Mauricio Garzon*,Mathiu Gayda,Anil Nigam, Alain-Stv Comtois,Martin Junau

aCardiovascular Prevention and Rehabilitation Centre(ÉPIC),Montreal Heart Institute and University of Montreal,Montreal,Quebec,H1T 1N6,Canada

bResearch Center,Montreal Heart Institute and University of Montreal,Montreal,Quebec,H1T 1C8,Canada

cDepartment of Kinesiolog y,University of Montreal,Montreal,Quebec,H3T 1J4,Canada

dDepartment of Medicine,University of Montreal,Montreal,Quebec,H3T 1J4,Canada

eKinanthropolog y Department,University of Quebec in Montreal(UQAM),Montreal,Quebec,H2X 1Y4,Canada

Immersible ergocycle prescription as a function of relative exercise intensity

Mauricio Garzona,b,c,*,Mathieu Gaydaa,b,d,Anil Nigama,b,d, Alain-Steve Comtoise,Martin Juneaua,b,d

aCardiovascular Prevention and Rehabilitation Centre(ÉPIC),Montreal Heart Institute and University of Montreal,Montreal,Quebec,H1T 1N6,Canada

bResearch Center,Montreal Heart Institute and University of Montreal,Montreal,Quebec,H1T 1C8,Canada

cDepartment of Kinesiolog y,University of Montreal,Montreal,Quebec,H3T 1J4,Canada

dDepartment of Medicine,University of Montreal,Montreal,Quebec,H3T 1J4,Canada

eKinanthropolog y Department,University of Quebec in Montreal(UQAM),Montreal,Quebec,H2X 1Y4,Canada

Purpose:The purpose of this study was to establish the relationship between various expressions of relative exercise intensity percentage of maximal oxygen uptake(%VO2max),percentage of maximal heart rate(%HRmax),%VO2reserve(%VO2R),and%HR reserve(%HRR))in order to obtain the more appropriate method for exercise intensity prescription when using an immersible ergocycle(IE)and to propose a prediction equation to estimate oxygen consumption(VO2)based on IE pedaling rate(rpm)for an individualized exercise training prescription.

Methods:Thirty-three healthy participants performed incremental exercise tests on IE and dryland ergocycle(DE)at equal external power output (Pext).Exercise on IE began at 40 rpm and was increased by 10 rpm until exhaustion.Exercise on DE began with an initial load of 25 W and increased by 25 W/min until exhaustion.VO2was measured with a portable gas analyzer(COSMED K4b2)during both incremental tests.On IE and DE,%VO2R,%HRmax,and%HRR at equal Pextdid not differ(p＞0.05).

Results:The%HRRvs.%VO2R regression for both IE and DE did not differ from the identity line%VO2R IE=0.99×HRR IE(%)+0.01 (r2=0.91,SEE=11%);%VO2R DE=0.94×HRR DE(%)+0.01(r2=0.94,SEE=8%).Similar mean values for%HRmax,%VO2R,and%HRR at equal Pextwere observed on IE and DE.Predicted VO2obtained according to rpm on IE is represented by:VO2(L/min)=0.000542×rpm2-0.026×rpm+0.739(r=0.91,SEE=0.319 L/min).

Conclusion:The%HRR–%VO2R relationship appears to be the most accurate for exercise training prescription on IE.This study offers new tools to better prescribe,control,and individualize exercise intensity on IE.

©2017 Production and hosting by Elsevier B.V.on behalf of Shanghai University of Sport.This is an open access article under the CC BY-NC-ND license(http://creativecommons.org/licenses/by-nc-nd/4.0/).

