The way in which the Root Mean Square of the Successive Differences between adjacent RR intervals (RMSSD) recovers immediately after exercise could be a good indicator of internal training load (ITL). The aim of this study is to design a recovery index based on RMSSD. Forteen healthy men took part in this study. The experiment lasted 2 weeks, with 4 separate (48 - 72 h) sessions. First session was an incremental treadmill test to determine ventilatory thresholds (VT1 and VT2) and maximal aerobic speed (MAS). Each subject ran at VT1 speed (second day), VT2 speed (third day) and a time-to-exhaustion test at MAS (fourth day). The duration of VT1 and VT2 loads was selected in such a way that the product intensity-duration (training load) was the same. HRV was measured from 10’ prior to test (Rest) to 30’ after completed (Recovery). Recovery slopes were calculated from RMSSD values at 10 and 30 minutes. Borg scale was recorded at the end of every test and the Training Impulse (TRIMP) values were calculated using Banister equations. The RMSSD values dropped substantially regardless of the intensity and the duration of exercise (average 4 ms). The RMSSD recovery was linear during the 30 min and different depending on the intensity of exercise. To propose a recovery index, we calculated the slope of RMSDD over the 30 minutes (slope-30) and also the first 10 minutes (slope-10). Given that the slopes presented an exponential behavior in relation with effort intensity, three curves were obtained (average values, plus SD and minus SD) defining a nomogram. For practical application, we propose: 1) to measure RMSSD the last 5 minutes of exercise and any period of 5 minutes during the first 30 minutes recovery; 2) to calculate the slope of RMSSD between exercise and recovery; 3) to compare with the nomogram.
There is a great deal of interest in controlling training load (TL) in athletes [
However, there are still discrepancies and some conflicting results that prevent clear conclusions from being reached that could be applied simply and directly to the control of training load. In fact, the most recent meta-analysis that analyzes the relationship between measures of ITL and ETL [
Most HRV studies evaluate the changes in different variables during recovery, immediately after exercise to evaluate how these values recover [
Furthermore, the prevailing idea in the literature is that the most useful approach is to explore different exercise intensities [
To our knowledge, most of previous studies did not adjust intensity and volume to obtain the same TL. Furthermore, no useful HRV post-exercise indexes can be easily applied for the control of TL, although two indexes have been previously reported [
Our hypothesis is that the way in which RMSSD recovers immediately after exercise could be a good indicator of ITL. So, the aim of this study is to design a recovery index based on RMSSD and to propose the way to use it in daily training.
A total of 14 men (Sports Science students) took part in this study during 2 weeks, all of whom were healthy, non-smokers and physically active but not participating in any athletic sport (age 20.93 ± 1.38 years; weight 75.34 ± 10.07 kg; height 178.04 ± 5.83 cm; VO2max 49.33 ± 3.93 ml∙kg−1∙min−1). It was a convenience sample and highly homogeneous.
Following the general indications of the Task Force [
Each subject was given a medical questionnaire to ensure that they were not receiving treatments or suffering from cardiovascular or any other disorder that might alter the state of the autonomic nervous system. All the subjects were informed of the procedure that would be followed, and they gave their written consent to take part in the experiment. The Local Ethics Board approved the study, which followed all the principles expressed in the Declaration of Helsinki [
Experimental design
The experiment lasted a total of 2 weeks, with 4 separate sessions with 48 - 72 h intervals between each one, taking place at approximately the same time of day (10:00 ± 2 h) and maintaining stable environmental conditions (temperature and humidity).
At the first session, a background questionnaire was completed for each subject, and all the participants’ height and weight measurements were taken. An incremental and maximal cardiopulmonary exercise test was performed on an ErgoRun Medical 8 treadmill (Daum Electronic; Fürth, Germany) following a steps protocol with an initial speed of 7 km/h for 3 minutes and increases of 1 km/h each minute until volitional exhaustion. A slope of 1% was fixed during the entire test. The test was carried out using a Breezesuite CPX ergospirometric equipment (Medical Graphics; St. Paul, Minnesota, USA) calibrated prior to each measurement. The ventilation data were obtained breath by breath using a differential pressure-based flow-meter, as well as the inspiratory and expiratory fractions of O2 and CO2 based on a galvanic cell and infrared analyser respectively.
For the purposes of this study, ventilatory thresholds (VT1 and VT2) were determined following the method proposed by Skinner and McLellan [
Maximal Aerobic Speed (MAS) was assessed as the speed at which VO2 plateau started.
At each session, training load was calculated as the product of intensity (speed) by volume (time) [
At the second session, each subject ran constantly for 20 minutes at VT1 speed. Given the low intensity, no prior warm-up was needed.
At the third session, each subject ran constantly at VT2 speed. In order to ensure the same TL, the time was established in such a way that the product (intensity per duration) was the same as for VT1. In this way, the same distance was covered both in VT1 and VT2 test. This test was preceded by a 5 minutes warm-up at 60% of MAS.
