© 2019 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses, in any current or future media, including reprinting /republishing this material for advertising or promotional purposes, creating new collective works, for resale or redistribution to servers or lists, or reuse of any copyrighted component of this work in other worksIn this paper, a non-linear HRV analysis was performed to assess fragmentation signatures observed in heartbeat time series after intermittent hypoxia (IH). Three markers quantifying short-term fragmentation levels, PIP, IALS and PSS, were evaluated on R-R interval series obtained in a rat model of recurrent apnea. Through airway obstructions, apnea episodes were periodically simulated in six anesthetized Sprague-Dawley rats. The number of apnea events per hour (AHI index) was varied during the first half of the experiment while apnea episodes lasted 15 s. For the second part, apnea episodes lasted 5, 10 or 15 s, but the AHI index was fixed. Recurrent apnea was repeated for 15-min time intervals in all cases, alternating with basal periods of the same duration. The fragmentation markers were evaluated in segments of 5 minutes, selected at the beginning and end of the experiment. The impact of the heart and breathing rates (HR and BR, respectively) on the parameter estimates was also investigated. The results obtained show a significant increase (from 5 to 10%, p  0.9) between these markers and BR, as well as with the ratio given by HR/BR. Although fragmentation may be impacted by IH, we found that it is highly dependent on HR and BR values and thus, they should be considered during its calculation or used to normalize the fragmentation estimatesPeer ReviewedPostprint (published version

Jané Campos, Raimon

Romero, Daniel

English

UPCommons (Universitat Politècnica de Catalunya)

Non-linear HRV Analysis to Quantify the Effects of IntermittentHypoxia Using an OSA Rat ModelDaniel Romero1 and Raimon Jané1,2 Senior Member, IEEEAbstract— In this paper, a non-linear HRV analysis was per-formed to assess fragmentation signatures observed in heartbeattime series after intermittent hypoxia (IH). Three markersquantifying short-term fragmentation levels, PIP , IALS andPSS, were evaluated on R-R interval series obtained in arat model of recurrent apnea. Through airway obstructions,apnea episodes were periodically simulated in six anesthetizedSprague-Dawley rats. The number of apnea events per hour(AHI index) was varied during the first half of the experimentwhile apnea episodes lasted 15 s. For the second part, apneaepisodes lasted 5, 10 or 15 s, but the AHI index was fixed.Recurrent apnea was repeated for 15-min time intervals inall cases, alternating with basal periods of the same duration.The fragmentation markers were evaluated in segments of 5minutes, selected at the beginning and end of the experiment.The impact of the heart and breathing rates (HR and BR,respectively) on the parameter estimates was also investigated.The results obtained show a significant increase (from 5 to10%, p <0.05) in fragmentation measures of heartbeat timeseries after IH, indicating a clear deterioration of the initialconditions. Moreover, there was a strong linear relationship(r > 0.9) between these markers and BR, as well as withthe ratio given by HR/BR. Although fragmentation may beimpacted by IH, we found that it is highly dependent on HRand BR values and thus, they should be considered during itscalculation or used to normalize the fragmentation estimates.I. INTRODUCTIONObstructive sleep apnea (OSA) is a chronic health con-dition characterized by repeated episodes of apnea dur-ing sleep, resulting in sustained exposure to intermittenthypoxia (IH). This chronic condition has been linked tosome cardiovascular consequences of OSA, such as systemichypertension, myocardial infarction and stroke [1], [2], [3].To date, the underlying mechanisms linking IH to vasculardiseases in OSA are unclear. However, it has been reportedthat an elevated sympathetic tone of the autonomic nervoussystem (ANS) [4], oxidative stress and endothelial dys-function [2], inflammation and atherosclerosis [3] somehowcontribute to this matter.