differences between adjacent NN int

differences between adjacent NN intervals. Thereafter, the variability of the resulting pattern is assessed based on the geometric and/or graphic properties. The most commonly used geometric indices include:
1. The integral of the sample density distribution of NN intervals di- vided by the maximum of the density distribution (NN triangular index) with a normative value of 37 ± 15 ms [3,14]. This indicator characterizes overall HRV measured over 24 h and it is driven pri- marily by SNS but it is also influenced to some degree by the PNS [3].
2. Baseline width of the minimum square difference triangular inter- polation of the maximum of the sample density distribution of NN intervals (TINN; in ms) that characterizes primarily the SNS but may be also influenced to some degree by the PNS [3].
3.4. Frequency-domain methods
The frequency-domain indicators of HRV are based on the distri- bution of power (variance) as a function of frequency of the time dif- ference between successive NN intervals, also known as power spectral density. The methodologies used to estimate the latter are classified into parametric and nonparametric which, in most cases, provide comparable results. A detailed discussion of the advantages and disadvantages of parametric and nonparametric methods is be- yond the scope of the present review and can be found elsewhere [3]. It is crucial to indicate that the VLF, LF, and HF power components are measured in absolute values of power (m2). However, LF and HF may be measured by normalized units, which represent the relative value of each power component. This measurement may indicate the controlled and balanced behavior of the ANS [3]. The most com- monly used frequency-domain indices distinguished in a spectrum calculated from short-term recordings of 2–5 min [30,32,38–40] are:
1. Very Low Frequency (VLF) in the range of 0.0033—0.04 Hz [14,41]. The physiological interpretation of VLF in relation to autonomic function warrants further elucidation.
2. Low Frequency (LF) band in the range of 0.04—0.15 Hz. It has been suggested that SNS activation is the main contributor of LF, partic- ularly when LF is expressed in normalized units. There is some controversy, however, as others have suggested that LF is also influenced by PNS activity [3,14,41,42].
3. HighFrequency(HF)bandintherangeof0.15—0.40Hzissuggested to be mainly driven by respiration and PNS activity [3,14,41].
4. The ratio of LF and HF frequency band powers (LF/HF), with nor- mative values of 1.5–2.0 indicating the balance between SNS and PNS [3,14].
5. The total variance of all NN intervals, called total power, corre- sponds to the sum of all spectral bands (i.e., 0.0—0.5 Hz) [3,14,41].
It is important to note that frequency-domain indicators can be
also used to analyze the sequence of NN intervals of the entire 24- hour period. In this case, however, the result also includes an ultra low frequency (ULF) band (in addition to VLF, LF, and HF compo- nents) between 0 and 0.0033 Hz [3].
4. Active smoking and HRV
4.1. Chronic effects
The influence of chronic active smoking on HRV has been studied extensively (Table 1). The first published evidence was provided by Penny and Mir [43] demonstrating a decreased HRV in chronic cigarette smokers compared to non-smokers. In the following years, a number of epidemiological studies were conducted, the vast majority of which confirmed that HRV is decreased in chronic active smokers. Specifically, Hayano and colleagues found a decreased vagal activation in heavy