Exercise prescription;Heart rate;Immersed ergocycle;Oxygen uptake;Pedaling rate

1.Introduction

Aerobic exercise training performed atan appropriate levelof intensity has bene ficial effects on health in the general population and improves aerobic capacity and exercise performance.1Prescription of exercise intensity using measured or estimated absolute values that may include either caloric expenditure (kcal/min)orabsoluteoxygen consumption(VO2,in L/min)may result in misclassi fication of exercise intensity(e.g.,moderate,vigorous)because they do notconsiderindividualfactorssuch as body mass,sex,and fitnesslevel1orthe environmentin which the exercise is performed(i.e.,water and land).2,3

Individualized exercise training prescription is more appropriate using a relative measure of intensity and the following parameters can be used:maximal oxygen uptake(VO2max),VO2reserve(VO2R),maximal heart rate(HRmax),heart rate reserve (HRR),maximal metabolic equivalent of task(METsmax)and their relative expressions,%VOmax,%VO2R,%HRmax,%HRR, and%METsmax.1,4

Previous studies have shown con flicting results regarding the best approach to express%VO2(max or reserve)as a function of HR variables(max or reserve).Several studies have shown abetter relationship between%HRR and%VO2R in healthy adults using a treadmill or ergocycles,5,6among athletes7and obese subjects.8However,another study has demonstrated a better relationship between%VO2maxand%HRR.9The American College of Sports Medicine(ACSM)has proposed a classi fication of relative and absolute exercise intensity for aerobic exercise where%VO2R and%HRR remain interchangeable,but the ACSM emphasizes that the relationship among actual energy expenditure,HRR,VO2R,%HRmax,and%VO2maxcan vary considerably depending on exercise test protocol,exercise intensity,resting HR, fitness level,age,body composition,exercise mode(i.e.,water and land)and other factors.1

Lately,an increasing number of individuals are performing aerobic exercise training in an aquatic environment using various exercise modalities and devices.Water exercise allows participants to undergo hard workouts at intensities similar to dryland physical activities with a lower impact on joints and with different physiological responses.2,10Previous studies have concluded that the most accurate way to estimate exercise intensity in water is to use HR measurements and/or ratings of perceived exertion(RPE).3,11Giacomini et al.12studied the relationship between revolution per minute(rpm)and VO2–HR responses on 4 different models of immersible ergocycle(IE). They showed that for a similar pedaling rate(70 rpm)the %VO2maxvaried from 45%to 90%and the%HRmaxvaried from 60%to 90%,which could be explained by the difference between IE pedaling systems used in their study.Thus,various IE models may be responsible for producing different external power outputs(Pext)for a similar rpm.Currently,the pedaling cadence(rpm)on various IE models is the only main parameter to increase or decrease exercise intensity(Pext).13–16

Previous studies have shown that immersion can reduce VO2and HR during deep water running,immersed treadmill running or immersible ergocycle pedaling at maximal15,17,18and submaximal intensities(i.e.,velocity or Pext).10,19Consequently, the VO2–HR relationship(in%of max or reserve)could be modi fied during exercise on IE and be different from that of dryland ergocycle(DE).Therefore,exercise prescription using the VO2–HR relationship of DE could be less valid and accurate for IE exercise.The effects of immersion on the VO2–HR relationship during IE has not been previously studied and compared with that of DE in healthy participants.Thus,the objectives of this work were:1)to study the relationship between various expressions of relative exercise intensity (%VO2max,%VO2R,%HRmax,and%HRR)in order to obtain the more appropriate method for exercise intensity prescription when using an IE;and 2)to propose a prediction equation to estimate VO2maxbased on IE pedaling rate(rpm)for individualized exercise training prescription.

2.Materials and methods

2.1.Experimental approach to the problem

All participants performed maximal incremental exercise tests in a random order on an IE(Hydrorider Aquabike professional;Hydrorider professional aquatic equipment®,DIESSE S.R.L,Bologna,Italy)and a DE(Ergoline 800S;Ergoline GmbH,Bitz,Germany)and at similar Pextin a laboratory with air temperature maintained at 21°C and in a swimming pool at a thermoneutral exercise water temperature of 30°C.20,21During incremental exercise tests,cardiopulmonary responses were measured with a portable gas analyzer(COSMED K4b2; COSMED,Rome,Italy).Gas analyzers were calibrated before each test using a standard certi fied commercial gas preparation (O2:16%;CO2:5%).21HR was measured continuously using a HR monitor(T 61;Polar,Kempele,Finland).