*This work supported in part by CERCA Program, Secretaria dUniver-sitats i Recerca del Departament dEmpresa i Coneixement de la Gener-alitat de Catalunya (GRC 2017 SGR 01770) and the Spanish Ministry ofEconomy and Competitiveness (DPI2015-68820-R MINECO/FEDER). D.R.acknowledges the financial support of the Juan de la Cierva fellowship fromMINECO, Ref: IJCI-2016-30696.1Daniel Romero is with the BIOSPIN group at the Institute for Bioengi-neering of Catalonia (IBEC), the Barcelona Institute of Science and Tech-nology (BIST), Barcelona, Spain. dromero@ibecbarcelona.eu2R. Jané is with the Institute for Bioengineering of Catalonia(IBEC), the Barcelona Institute of Science and Technology (BIST), Cen-tro de Investigación Biomédica en Red de Bioingenierı́a, Biomateri-ales y Nanomedicina (CIBER-BBN) and ESAII Department, Universi-tat Politècnica de Catalunya - BarcelonaTech (UPC), Barcelona, Spain.rjane@ibecbarcelona.euMany research studies in OSA have developed experimen-tal and human models of acute/chronic IH to figure out theassociation between OSA and cardiovascular diseases. Forinstance, in animal studies, the rat models represent oneof the most common experiments used for understandingand studying physiological mechanisms involved in sleepapnea. However, rats are usually anesthetized, which canaffect cardiovascular functions and the control handled by theautonomic nervous system (ANS) could be partially blocked.Although the dose, type and method used for anestheticsadministration can disturb in different ways this controlsystem in rats [6], a recent study reported increased sym-pathetic nerve activity, sympathetic peripheral chemoreflexsensitivity and central sympathetic respiratory coupling afterIH in anesthetized rats [7].To study the induced-hypoxia effects caused by OSA,a rat model of chronic recurrent airway obstructions wasdeveloped [8], [9]. This model was completed [10] with anexternal control varying the duration and frequency of theinduced apneas. Different sensors were included in order toacquire cardiac and respiratory activity, such as flow andpressure transducers, electrodes and a specific pulse oximeterfor rat monitoring.This study aims at characterizing the effects of intermittenthypoxia after completion of several recurrent apnea episodes.Modifications in the ANS activity after OSA episodes wereevaluated by means of fragmentation signatures observed inheartbeat time series, analyzed during the start and end ofthe experiment.II. MATERIALS AND METHODSA. Experimental dataSix male Sprague-Dawley rats (mean weight: 437±27 g)were intraperitoneally anesthetized with uretane (1g/1kg).The rats were connected to a system that incorporatesa controlled nasal mask, including one tube open to theatmosphere and another connected to a positive pressurepump, preventing the animal from rebreathing. OSA episodeswere simulated by obstructing the airways in the tubesusing electrovalves. The electrovalves were controlled bysoftware using the Biopacr Systems. The electrodes, nasalmask and SpO2 sensor were placed on the animals afteranesthesia and shaving (Fig 1). The experimental procedureinvolving the animal model described here was approved bythe Institutional Animal Care and Ethics Committee.Several signals were acquired during spontaneous breath-ing and simulated OSA episodes. Respiratory flow signal,respiratory pressure and electrocardiogram (ECG) signal(leads I and II) were registered by Biopacr Systems. Pho-toplesthysmography signal and SpO2 were measured by apulse oximeter (Mouse OxPlusr) positioned in the rat leg.+GroundBiopacECGBiopacoutMouseOxPlusSpO2, PPGElectrovalvesControlSystemEVEVPositivepressurepumpairPVFig. 1. Experimental setup for the OSA model, using two electrovalves(EV) and a positive pressure pump. Signal acquired: respiratory flow (V’)and pressure (P), SpO2 and PPG (MouseOx Plus r) and ECG ( Biopacr).B. Experimental ProtocolTwo different protocols were set for the experiment. Inboth of them, recurrent apnea episodes were induced for15-min intervals followed by 15-min resting periods. Apneaindex (AI) of 20, 40 and 60 apneas/hour were applied inthe first protocol with apnea episodes duration of 15 s (Fig.2-a). In the second protocol (Fig. 2-b), AI was fixed to 60and the apnea episodes lasted either 5, 10 or 15 s. In bothconfigurations, the order of the 15-min intervals of recurrentapnea was randomly selected. Desaturation levels, assessedfrom SpO2 signals, ranged between 5–23% with respect tothe pre-apnea values. For this study, only the initial and finalbasal intervals (end of the second protocol) were consideredto evaluate heart rate fragmentation before and after apneaepisodes, to assess the cumulative effect of IH.C. ECG PreprocessingECG signals, sampled at 1250 Hz, were preprocessedbefore the automatic extraction of the evaluated marker,including automatic QRS complex detection [11] and visualinspection to remove abnormal beats, baseline drift attenua-tion, 4-th order bidirectional Butterworth low-pass filtering at45 Hz to remove power line interference and high frequencynoise.D. Non-linear HRV analysisAfter QRS complexes detection, the time positions ofconsecutive R-wave