by Andrew Flatt MS, CSCS
After purchasing my ithlete to monitor heart rate variability (HRV) well over a year ago I was unsure of whether to take measurements laying down (supine) or standing up. I don’t recall what it was exactly that prompted my decision, but I decided to measure standing. Since day one I’ve recorded my HRV in the exact same position (standing) after waking up for consistency. I often wonder however if this is the best way of measuring HRV for the purpose of monitoring training load and recovery status. Please understand that this article is simply my perspective on the topic based on my experience and research into the matter. Furthermore, I’ve yet to see this discussed in too much depth and therefore decided to investigate the issue myself.
In this discussion I wish to accomplish 3 objectives;
- Briefly discuss the role of the autonomic nervous system (ANS) in controlling heart rate at rest and in response to orthostasis (standing up)
- To briefly review some of the research I have read pertaining to this issue
- To present and discuss some data I collected over a two week period comparing my morning supine resting heart rate (RHR) and HRV score vs. my morning standing RHR and HRV score.
Heart Rate Mediated by ANS
Within the wall of the right atrium of the heart is the sino-atrial node (SA node). The SA node randomly initiates impulses that cause the heart to beat. The cardiovascular center of the autonomic nervous system located in the brainstem governs the SA node via parasympathetic and sympathetic innervation. More specifically, the cardiac accelerating center (sympathetic) and cardiac decelerating centers (parasympathetic) of the medulla are responsible for sending sympathetic and parasympathetic impulses to the heart in response to altered blood distribution and pressure requirements (exercise, stress, standing, laying down, etc.)
Sympathetic impulses increase heart rate by exciting the SA node while parasympathetic impulses reduce heart rate by inhibiting it. Thus, with parasympathetic predominance we can expect heart rate to be less frequent and less consistent (more variability between beats) while sympathetic predominance would result in more beats with less variability.
During supine rest, heart rate and blood pressure are lower as the body is in a relaxed state. From supine (a state of high parasympathetic activity and low sympathetic activity) to standing, there is a shift in sympathovagal balance characterised by a withdrawal of parasympathetic activity and a concomitant increase in sympathetic activity (Montano et al. 1994, Mourot et al. 2004). Naturally, the body needs to accommodate for postural change forcing the heart to beat harder and faster to pump blood to the brain; a task much less strenuous in the horizontal position.
Some Pertinent Research
Kiviniemi et al. (2007) provides a very through explanation of why HRV might be better measured in a standing position as opposed to seated or standing. Essentially, HRV is susceptible to saturation of the parasympathetic nervous system in subjects with low heart rates. Therefore, in athletic populations, changes in parasympathetic activity may be harder to detect. The authors state “In the present study, endurance training increased HF power measured at standing position but did not change HF power measured at sitting position. This supports our notions that orthostatic stimulus may be more favorable condition than sitting or supine positions to obtain specific information on the status of cardiac autonomic regulation in exercise intervention settings among relatively high fit subjects.”
Mourout et al (2004) saw decreased HRV in overtrained athletes compared to not overtrained athletes in the supine position. Similar results were found when HRV was measured after 60 degree tilt. The non-OT group always had higher HRV in the standing position and saw greater reactivity to the postural change.
Uusitalo et al (1999) saw similar results to the work mentioned above by Mourot. Overtrained athletes saw an increase in LF power in the supine position; lower HRV in the standing position; and decreased reactivity to postural change. Additionally, changes in maximal aerobic power were related to decreased HRV in the standing position.
Gilder and Ramsbottom (2008) wanted to test whether volume of training load resulted in changes in HRV in response to orthostasis. The authors findings in their words; “Women reporting higher volumes of physical activity had significantly higher levels of parasympathetic HRV than less active women while supine, but also demonstrated a much greater change in parasympathetic HRV in response to standing. It is of interest to note that short-term vagal measures of HRV for HV while standing are similar to those for LV while supine.” *LV=Low Volume HV=High Volume
Grant et al. (2009) found that standing HRV indicators showed significantly more correlations with cardiopulmonary fitness indicators compared to supine measurements. The authors did however urge practitioners to use caution when attempting to measure fitness via HRV.
Hedelin et al. (2001) found that during a 70 degree head up tilt, LF power correlated to measures of strength and aerobic capacity. A greater shift toward LF power in the tilted position correlated to reduced performance. Changes in LF were linearly related to changes in performance suggesting a reflection of adaptation to training.