2.2.Subjects

Thirty-three healthy young participants(age:33±10 years, 28 men and 5 women)were recruited at the Cardiovascular Prevention and Rehabilitation Centre of the Montreal Heart Institute.This study was approved by the Research Ethics Committee of the Montreal Heart Institute and all the subjects gave their written informed consent to participate in the study.Their baseline characteristics are presented in Table 1.Inclusion criteria were no apparent health problems and age 18 years and above. The exclusion criteria included:1)any documented cardiovascular,pulmonary,musculo-skeletal,or metabolic diseases;and 2) inability to perform a maximal cardiopulmonary exercise test.

2.3.Procedures

During data collection on both IE and DE,cardiopulmonary parameters were measured during a 3 min rest period,the exerciseperiod,and a5 min post-exerciserecovery period.Datawere averaged every 15 s for minute ventilation(VE,in L/min),body temperature,pressure,and saturation(BTPS),oxygen uptake (VO2,in L/min),standard temperature and pressure dry(STPD), and carbon dioxide production(VCO2,in L/min).Maximalexercise testson IE and DE lasted untilthe attainmentof1 ofthe 2 primary maximal criteria:(1)a plateau of VO2(＜150 mL) despite an increasein Pext(rpm orWon IEand DE,respectively), and(2)respiratory exchange ratio＞1.1;or 1 of the 3 secondary maximal criteria:(1)measured HRmaxattaining 95%of agepredicted HRmax;(2)inability to maintain the required workload; and(3)subject exhaustion with cessation caused by fatigue or subjects and/or other clinical symptoms(dyspnea)and/or ECG abnormalities that required exercise cessation.15,21

Table 1 Subjects’physical characteristics and exercise testing parameters on IE and DE.

Following the 3 min rest period,the initial exercise load for incremental test on DE was 25 W and was increased by 25 W/min until exhaustion.The pedaling rate(rpm)was at a minimum cadence of 60 rpm;however,the participants were instructed to maintain a pedaling cadence of 80 rpm since previous studies have shown that in conditions simulating those seen during prolonged competitive cycling,higher cadences (i.e.,100 rpmvs.80 rpm)are less ef ficient,resulting in greater energy expenditure and reduced peak poweroutput(327±27 Wvs.362±38 W,respectively)during maximal performance.22

The Pextincreases in water as a function of pedaling rate/velocity.16,23,24Thus,in the large number of commercially available models of IE,the only method to either increase or decrease the intensity of exercise is by varying the rpm.On the IE,the subjects were immersed up to the xiphoid process level and the exercise protocol began at a pedaling rate of 40 rpm and was increased each minute by 10 rpm until 70 rpm.Afterwards, the rpm was increased by 5 rpm until the subject was unable to follow the pace or until exhaustion.15,16Pedaling rate(rpm)was controlled with the use of both a metronome(Matrix MR500; Metronome,Seoul,Korea)and a pedaling rpm meter(Echowell F2;CATEYE Co.,Ltd.,Taichung,Taiwan,China)to help the participant to maintain correct rpm.Following the exercise test, the participants recovered for 5 min while seated on the IE or DE.The posture of each subject on both cycle ergometers was adjusted for the correct height of the saddle by sitting the participant on the bicycle,according to previous studies.13,16

The highest VO2and HR values reached during the exercise phase of each test were considered as the VO2maxand HRmax.The following values of HRR and VO2R were calculated by subtracting,respectively,the value at rest from the maximal values.7Each test on IE and DE was separated from each other by 1 week.For each subject,HR and VO2values were recorded at rest,were averaged during the last 15 s of each 1 min stage,and were expressed as percentages of their respective reserve(%VO2R and %HRR)ormaximum values(%VO2max,%HRmax,data notshown).