peaks were determined and used to buildthe RR interval series in all rats as follows:RR[i] = R[i+ 1]−R[i]; i = 1, ...N − 1 (1)where i and N represent the i-th beat and the total numberof beats of the analyzed segment.a)b)Fig. 2. a) Protocol 1: Sequences of 15-s apnea episodes used during 15-minrecurrent apnea intervals, preceded and followed by resting periods of 15minutes (Bas #), applied for each rat. b) Protocol 2: Sequences of recurrentapnea episodes (with AI=60) for 15-min intervals, preceded and followedby resting resting period of 15 minutes (Bas #).To assess the level of fragmentation present in RR intervalseries, a set of recently proposed markers were evaluated onnormal-to-normal (NN) interval series, obtained by consid-ering only normal sinus heartbeats [5]. Abnormal intervalswere replaced by the average of the previous 5 intervals. Thefragmentation indices are the following:• PIP: The percentage of inflection points in the NN timeseries, that is, the number of zero-crossing points in thefirst derivative of the NN series referred to their totallengths.• IALS: The inverse average length of accelera-tion/deceleration segments. Acceleration/decelerationsegments represent consecutive NN intervals betweenadjacent inflection points, where the difference between2 consecutive NN intervals is negative or positive,respectively.• PSS: The percentage of NN intervals that are in shortsegments. Short segments are defined as those accel-eration or deceleration segments that lasted ≥ 3 NNintervals.According to the definition of fragmentation, the aboveindices will be higher if a time series is more fragmented.Importantly, removing the presence of non-sinus heartbeatsfrom the annotation step is crucial because it can increasefragmentation in the analyzed time series [5]. Nevertheless,since these parameters can be highly influenced by boththe respiratory rate (BR) and heart rate (HR), we alsoinvestigated their relationships during the experiment.E. Statistical analysisResults obtained are expressed in mean ± SD. TheWilcoxon signed rank nonparametric test was applied tocompare paired observations obtained at different stages ofthe experiment. The relationships of the parameters withHR and BR was determine using the Pearson’s correlationcoefficient. The significance level was set to 0.05 in all cases.III. RESULTSThe Fig. 3 shows an example of two NN segments (initialand final), analyzed in one rat of the study population. Itcan be observed that the initial segment is more regularthan the final one. Moreover, the HR is quite different inboth segments, being higher (> 20%) during the initialstage. Respiratory rate (BR) is slightly lower (∼17%) andthe number of inflections points (IP) is smaller at the end,however, the PIP value is higher. This suggests that somekind of relationship may exist between fragmentation andHR, BR, or a combination of both.0 10 20 30 40 50 60 70 80 90146148150152154156RR [ms]Beginning: HR=399 beats/min; RR=65 cycles/min; PIP= 30 % IP= 1870 10 20 30 40 50 60 70 80 90192194196198200202RR [ms]Ending: HR= 305 beats/min; RR=54 cycles/min; PIP= 35 % IP= 166Time [s]Fig. 3. NN time series representing 90-s segments during the initial andfinal stage of the experiment. Red points indicate inflection points detectedon the NN series. Heart rate, respiratory rate, PIP value and the number ofIP are displayed in the top of each graph.Table 1 summarizes the results obtained for all markersand rats before and after IH. It can be observed that boththe HR and HR/BR significantly decreased by the end of theexperiment while the PIP and PSS markers were significantlyhigher, indicating an increase in fragmentation of the timeseries analyzed. The p-values obtained show that only BRdid not change significantly between both time periods.In Fig. 4 are plotted the PIP values against the HR, BRand the ratio HR/BR for each animal, evaluated during theinitial and final stages. The straight lines represent the modelobtained after fitting a linear function to all data. From thefigure, we can observe that BR and the HR/BR ratio have astrong linear relationship with the PIP values when the ex-periment started. However, in the case of HR, some animalswith similar values (see Fig. 4-(a)) present very differentfragmentation measures in the same period, meaning that BRTABLE IMEAN ± SD OF THE NON-LINEAR HRV PARAMETERS, HEART RATEAND RESPIRATORY RATE.Parameters Before IH After IH p-valueHR (beats/min) 385 ± 26 350 ± 29 0.0156BR (cycles/min) 92 ± 18 90 ± 19 0.2813HR/BR (beats/cycles) 4.3 ± 1.0 4.0 ± 0.8 0.0469PIP (%) 46.5 ± 7.8 50.3± 5.5 0.0313PSS (%) 64.7 ± 27.0 74.8 ± 24.1 0.0469IALS (%) 0.46 ± 0.08 0.51 ± 0.05 0.0313seems to