At the fourth session, a time-to-exhaustion test was carried out for Maximal Aerobic Speed (MAS). Given that this speed was very high, it was achieved gradually over a 2 minutes period: 90 seconds at 70% of MAS followed by 30 seconds at 80% of MAS.
At sessions 2, 3 and 4, a V800 Polar HR monitor was fitted onto the subjects, with an H10 Sensor thoracic band (Polar Inc., Kempele, Finland). HRV measurements were recorded from 8 minutes prior to the test until 30 minutes after the test was completed. All the pre and post exercise measurements were taken with the subject in a seated position and in a calm and quiet environment. The subject had to sit down immediately after finishing the test (with no active cool down) in order to measure their recovery.
The RR time series were downloaded using the Polar Flow Sync application (version 2.6.2) to be analyzed using Kubios HRV software (Version 2.1, University of Eastern Finland, Kuopio, Finland).
At each session, the last 5 minutes of the rest and exercise records were taken. In the case of the 30-minute recovery period (rec), measurements were divided into 5-minute slots, starting at minute 10 (rec 10, rec 15, rec 20, rec 25, rec 30). HRV was not quantified the first 5 minute of recovery because of the loss of time series stability derived from the sudden change between the end of the exercise and the start of recovery [
Each record was analyzed previously to detect the possible presence of artifacts and anomalous beats, applying the corresponding filters if required.
In order to develop a simple methodology easy to use in real assessments of athletes, analysis was conducted using one variable for parasympathetic stimulus. In accordance with the literature [
To propose a recovery index based on HRV, we calculated the recovery slope of the RMSDD values over the course of 30 minutes (slope-30). As in the daily training 30 minutes could be an excessive time, we also tested the 10 minutes RMSSD slope (slope-10).
To compare the proposed index, the perceived effort was recorded using the Borg 1 - 10 scale [
Firstly, a descriptive study was carried out so that all the data are presented by their average values and standard deviations. The Kolmogorov-Smirnov test was used to verify the normality of the distributions. Then, the Levene Test was applied to verify equality of variances, and an ANOVA was applied using the Games-Howell procedure as the post-hoc test. The level of significance was set at p < 0.05, with a confidence level of 95%.
To analyze the relationships between the proposed slopes and other load variables, a Pearson correlation analysis was conducted. Specially, the graphical relationship between RMSSD slopes and intensities was explored.
For statistical analysis, the SPSS programme version 15.0 for Windows was used.
Slope-10 presents a Pearson correlation coefficient (r) of 0.09 for TL, −0.70 for Borg’s scale, and 0.47 for TRIMP. The r values for Slope-30 were 0.21 with TL, −0.64 with Borg’s scale, and 0.49 with TRIMP.
The Pearson correlation coefficient between Slope-10 and Slope-30 was 0.78.
The main contribution of this study is to provide a simple tool capable of evaluating internal training load based on the immediate recovery of RMSSD following any kind of exertion.
The rest RMSSD values were the same in the different sessions, corresponding to the 75th percentile for the age [
| VT1 | VT2 | MAS | ||||
|---|---|---|---|---|---|---|
| Average | SD | Average | SD | Average | SD | |
| Speed (km/h) | 10.24 | 1.44 | 13.71 | 0.89 | 16.29 | 1.1 |
| Time (h) | 0.33 | 0 | 0.22 | 0.05 | 0.11 | 0.03 |
| % VO2max | 64.39 | 7.22 | 83.11 | 7.32 | 100 | 0 |
| TL (km) | 3.44 | 0.50 | 3.44 | 0.50 | 1.75 | 0.49 |
| Borg 1-10 | 3.93 | 0.92 | 7.57 | 1.74 | 9.00 | 0.78 |
| TRIMP | 24.34 | 0.3 | 22.32 | 3.23 | 12.56 | 1.62 |
Abbreviations: VT1 (first ventilatory threshold); VT2 (second ventilatory threshold); MAS (maximal aerobic speed); VO2max: maximal oxygen uptake; TL (Trainning Load); TRIMP (Trainning Impulse); Note: warm-up (5 minutes at 9.77 ± 0.66 km/h) is not included in the VT2 data, neither the acceleration time (2 minutes at 12.22 ± 0.82 km/h) in the MAS data.