On the IE,the Pextwas produced by the pedaling rate that has been detailed elsewhere.13,15,17,25Brie fly,the external forces during exercise on an IE are mainly caused by the mechanical components of the pedaling system(paddles,pedals,and rods) and by leg movement drag(calf,foot,and thigh)that is dependent on the surface area of the lower limbs and the pedaling rate (rpm).

The Pextexpressed in watt(W)was calculated by multiplying the total net force(F)overcoming the resistance of the system movement(pedaling system and legs)by the tangential velocity (m/s)of the pedal.Thus,the following general fluid equation was used to determineFmathematically:

whereρis the density of water(at 30°C=995.7 kg/m3),Ais the projected frontal area(m2)in the direction of the movement for all segments involved(lower limbs,paddles,rods,and pedals),vis the velocity(m/s)ranging from 40 to 120 rpm,andCdis the drag coef ficient of shape for every element of the pedaling system and of the lower limbs.15,16

2.4.Statistical analysis

Results are presented as mean±SD.An ANOVA with repeated measures(condition×intensity)was performed to compare:(1)%VO2R and%HRR during exercise on IE and DE for the same Pextand(2)the VO2and HR responses during maximal incremental exercise test on DE or IE.Relationships between variables(%HRR and%VO2R)obtained on IE and DE were performed using linear regression analysis.The level of equivalency was evaluated with analysis of the mean slopes and intercepts(i.e.,slope=1;intercept=0)that was determined from linear regression equations.Statistical analysis was performed with Sigma Plot(Version 11.0;Sigma,San Jose,CA, USA),StatView(Version 5.0;SAS Institute Inc.,Cary,NC, USA)and SPSS(Version 15.0;SPSS,Chicago,IL,USA).The Bland and Altman analysis was performed with Excel (Microsoft,Redmond,WA,USA).

3.Results

3.1.Absolute and%VO2R

Fig.1 illustrates the absolute and relative values of VO2obtained on IE in relationship to DE.The data points represent VO2measured during the incremental test at each stage(same Pext)on IE and DE for each individual.As seen in Fig.1A,the absolute VO2(L/min)obtained on IE was systematically lower and signi ficantly correlated(r2=0.81,p＜0.0001)to the VO2(L/min)on DE.The regression equation to predictVO2(L/min) on an IE from VO2(L/min)obtained on DE is:VO2IE (L/min)=0.69×VO2DE(L/min)+130.09.Fig.1B shows a signi ficant correlation(r2=0.89,p＜0.0001)of relative VO2R (%)on IE as a function of relative VO2R(%)on DE.The regression equation obtained is VO2R IE(%)=1.01×VO2R DE(%)+0.02 and indicates that the slope is equal to 1 and that the intercept goes through 0,demonstrating that both forms of expression are equal.

Fig.1.Relationship of VO2measured on IE and DE.(A)VO2on IE relative to VO2on DE in absolute values of VO2(L/min);the filled black line represents the line of identity.(B)VO2on IE relative to VO2on DE in relative values of VO2R(VO2max-VO2rest).All data points represent all participants.The dashed line in both graphs represents the line of the regression equation.DE=dryland ergocycle;IE=immersible ergocycle;VO2=oxygen uptake;VO2max=maximal oxygen uptake;VO2rest=oxygen uptake recorded at rest.

3.2.%HRR and%VO2R

Table 2 presents%HRR and%VO2R on IE and DE for the same Pext.As well,Table 2 proposes a classi fication of RPE exercise intensity for both IE and DE.The average values of %HRR and%VO2R were not signi ficantly different for the same Pext(p=0.81 andp=0.29,respectively)during exercise on IE and DE.