have a stronger impact on fragmentation estimatesas compared to HR.30 35 40 45 50 55280300320340360380400420HR [beats/min]R= −0.06967730 35 40 45 50 555060708090100110120RR [cycles/min]R= 0.9460230 35 40 45 50 5534567HR/RRPIP (%)R= −0.9893540 45 50 55 60280300320340360380400420HR [beats/min]R= 0.7930640 45 50 55 605060708090100110120RR [cycles/min]R= 0.9330140 45 50 55 6034567HR/RRPIP (%)R= −0.93911Fig. 4. PIP values vs HR, RR and HR/RR ratio obtained for all animalsbefore (left column) and after (right column) the IH. R stands for Pearson’scorrelation coefficient.The same analysis was performed after completion of therecurrent apnea episodes to assess their effects. Results aredisplayed in the right column of Fig. 4. In most rats, HR andBR decreased with respect to the initial values, confirmingthe results of Table I. The HR/BR ratio was also lower at thefinal stage, keeping in some extent their linear relationshipwith the fragmentation values. The major difference wasobserved in the analysis of HR vs PIP, where the linearmodel fitted better to the actual data as compared to theinitial ones. Similar results were also obtained for the PSSand IALS markers, which are summarized in Table II.In addition to the actual values, the changes developedduring the experiment by the analyzed markers were alsoinvestigated. Fig. 5 presents the correlation values obtainedwhen analyzing the changes seen in fragmentation markersvs those changes occurred in HR, BR an their ratio. In-10 -5 0020406080100HR (beats/min)R= -0.51008-20 -10 0020406080100R= -0.60093-0.1 -0.05 0020406080100R= -0.58267-10 -5 0-10-5051015BR (cycles/min)R= 0.19485-20 -10 0-10-5051015R= -0.096647-0.1 -0.05 0-10-5051015R= 0.13521-10 -5 0PIP (%)-0.200.20.40.60.8HR/BRR= -0.86249-20 -10 0PSS (%)-0.200.20.40.60.8R= -0.64171-0.1 -0.05 0IALS-0.200.20.40.60.8R= -0.90239Fig. 5. Correlation values obtained between changes observed in fragmen-tation markers and in heart rate, respiratory rates and their ratio.this analysis, only HR/BR seems to have a stronger linearrelationship with all of them.TABLE IICORRELATION VALUES OBTAINED BETWEEN FRAGMENTATIONMARKERS AND THE HEART AND RESPIRATORY RATES.HR BR HR/BRParameters Before | After Before | After Before | AfterPIP (%) -0.07 | 0.79 0.95 | 0.93 -0.99 | -0.94PSS (%) -0.07 | 0.72 0.94 | 0.85 -0.97 | -0.85IALS (%) -0.07 | 0.79 0.95 | 0.93 -0.99 | -0.93IV. DISCUSSION AND CONCLUSIONSIn this study, we evaluated the level of fragmentationobserved in heartbeat time series and how they are affectedby intermittent hypoxia. To performed this analysis, weevaluated three fragmentation indices on RR interval timeseries, extracted from the initial and final periods of an OSAmodel in rats. The results obtained shown that the level offragmentation significantly increased (between 5% and 10%,p < 0.05) after completion of several sequences of recurrentapnea episodes, which caused intermittent hypoxia duringthe whole experiment.A important finding of the study is related to the fact thatboth the respiratory rate and its relationship to heart rate arehighly correlated with fragmentation parameters (|R| > 0.9).Comparable results were also obtained when HR/BR changeswere correlated with these parameters. This finding suggeststhat these variables could be used to obtain indirect measuresof fragmentation levels, or at least should be consideredduring their calculation.Costa et al. [5] reported that fragmentation of heartbeattime series increases with aging in healthy subjects as wellas in patients with heart diseases such as coronary arterydisease (CAD). However, fragmentation tends to be higherin patients with CAD than in healthy subjects of similar ages.They also showed that fragmentation seems not to be affectedby the mean heart rate, however, our study showed a highcorrelation with respiratory rate and the ratio between HRand BR, even under different conditions. Nevertheless, ourresults should be interpreted with caution due to the smallsize of the population.It is known that intermittent hypoxia caused by obstructivesleep apnea may contribute to impaired autonomic cardiacfunction. These alterations are mainly driven by the sympa-thetic activation and may represent mechanisms for increasedoccurrence of cardiac arrhythmias in OSA patients. Weconcluded that the investigated parameters could be useful toassess how much the HRV is affected after recurrent hypoxiaepisodes, and they should be analyzed and compared to othertraditional HRV markers to determine their added value inpatients with OSA.ACKNOWLEDGMENTThe authors are grateful to Ramon Farré, Daniel Navajas,Josep Maria Montserrat, Isaac Almendros, Marta Torresand Puy Ruiz for their excellent help in designing andimplementing the animal model.REFERENCES[1] N.R. Prabhakar. Invited Review: Oxygen sensing during intermittenthypoxia: cellular and molecular mechanisms. J Appl Physiol, vol. 90,pp. 1986-1994, 2001.