower Spectral Density Analysis of Electrodermal Activity for Sympathetic Function Assessment2016441031243135Search in Google Scholar
Boucsein W, Fowles DC, Grimnes S, Ben-Shakhar G, Roth WT, Dawson ME, Filion DL. Publication recommendations for electrodermal measurements. Psychophysiology 2012; 49 (8): 1017–1034.BoucseinWFowlesDCGrimnesSBen-ShakharGRothWTDawsonMEFilionDLPublication recommendations for electrodermal measurements201249810171034Search in Google Scholar
Bari, D.S. Gender differences in tonic and phasic electrodermal activity components. SJUOZ 2020; 8 (1):29–30.BariD.S.Gender differences in tonic and phasic electrodermal activity components2020812930Search in Google Scholar
Javorka K. Variabilita frekvencie srdca. Mechanizmy, hodnotenie, klinické vyuźitie. Vydavatełstvo Osveta: Martin; 2008.JavorkaKVydavatełstvo OsvetaMartin2008Search in Google Scholar
Thorlacius K, Zhoujun C, Bodelsson M. Effects of sevoflurane on sympathetic neurotransmission in human omental arteries and veins. Br. J. Anaesth 2003; 90:766–773.ThorlaciusKZhoujunCBodelssonMEffects of sevoflurane on sympathetic neurotransmission in human omental arteries and veins200390766773Search in Google Scholar