| RMSSD | |||||
|---|---|---|---|---|---|
| VT1 | VT2 | MAS | |||
| Rest | Mean | 71.24 | 71.15 | 68.48 | |
| SD | 31.22 | 21.69 | 19.65 | ||
| Exc. | Mean | 3.92 | 4.26 | 4.29 | |
| SD | 1.11 | 0.83 | 0.92 | ||
| p (rest) | 0.000 | 0.000 | 0.000 | ||
| Rec. 10 | Mean | 19.56 | 7.00 | 6.74 | |
| SD | 10.33 | 3.26 | 3.28 | ||
| p (rest) | 0.001 | 0.000 | 0.000 | ||
| p (exc) | 0.001 | 0.184 | 0.196 | ||
| Rec. 15 | Mean | 25.39 | 10.07 | 8.11 | |
| SD | 14.61 | 7.45 | 3.97 | ||
| p (rest) | 0.002 | 0.000 | 0.000 | ||
| p (exc) | 0.002 | 0.149 | 0.051 | ||
| Rec. 20 | Mean | 27.46 | 11.61 | 8.87 | |
| SD | 14.04 | 6.98 | 4.45 | ||
| p (rest) | 0.003 | 0.000 | 0.000 | ||
| p (exc) | 0.001 | 0.027 | 0.032 | ||
| Rec. 25 | Mean | 28.59 | 14.00 | 11.28 | |
| SD | 16.49 | 9.64 | 7.19 | ||
| p (rest) | 0.004 | 0.000 | 0.000 | ||
| p (exc) | 0.002 | 0.035 | 0.045 | ||
| Rec. 30 | Mean | 33.91 | 16.59 | 11.90 | |
| SD | 16.45 | 10.43 | 6.16 | ||
| p (rest) | 0.015 | 0.000 | 0.000 | ||
| p (exc) | 0.000 | 0.012 | 0.008 | ||
Abbreviations: RMSSD: Root Mean Square of the Successive Differences between adjacent RR intervals in ms.; Exc: exercise; Rec: recovery; VT1 (first ventilatory threshold); VT2 (second ventilatory threshold); MAS (maximal aerobic speed).
| Slope-30 | Slope-10 | |||||
|---|---|---|---|---|---|---|
| Min. | Avr. | Max. | Min. | Avr. | Max. | |
| VT1 | 0.44 | 1.00 | 1.56 | 0.45 | 1.51 | 2.57 |
| VT2 | 0.10 | 0.41 | 0.75 | 0.10 | 0.29 | 0.57 |
| MAS | 0.10 | 0.25 | 0.45 | 0.10 | 0.28 | 0.53 |
Abbreviations: Min. (minimum); Avr. (average); Max. (maximum); RMSSD: Root Mean Square of the Successive Differences between adjacent RR intervals in ms.; VT1 (first ventilatory threshold); VT2 (second ventilatory threshold); MAS (maximal aerobic speed).
The RMSSD reactivation following exercise behaves in a linear way, at least for the first 30 minutes, and the slope can be calculated at any point during those 30 minutes.
The RMSSD values dropped substantially regardless of the intensity and the duration of exercise to an average value of 4 ms (
Therefore, it would appear that the recovery rate of the parasympathetic system after an exercise load depends mainly on the intensity of the exercise, coinciding with Stanley [
The RMSSD recovery slope increases as the intensity of effort decreases, and vice versa. Given that RMSSD recovered faster at lower intensities, if “n” subjects who carry out the same TL undergo the almost total loss of RMSSD regardless of the load carried out [
We evaluated the slope for all 30 minutes of recovery (Slope-30) and also in the first 10 minutes (Slope-10) looking for an indicator easier to measure in a real situation following training sessions. Slope-10 and Slope-30 had a very good correlation between them and showed very similar correlations with other variables. These slopes have a very low correlation with TL (as expected in a measure of ITL) and when they were compared with other internal load indicators, it was found a moderate correlation with TRIMP, but a very good inverse correlation with Borg scale which is considered one of the best indicators of ITL.
Based on these observations we choose Slope-10 for a practical application given that 30 minutes could be a too long period to ensure the cooperation of athletes.
Given that the slopes present an exponential behavior in relation with effort intensity, we see that at very high intensities, these exponentials approach asymptote, which is close to 0.1. For this reason, 0.1 is considered the minimum value of the slopes, so that for any value less than 0.1, this value would be assigned.
Practical ApplicationsThe results of this study could be of application for monitoring individual recovery after different workloads (i.e. training sessions).
Given that the RMSSD slope has very similar characteristics along the 30 minutes period, we recommend measuring RMSSD along any period of 5 minutes during the first 30 minutes recovery, excluding the first 5 minutes [
Slope = (RMSSD-rec. - RMSSD-exc.)/t
Were RMSSD-rec is the 5 minutes value during the first 30 minutes recovery, RMSSD-exc. is the value in the last 5 minutes of exercise and t is the time elapsed from the end of exercise to the end of the HRV record. If the RMSSD was not recorded during exercise, we can calculate the RMSSD recovery slope based on the average value of 4 ms.
The main limitation of this study could be the short sample but, although the number of subjects was not very high, it is very similar to the figure included in the majority of studies on HRV. In addition, in this study the same subjects underwent 3 different experimental situations, so the “real” population was 42 subjects.
The authors declare no conflicts of interest regarding the publication of this paper.
Naranjo Orellana, J., Nieto-Jiménez, C. and Ruso-Álvarez, J.F. (2019) Recovery Slope of Heart Rate Variability as an Indicator of Internal Training Load. Health, 11, 211-221. https://doi.org/10.4236/health.2019.112019