[2] L. Lavie. Obstructive sleep apnoea syndrome - an oxidative stressdisorder. Sleep Med Rev, vol. 7, pp. 35-51, 2003.[3] L. Lavie. Sleep-disordered breathing and cerebrovascular disease: amechanistic approach. Neurol Clin, vol. 23, pp. 1059–1075, 2005.[4] E.C. Fletcher. Invited review: Physiological consequences of intermit-tent hypoxia: systemic blood pressure. J Appl Physiol, vol. 90, pp.1600-1605, 2001.[5] M.D. Costa, R.B. Davis, A.L. Goldberger. Heart rate fragmentation: anew approach to the analysis of cardiac interbeat interval dynamics.Front Physiol, vol 8, pp. 255. 2017.[6] A. Shimokawa, T. Kunitake, M. Takasaki, H. Kannan. Differentialeffects of anesthetics on sympathetic nerve activity and arterial barore-ceptor reflex in chronically instrumented rats. J. Auton. Nerv. Syst.,vol. 72, pp. 46–54, 1998.[7] S.J. Kim, A.Y. Fong, P.M. Pilowsky, S.B. Abbott. Sympathoexcita-tion following intermittent hypoxia in rat is mediated by circulatingangiotensin II acting at the carotid body and subfornical organ. J.Physiol, vol. 596, pp. 3217–3232, 2018.[8] Farré, R., Ncher, M., Serrano-Mollar, A., Gldiz, J. B., Alvarez, F. J.,Navajas, D., Montserrat, J. M. Rat model of chronic recurrent airwayobstructions to study the sleep apnea syndrome. Sleep, vol. 30, pp.930–933, 2007.[9] A. Carreras, I. Almendros, I. Acerbi, J.M. Montserrat, D. Navajas, R.Farr. Obstructive apneas induce early release of mesenchymal stemcells into circulating blood. Sleep, vol. 32, pp. 117–119, 2009.[10] R. Jané R, J. Lázaro, P. Ruiz, E. Gil, D. Navajas, R. Farré, P. Laguna.Obstructive Sleep Apnea in a rat model: Effects of anesthesia onautonomic evaluation from heart rate variability measures. In proc.Computing in Cardiology (CinC), pp. 1011-1014, 2013.[11] Martı́nez, J. P., Almeida, R., Olmos, S., Rocha, A. P., Laguna, P.A wavelet-based ECG delineator: evaluation on standard databases.IEEE Trans. Biomed. Eng, vol. 51, pp. 570-581, 2004.

Non-linear HRV analysis to quantify the effects of intermittent hypoxia using an OSA rat model

© 2019 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses, in any current or future media, including reprinting /republishing this material for advertising or promotional purposes, creating new collective works, for resale or redistribution to servers or lists, or reuse of any copyrighted component of this work in other worksIn this paper, a non-linear HRV analysis was performed to assess fragmentation signatures observed in heartbeat time series after intermittent hypoxia (IH). Three markers quantifying short-term fragmentation levels, PIP, IALS and PSS, were evaluated on R-R interval series obtained in a rat model of recurrent apnea. Through airway obstructions, apnea episodes were periodically simulated in six anesthetized Sprague-Dawley rats. The number of apnea events per hour (AHI index) was varied during the first half of the experiment while apnea episodes lasted 15 s. For the second part, apnea episodes lasted 5, 10 or 15 s, but the AHI index was fixed. Recurrent apnea was repeated for 15-min time intervals in all cases, alternating with basal periods of the same duration. The fragmentation markers were evaluated in segments of 5 minutes, selected at the beginning and end of the experiment. The impact of the heart and breathing rates (HR and BR, respectively) on the parameter estimates was also investigated. The results obtained show a significant increase (from 5 to 10%, p  0.9) between these markers and BR, as well as with the ratio given by HR/BR. Although fragmentation may be impacted by IH, we found that it is highly dependent on HR and BR values and thus, they should be considered during its calculation or used to normalize the fragmentation estimatesPeer Reviewe

UPCommons

Crossref

Non-linear HRV Analysis to Quantify the Effects of Intermittent Hypoxia Using an OSA Rat Model

UPCommons. Portal del coneixement obert de la UPC