Fig.2 shows the relationships between%HRR and%VO2R obtained for both IE and DE.As shown in Fig.2A and 2B, %VO2R was signi ficantly correlated to%HRR for both IE and DE(r2=0.91,p＜0.0001 andr2=0.94,p＜0.0001,respectively),and the regression equations indicated that the 2 expressions of exercise intensity(%VO2R and%HRR)were equal %VO2R IE=0.99×HRR IE(%)+0.01,SEE=11%;%VO2R DE=0.94×HRR DE(%)+0.01,SEE=8%,respectively. Fig.2C shows the signi ficant relationship(r2=0.94,p＜0.0001)between%HRR IE and%HRR DE.The regression between both variables is%HRR IE=0.97×HRR DE(%)+ 0.02.The equation slope and intercept are near equal to 1, respectively.

3.3.%HRR IE and%HRR DE level of agreement

Fig.2D is a Bland and Altman plot illustrating the level of agreement(mean=-0.02)between the%HRR IE and%HRR DE difference.The regression line(medium hash)has a slope near equal to 0(-0.08),indicating that the error in measure is nil and is constant throughout the range of 0–100%.

3.4.Estimated VO2prediction

Predicted VO2(L/min)obtained according to rpm on IE (data not shown)is represented by the following equation (r=0.91,SEE=0.319 L/min):

Table 2 Relative intensity(%HRR and%VO2R)for a same Pext(W)on IE and DE and classi fication of exercise intensity on IE(mean±SD).

Fig.2.Relationship of%VO2R with%HRR obtained with the IE and DE.(A)%VO2Rvs.%HRR obtained with IE;(B)%VO2Rvs.%HRR obtained with DE;(C) %HRR obtained on IEvs.%HRR obtained on DE;(D)level of agreement between%HRR obtained on IE and%HRR obtained on DE.All data points represent all participants.Dashed lines represent the regression equation in all graphs.%HRR=percentage of heart rate reserve;%VO2R=percentage of oxygen uptake reserve;DE=dryland ergocycle;HRR=heart rate reserve;IE=immersible ergocycle;VO2R=oxygen uptake reserve.

4.Discussion

The original findings of this study were that:1)relative intensity was found to be similar for%VO2R,%HRmax(data not shown)and%HRR at a similar Pexton IE and DE;2)on IE and DE,the%HRRvs.%VO2R relationship was the closest to the identity line and the most accurate for exercise prescription in immersion.Linear regressions obtained on IE and DE to predict %VO2R from%HRR,as shown in Fig.2A and 2B,can be considered the most accurate for exercise training prescription for either exercise modality(IE and DE).To the best of our knowledge,this is the first study to compare the HR–VO2relationship(in%of reserve values)during incremental exercise on IEvs.DE at the same Pextin healthy subjects.

We have used the method reported in previous studies using the same IE model to calculate the Pext.13,15,16This method provides a mathematical model for generalizability of calculation for IE Pextwith any IE type.The model takes into account rpm, IE pedaling system physical characteristics and lower limb size. Thus,from a performed incremental exercise test on IE,it is possible to obtain the relationship between rpm and Pextto better prescribe relative to maximal exercise intensity on any IE.Currently,the differences between commercially available IE are in the pedaling system physical characteristics(the paddle and rod length varying between brands).The method proposed herein makes it possible to calculate Pext.

In the current study,the predicted values to%HRR and %VO2R at all levels of relative intensity agreed with the most recent exercise intensity scale of the ACSM.1In addition,the relationship between%VO2R and%HRR(Fig.2)is in agreement with the ACSM recommendations for healthy young participants despite the controversy raised by other investigators that have reported higher values at 85%VO2maxor VO2R(i.e., 92%–93%HRmax).7,8,26

Other authors,however,who criticize the“traditional”concept to prescribe exercise intensity by means of a target%of HRmax,HRR,VO2max,or VO2R,have suggested that it might be more appropriate to consider,in addition,the metabolic demand of exercise by means of determining a lactate-threshold and to tailor exercise within target training zones of intensity.27,28Nonetheless,our study appears to offer a method for interchanging exercise prescription intensity for 2 different exercise devices(IE and DE)that is more accurate than the traditional%HR–%VO2maxrelationship.Thus,if the following parameters,such as the absolute VO2,HR and hemodynamic response(stroke volume,cardiac preload,cardiac output, and venous return)are affected during upright immersion exercise,14,15,19,29–31then,the rationale for using%VO2R and %HRR for IE exercise prescription appears more appropriate. Therefore,as the theory of speci ficity suggests,32,33it is important to establish the value ofVO2maxand HRmaxdirectly in water to properly prescribe the intensity on IE.