Hellard et al. (2011) measured HRV in swimmers to model a relationship between HRV and illness. The main results of this study were the following:
“1) In winter, national-level swimmers showed a greater risk of pathology than international-level swimmers. 2) The weeks that preceded the appearance of URTI and pulmonary infection but also MA were characterized by an increase in autonomic parasympathetic activity in supine position. Conversely, in orthostatic position and in winter, the weeks that preceded the appearance of AP were characterized by a drop in parasympathetic activity. 3) During weeks characterized by URTI and pulmonary infection, a shift was noted in the autonomic balance toward sympathetic predominance in supine position and a drop in parasympathetic drive in orthostatic position. And 4) in winter and in orthostatic position, a drop in parasympathetic drive associated with an increase in sympathetic drive was linked to an increased risk of MA.” MA= Muscular Injury, AP=All type pathologies, URTI=Upper Respiratory Tract Infection
Huovinen et al. (2009) measured HRV and Testosterone-Cortsiol ratios in army recruits during a week of basic training (class room based). The authors stated; “In the present study, the correlation between the
testosterone-to-cortisol ratio and changes in heart rate, SDNN, and high-frequency power expressing an association between circulating ‘‘stress’’ hormones and cardiac vagal activity was apparent in the standing condition only. Thus, based on the results of the present study, measures of heart rate variability should be done not only at rest but also during a controlled sympathetic stimulation (e.g. during an orthostatic challenge).”
I will add that there is plenty of research that has demonstrated a detection of overtraining in athletes from measuring HRV in the supine position. The focus of this article however is on standing measurements.
I summarize my thoughts and conclusions on the research at the end of this article.
My Experiment: HRV Supine vs. Standing
Protocol:
- Wake up and go pee
- Return to bed and record HRV once HR stabilized from postural change
- Stand up and record HRV once HR stabilized from postural change
sRPE is my rating of perceived exertion of my workout from that day. Workouts rated as 8 or above were higher in volume and intensity while workouts rated as 7 were lower volume and intensity. A score of 5 or below represent active recovery work. Therefore it is the following day that will reflect quality of recovery. Keep in mind that workouts rated as 5 or above were resistance training based while workouts rated below 5 were more aerobic in nature to facilitate recovery.
| Date | Supine HR/HRV | Standing HR/HRV | HRV Difference | sRPE |
| 8/10 | 52 / 87 | 56 / 85 | 2 | 8 |
| 8/11 | 51 / 89.5 | 65 / 80.5 | 9.5 | 1 |
| 8/12 | 48.5 / 94.5 | 67 / 84.5 | 10 | 5 |
| 8/13 | 49.5 / 88 | 66 / 78.5 | 9.5 | 7 |
| 8/14 | 50 / 88 | 67 / 79 | 9 | 3 |
| 8/15 | 49 / 90 | 61 / 86 | 4 | 8 |
| 8/16 | 48 / 92 | 71 / 79 | 13 | 3 |
| 8/17 | 53 / 92 | 69.5 / 80 | 12 | 8 |
| 8/18 | 51 / 101 | 78 / 73 | 28 | 3 |
| 8/19 | 50 / 85.5 | 63 / 79 | 6.5 | 0 |
| 8/20 | 49.5 / 81.5 | 60.5 / 74.5 | 7 | 0 |
| 8/21 | 47 / 90 | 58 / 86 | 4 | 8 |
| 8/22 | 52 / 90 | 75 / 70 | 20 | 3 |
| 8/23 | 50 / 83 | 65.5 / 84 | 1 | 8 |
| 8/24 | 49.5 / 87 | 60.5 / 85.5 | 1.5 | 8 |
I have highlighted four instances that showed conflicting scores. On all four occasions supine HRV is high while standing HRV is low. Each of these conflicting scores occurred on days following a higher intensity workout. Based on my trends and perception of stress I find that the standing scores to be a more accurate reflection of my training load. Generally after an intense workout I’m sore the next morning and fatigued from the workout.When reviewing my overall trends (not just these two weeks) usually HR goes up and HRV decreases in response to a high loading day (sRPE 8+). Likewise, HR will decrease and HRV will increase in response to a lower loading day. However, I’ve found this to be subject to change based on sleep quality and other lifestyle factors that can promote a change in HRV.