Non-linear HRV Analysis to Quantify the Effects of IntermittentHypoxia Using an OSA Rat ModelDaniel Romero1 and Raimon Jane´1,2 Senior Member, IEEEAbstract— In this paper, a non-linear HRV analysis was per-formed to assess fragmentation signatures observed in heartbeattime series after intermittent hypoxia (IH). Three markersquantifying short-term fragmentation levels, PIP , IALS andPSS, were evaluated on R-R interval series obtained in arat model of recurrent apnea. Through airway obstructions,apnea episodes were periodically simulated in six anesthetizedSprague-Dawley rats. The number of apnea events per hour(AHI index) was varied during the first half of the experimentwhile apnea episodes lasted 15 s. For the second part, apneaepisodes lasted 5, 10 or 15 s, but the AHI index was fixed.Recurrent apnea was repeated for 15-min time intervals inall cases, alternating with basal periods of the same duration.The fragmentation markers were evaluated in segments of 5minutes, selected at the beginning and end of the experiment.The impact of the heart and breathing rates (HR and BR,respectively) on the parameter estimates was also investigated.The results obtained show a significant increase (from 5 to10%, p <0.05) in fragmentation measures of heartbeat timeseries after IH, indicating a clear deterioration of the initialconditions. Moreover, there was a strong linear relationship(r > 0.9) between these markers and BR, as well as withthe ratio given by HR/BR. Although fragmentation may beimpacted by IH, we found that it is highly dependent on HRand BR values and thus, they should be considered during itscalculation or used to normalize the fragmentation estimates.I. INTRODUCTIONObstructive sleep apnea (OSA) is a chronic health con-dition characterized by repeated episodes of apnea dur-ing sleep, resulting in sustained exposure to intermittenthypoxia (IH). This chronic condition has been linked tosome cardiovascular consequences of OSA, such as systemichypertension, myocardial infarction and stroke [1], [2], [3].To date, the underlying mechanisms linking IH to vasculardiseases in OSA are unclear. However, it has been reportedthat an elevated sympathetic tone of the autonomic nervoussystem (ANS) [4], oxidative stress and endothelial dys-function [2], inflammation and atherosclerosis [3] somehowcontribute to this matter.*This work supported in part by CERCA Program, Secretaria dUniver-sitats i Recerca del Departament dEmpresa i Coneixement de la Gener-alitat de Catalunya (GRC 2017 SGR 01770) and the Spanish Ministry ofEconomy and Competitiveness (DPI2015-68820-R MINECO/FEDER). D.R.acknowledges the financial support of the Juan de la Cierva fellowship fromMINECO, Ref: IJCI-2016-30696.1Daniel Romero is with the BIOSPIN group at the Institute for Bioengi-neering of Catalonia (IBEC), the Barcelona Institute of Science and Tech-nology (BIST), Barcelona, Spain. dromero@ibecbarcelona.eu2R. Jane´ is with the Institute for Bioengineering of Catalonia(IBEC), the Barcelona Institute of Science and Technology (BIST), Cen-tro de Investigacio´n Biome´dica en Red de Bioingenierı´a, Biomateri-ales y Nanomedicina (CIBER-BBN) and ESAII Department, Universi-tat Polite`cnica de Catalunya - BarcelonaTech (UPC), Barcelona, Spain.rjane@ibecbarcelona.euMany research studies in OSA have developed experimen-tal and human models of acute/chronic IH to figure out theassociation between OSA and cardiovascular diseases. Forinstance, in animal studies, the rat models represent oneof the most common experiments used for understandingand studying physiological mechanisms involved in sleepapnea. However, rats are usually anesthetized, which canaffect cardiovascular functions and the control handled by theautonomic nervous system (ANS) could be partially blocked.Although the dose, type and method used for anestheticsadministration can disturb in different ways this controlsystem in rats [6], a recent study reported increased sym-pathetic nerve activity, sympathetic peripheral chemoreflexsensitivity and central sympathetic respiratory coupling afterIH in anesthetized rats [7].To study the induced-hypoxia effects caused by OSA,a rat model of chronic recurrent airway obstructions wasdeveloped [8], [9]. This model was completed [10] with anexternal control varying the duration and frequency of theinduced apneas. Different sensors were included in order toacquire cardiac and respiratory activity, such as flow andpressure transducers, electrodes and a specific pulse oximeterfor rat monitoring.This study aims at characterizing the effects of intermittenthypoxia after completion of several recurrent apnea episodes.Modifications in the ANS activity after OSA episodes wereevaluated by means of fragmentation signatures observed inheartbeat time series, analyzed during the start and end ofthe experiment.II. MATERIALS AND METHODSA. Experimental dataSix male Sprague-Dawley rats (mean weight: 437±27 g)were intraperitoneally anesthetized with uretane (1g/1kg).The rats were connected to a system that incorporatesa controlled nasal mask, including one tube open to theatmosphere and another connected to a positive pressurepump, preventing the animal from rebreathing. OSA episodeswere simulated by obstructing the airways in the tubesusing electrovalves. The electrovalves were controlled bysoftware using the Biopacr Systems. The electrodes, nasalmask and SpO2 sensor were placed on the animals afteranesthesia and shaving (Fig 1). The experimental procedureinvolving the animal model described here was approved bythe Institutional Animal Care and Ethics Committee.Several signals were acquired during spontaneous breath-ing and simulated OSA episodes. Respiratory flow signal,respiratory pressure and electrocardiogram (ECG) signal(leads I and II) were registered by Biopacr Systems. Pho-toplesthysmography signal and SpO2 were measured by apulse oximeter (Mouse OxPlusr) positioned in the rat leg.