Wehave previously reported thattherelationship between Pext(W)and rpm during incremental exercise on the IE isnon-linear and could explain why VO2expressed as%VO2maxforintensities＞60 rpm increases exponentially as a function of rpm.13,16This non-linear relationship,reported by us and others,reiterates the importance of using%HRR,as proposed herein,since as shown in Fig.2A,the relationship between%VO2R and%HRR is linear.This could have practical implications since small increases in rpm generate a more rapid increase ofphysiological responses.We have included a very very lightcategory(Table 2) that corresponds to the lowest intensity on IE(≤40 rpm)and relates to the intensity recommended for warm-up.

There are some limitations in our study.This work is based on a sample of young healthy subjects;thus,our results apply only to a similar population and cannot be generalized to other groups,such as older subjects,subjects with cardiovascular risk factors or established cardiac disease.

Future studies in those populations would be necessary to see if similar results would be obtained.

Practically,however,the current study offers a new tool to better prescribe,control,and individualize exercise intensity on IE from the%HRR–%VO2R relationship.It is possible to estimate these variables using the suggested method from IE pedaling cadencies(rpm)13,16for various water immersed bicycle models with a similar pedaling systems(i.e.,Hydrorider®, Archimedes®,Poolbike®)orby directly measuring cardiopulmonary and hemodynamic responses.However,for accurate prescription in different populations as quoted above,practitioners using any IE type will have to consider the following 4 elements when calculating the power output:(1)the pedaling rate;(2)the seat height adjustment;(3)the precise characteristics of the pedaling system(length and width ofpaddles,pedals,and rods); and(4)participant leg anthropometric characteristics.16

5.Conclusion

This study offers a new tool to better prescribe,control and individualize exercise intensity on IE.The%HRR–%VO2R relationship appears to be the most accurate for exercise training prescription on IE.VO2(L/min)on IE can be obtained and predicted from the VO2measured on a DE.Similarly,VO2(L/min)obtained on IE can be predicted from IE pedaling cadencies(rpm)and is represented by:VO2(L/min)=0.000542×rpm2-0.026×rpm+ 0.739(r=0.91,SEE=0.319 L/min).Absolute cardiopulmonary responses(VO2and HR)during exercise on IE are different from that of DE,but relative intensity was found similar at a similar Pexton both IE and DE.The classi fication of exercise intensity from rpm on IE for relative intensity(%HRR and%VO2R)is in agreement with the 2011 ACSM exercise intensity scale.1

Acknowledgment

The authors wish to express extreme gratitude to Julie Lalongé,Philippe Sosner and Joffrey Drigny for technical assistance.Funding was provided by the ÉPIC Foundation and the Montreal Heart Institute Foundation.

Authors’contributions

MGarzon conceived of the study,carried out the experiments,participated in the analysis and drafted the manuscript;MGayda participated in the coordination and drafted the manuscript;AN helped to draft the manuscript;ASC conceived of the study,participated in the analysis,and drafted and revised the manuscript;MJ helped to draft the manuscript.All authors have read and approved the final version of the manuscript,and agree with the order of presentation of the authors.

Competing interests

That authors declare that they have no competing interests.

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24 October 2014;revised 9 May 2015;accepted 27 July 2015

Available online 14 December 2015

Peer review under responsibility of Shanghai University of Sport.

*Corresponding author.

E-mail addresses:mauricio.garzon.1@umontreal.ca;mauriciogrzn@ gmail.com(M.Garzon).

http://dx.doi.org/10.1016/j.jshs.2015.12.004

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