Non-training related stressors are not documented. This is a huge limitation as various forms of stress (mental, physical, chemical) can affect HRV.
Thoughts and Wrap Up
First and foremost, consistent measurements are more important than position. This is because each position appears to provide important data regarding training status. Therefore, pick a position and stick to it 100% of the time for your values to be meaningful. Switching positions from day to day will provide skewed data and affect daily ithlete colour indications.
In my opinion, endurance athletes and individuals with low resting heart rates are probably better off measuring HRV in a standing position to avoid the potential affect of “parasympathetic saturation”. A colleague pointed out an important point after I ran this experiment; a standing HRV measurement will produce a larger sample size of R-R intervals which decreases margin for error.
Nearly every paper I’ve read on HRV stresses that HRV varies a great deal between individuals. This means that you should not be comparing your data to others. In a team setting, it is important to always compare daily values to baseline (of each individual) for meaningful interpretations. A score of 80 may be high for one individual and low for another.
I like the standing test for the simple reason that it provokes a small stress response. This removes the issues of parasympathetic saturation from the supine position. Seeing how your body responds to standing appears to give you a good idea of how your body can/will handle stress that day. If HRV remains high after standing (given time to stabilize) then you are likely in an adaptive state. If HRV is low after standing (given time to stabilize) you are likely less adaptive (currently under higher stress).
HRV test length may influence positional preference. The ithlete measurement is a 1 minute test and therefore I don’t find the standing position to be a nuisance. However, I did prefer the supine measurements simply because I only needed to focus on breathing and nothing else. When measuring HRV with devices of longer duration I preferred the supine or seated position.
Ultimately, you should experiment for yourself to determine positional measurement preference. Try recording data in both positions, compare it to perceived stress (training, mental, chemical, etc) and determine what method you like best.
References
Author Profile
Andrew Flatt currently resides in Toronto, Ontario, Canada. He holds a Master’s Degree in Exercise Science with an interest pertaining to HRV and its application to monitoring training status in athletes. Andrew is a competitive powerlifter and former collegiate football player.
For more information about Andrew, visit his blog hrvtraining.com, read his ithlete case study or follow on twitter @andrew_flatt
Great write up thanks! I really like your not comparing scores. Is there any data that shows an athlete actually performs better over time if their HRV improves over time?
Thanks Steve.
Off the top of my head I can’t recall anything that specifically looked at long term HRV changes with performance, but that doesn’t mean it doesn’t exist. Rather, how one performs or adapts to training based on HRV score has been studied.
The following may be of interest to you;
Hedelin et al (2001): “High-frequency and total HRV did not change in proportion with changes in muscle performance or aerobic capacity, but the ability to further improve VO2,na, with training in these already fit subjects seemed to depend on their average levels of these HRV measures, interpreted to reflect parasympathetic activity.”
Kiviniemi et al (2010) compared HRV guided aerobic training vs Pre-planned aerobic training. The results showed that men in the HRV group had greater maximum velocity than the pre planned group consistent with Kiviniemi et al (2007) results. The HRV female group saw no significant increase in maximum velocity over the pre planned group however the HRV female group was able to improve their fitness to the same levels of the pre planned group with a lower weekly training load (fewer high intensity training days).
Cipryan et al (2007) showed that male hockey players have higher rated performances from their coach when HRV is high while any drops in HRV correspond with a lower rating of performance. Of the sample players, the one with consistently low HRV was rated the lowest in performance.
In my experience HRV baseline will improve to a certain point in response to improved fitness. This improved fitness will obviously result in improved performance in most sports. However after this point it appears to be more about daily HRV changes and manipulating training accordingly. Strategically increasing loads when HRV scores are high and reducing loads when HRV is low.
Competition day HRV scores should be interpreted with caution as athletes will likely be experiencing some form of arousal/anxiety. A recent study by Edmunds et al (2012) demonstrates this well;
“Prior to a competitive game, elite youth, Rugby League players exhibited a significant reduction in HRV that was sustained for at least 24 hours post-game. This withdrawal of parasympathetic and/or increased sympathetic control of HR possibly may result from pre-match anxiety as well as the physical demands of the game. Strong relationships between HRV and training load at Pre-2 indicate that early monitoring may assist in identifying training workloads for the upcoming week. The current results support HRV as an important monitoring tool for managing training workload.”
I may have digressed a little here. I hope that somewhat helped.