+GroundBiopacECGBiopacoutMouseOxPlusSpO2, PPGElectrovalvesControlSystemEVEVPositivepressurepumpairPVFig. 1. Experimental setup for the OSA model, using two electrovalves(EV) and a positive pressure pump. Signal acquired: respiratory flow (V’)and pressure (P), SpO2 and PPG (MouseOx Plus r) and ECG ( Biopacr).B. Experimental ProtocolTwo different protocols were set for the experiment. Inboth of them, recurrent apnea episodes were induced for15-min intervals followed by 15-min resting periods. Apneaindex (AI) of 20, 40 and 60 apneas/hour were applied inthe first protocol with apnea episodes duration of 15 s (Fig.2-a). In the second protocol (Fig. 2-b), AI was fixed to 60and the apnea episodes lasted either 5, 10 or 15 s. In bothconfigurations, the order of the 15-min intervals of recurrentapnea was randomly selected. Desaturation levels, assessedfrom SpO2 signals, ranged between 5–23% with respect tothe pre-apnea values. For this study, only the initial and finalbasal intervals (end of the second protocol) were consideredto evaluate heart rate fragmentation before and after apneaepisodes, to assess the cumulative effect of IH.C. ECG PreprocessingECG signals, sampled at 1250 Hz, were preprocessedbefore the automatic extraction of the evaluated marker,including automatic QRS complex detection [11] and visualinspection to remove abnormal beats, baseline drift attenua-tion, 4-th order bidirectional Butterworth low-pass filtering at45 Hz to remove power line interference and high frequencynoise.D. Non-linear HRV analysisAfter QRS complexes detection, the time positions ofconsecutive R-wave peaks were determined and used to buildthe RR interval series in all rats as follows:RR[i] = R[i+ 1]−R[i]; i = 1, ...N − 1 (1)where i and N represent the i-th beat and the total numberof beats of the analyzed segment.a)b)Fig. 2. a) Protocol 1: Sequences of 15-s apnea episodes used during 15-minrecurrent apnea intervals, preceded and followed by resting periods of 15minutes (Bas #), applied for each rat. b) Protocol 2: Sequences of recurrentapnea episodes (with AI=60) for 15-min intervals, preceded and followedby resting resting period of 15 minutes (Bas #).To assess the level of fragmentation present in RR intervalseries, a set of recently proposed markers were evaluated onnormal-to-normal (NN) interval series, obtained by consid-ering only normal sinus heartbeats [5]. Abnormal intervalswere replaced by the average of the previous 5 intervals. Thefragmentation indices are the following:• PIP: The percentage of inflection points in the NN timeseries, that is, the number of zero-crossing points in thefirst derivative of the NN series referred to their totallengths.• IALS: The inverse average length of accelera-tion/deceleration segments. Acceleration/decelerationsegments represent consecutive NN intervals betweenadjacent inflection points, where the difference between2 consecutive NN intervals is negative or positive,respectively.• PSS: The percentage of NN intervals that are in shortsegments. Short segments are defined as those accel-eration or deceleration segments that lasted ≥ 3 NNintervals.According to the definition of fragmentation, the aboveindices will be higher if a time series is more fragmented.Importantly, removing the presence of non-sinus heartbeatsfrom the annotation step is crucial because it can increasefragmentation in the analyzed time series [5]. Nevertheless,since these parameters can be highly influenced by boththe respiratory rate (BR) and heart rate (HR), we alsoinvestigated their relationships during the experiment.E. Statistical analysisResults obtained are expressed in mean ± SD. TheWilcoxon signed rank nonparametric test was applied tocompare paired observations obtained at different stages ofthe experiment. The relationships of the parameters withHR and BR was determine using the Pearson’s correlationcoefficient. The significance level was set to 0.05 in all cases.III. RESULTSThe Fig. 3 shows an example of two NN