-Andrew
Maybe I can help a little here. Martin Buchheit and his research team did a study on runners training for a 10km race in 2009.
From the abstract of the paper ‘In 14 moderately trained runners (36 ± 7 years), resting vagal-related HR variability (HRV) indices were measured daily, while exercise HR and post-exercise HR recovery (HRR) and HRV indices were measured fortnightly. Maximal aerobic speed (MAS) and 10 km running performance were assessed before and after the training intervention. Correlations (r [ 0.60, P < 0.01) were
observed between changes in vagal-related indices and changes in MAS and 10 km running time. Exercise HR decreased progressively during the training period (P 0.5% (responders), resting vagal-related indices showed a progressively increasing trend (time effect P = 0.03) and qualitative indications of possibly and likely higher values during week 7 [?7% (90% CI -3.7;17.0)] and week 9 [?10% (90% CI -1.5;23)] compared with pre-training values, respectively.
So in summary, what they found was that in every case where the training program produced improved running speed in the 10km, their HRV (LnRMSSD) also increased. They also found some runners who did not improve their performance (non-responders) showed no significant improvement in HRV.
Powerful stuff – the paper reference is at : Eur J Appl Physiol DOI 10.1007/s00421-009-1317-x
Great stuff guys! It makes sense to me. A person who trains to HRV optimizes their training plan and hence can race faster that without. So what would a low reading be for a person? When I started HRV collection quite a few months ago my base line was like 65 now it’s looking like it’s going to be in the low 80s. Would it take a dip back down to the 60’s to say slow down or rest day or any significant drop off of base line which I suspect would show up as an orange or red ball?
Next, now that I recently turned 55 (I never actually thought this would actually happen to me) is there any data regarding HRV and heart disease? I know I’m good to go in that department but I’m a geek and so curious. What about HRV and longevity?
There is indeed lots of interesting research on HRV and heart disease – in fact one of the first clinical uses of HRV was to screen heart attack victims in ER to evaluate their prognosis – the lower their HRV, the poorer the chances they would make it through the next few days.
HRV and longevity is a subject I find fascinating and rather than try to cover it here will do a blog post in the near future.
Simon, I took up triathlon 2 years ago, 12 months ago I retired and became (by default) a fulltime triathlete. This August I completed my first Ironman at age 67.
I’ve just started using ithlete, having stumbled over HRV when I was looking for a tool that would help me know when I was sufficiently recovered to train.
I’m looking forward to reading your blog post on HRV and longevity.
Congrats on your first IM Winston! I think monitoring your recovery with ithlete will help you train more effectively. Please do use the subjective sliders & record comments for the all-important context that will allow you to associate lifestyle with recovery.
Hey Steve, interesting stuff. Ive used the iThlete for two month now and in supine position my hrv only varies +-5 max, so maybe in my case it would be more reliable standing? I have one further question though, what if you have a positive tilt test indicating orthostatic intolerance, can i still use the hrv from standing? my hr will be high even on a good day, but even higher on a bad day.
Hi Andrew, great article and thanks for the quoted studies. What’s your take on the use of orthostatic HR change I.e HR supine to HR standing versus HRV standing as usable measures?
Is there any reason to use one and not the other ?
Thanks, Paul.
I haven’t collected enough data using the supine to standing method with calculated change scores (i.e., Rusko Test) to have a strong opinion. I think that the extra time to acquire both positional measurements would limit its practical implementation due to the added time.
Thanks Andrew. If I can add my 2c worth, this was one of the articles I came across whilst researching ithlete in 2009 http://www.ilog.ca/help/Rusko_Heart_Rate_Test.htm
You will see that all the interesting variation with training state happens in the standing position, and together with research by Kiviniemi and others on parasympathetic saturation, convinced me that standing was probably going to the best single position for day to day HRV monitoring. I haven’t changed my mind since, but suspect that it is the torso being upright which is important, so sitting is probably a very good second best in people with all but the lowest resting HR values.
Hello, how to delete old reading taking in Supine position?
Hi Riccardo. You can do two things:
1) Delete individual readings by tapping them on the dashboard, followed by the trash symbol at top right
2) Delete the app altogether and start a new set of readings
Hope this helps!
how soon after getting out of bed do you take the standing measurement?
Hi Lindsay,
We recommend taking the reading right after waking. Have a moment to wake properly, use the bathroom if needed, then take the ithlete measurement. it is certainly important to do so before eating or drinking.