segments (initialand final), analyzed in one rat of the study population. Itcan be observed that the initial segment is more regularthan the final one. Moreover, the HR is quite different inboth segments, being higher (> 20%) during the initialstage. Respiratory rate (BR) is slightly lower (∼17%) andthe number of inflections points (IP) is smaller at the end,however, the PIP value is higher. This suggests that somekind of relationship may exist between fragmentation andHR, BR, or a combination of both.0 10 20 30 40 50 60 70 80 90146148150152154156RR [ms]Beginning: HR=399 beats/min; RR=65 cycles/min; PIP= 30 % IP= 1870 10 20 30 40 50 60 70 80 90192194196198200202RR [ms]Ending: HR= 305 beats/min; RR=54 cycles/min; PIP= 35 % IP= 166Time [s]Fig. 3. NN time series representing 90-s segments during the initial andfinal stage of the experiment. Red points indicate inflection points detectedon the NN series. Heart rate, respiratory rate, PIP value and the number ofIP are displayed in the top of each graph.Table 1 summarizes the results obtained for all markersand rats before and after IH. It can be observed that boththe HR and HR/BR significantly decreased by the end of theexperiment while the PIP and PSS markers were significantlyhigher, indicating an increase in fragmentation of the timeseries analyzed. The p-values obtained show that only BRdid not change significantly between both time periods.In Fig. 4 are plotted the PIP values against the HR, BRand the ratio HR/BR for each animal, evaluated during theinitial and final stages. The straight lines represent the modelobtained after fitting a linear function to all data. From thefigure, we can observe that BR and the HR/BR ratio have astrong linear relationship with the PIP values when the ex-periment started. However, in the case of HR, some animalswith similar values (see Fig. 4-(a)) present very differentfragmentation measures in the same period, meaning that BRTABLE IMEAN ± SD OF THE NON-LINEAR HRV PARAMETERS, HEART RATEAND RESPIRATORY RATE.Parameters Before IH After IH p-valueHR (beats/min) 385 ± 26 350 ± 29 0.0156BR (cycles/min) 92 ± 18 90 ± 19 0.2813HR/BR (beats/cycles) 4.3 ± 1.0 4.0 ± 0.8 0.0469PIP (%) 46.5 ± 7.8 50.3± 5.5 0.0313PSS (%) 64.7 ± 27.0 74.8 ± 24.1 0.0469IALS (%) 0.46 ± 0.08 0.51 ± 0.05 0.0313seems to have a stronger impact on fragmentation estimatesas compared to HR.30 35 40 45 50 55280300320340360380400420HR [beats/min]R= −0.06967730 35 40 45 50 555060708090100110120RR [cycles/min]R= 0.9460230 35 40 45 50 5534567HR/RRPIP (%)R= −0.9893540 45 50 55 60280300320340360380400420HR [beats/min]R= 0.7930640 45 50 55 605060708090100110120RR [cycles/min]R= 0.9330140 45 50 55 6034567HR/RRPIP (%)R= −0.93911Fig. 4. PIP values vs HR, RR and HR/RR ratio obtained for all animalsbefore (left column) and after (right column) the IH. R stands for Pearson’scorrelation coefficient.The same analysis was performed after completion of therecurrent apnea episodes to assess their effects. Results aredisplayed in the right column of Fig. 4. In most rats, HR andBR decreased with respect to the initial values, confirmingthe results of Table I. The HR/BR ratio was also lower at thefinal stage, keeping in some extent their linear relationshipwith the fragmentation values. The major difference wasobserved in the analysis of HR vs PIP, where the linearmodel fitted better to the actual data as compared to theinitial ones. Similar results were also obtained for the PSSand IALS markers, which are summarized in Table II.In addition to the actual values, the changes developedduring the experiment by the analyzed markers were alsoinvestigated. Fig. 5 presents the correlation values obtainedwhen analyzing the changes seen in fragmentation markersvs those changes occurred in HR, BR an their ratio. In-10 -5 0020406080100HR (beats/min)R= -0.51008-20 -10 0020406080100R= -0.60093-0.1 -0.05 0020406080100R= -0.58267-10 -5 0-10-5051015BR (cycles/min)R= 0.19485-20 -10 0-10-5051015R= -0.096647-0.1 -0.05 0-10-5051015R= 0.13521-10 -5 0PIP (%)-0.200.20.40.60.8HR/BRR= -0.86249-20 -10 0PSS (%)-0.200.20.40.60.8R= -0.64171-0.1 -0.05 0IALS-0.200.20.40.60.8R= -0.90239Fig. 5. Correlation values obtained between changes observed in fragmen-tation markers and in heart rate, respiratory rates and their ratio.this analysis, only HR/BR seems to have a stronger linearrelationship with all of them.TABLE IICORRELATION VALUES OBTAINED BETWEEN FRAGMENTATIONMARKERS AND THE HEART AND RESPIRATORY RATES.HR BR HR/BRParameters Before | After Before | After Before | AfterPIP (%) -0.07 | 0.79 0.95 | 0.93 -0.99 | -0.94PSS (%) -0.07 | 0.72 0.94 | 0.85 -0.97 | -0.85IALS (%) -0.07 | 0.79 0.95 | 0.93 -0.99 | -0.93IV. DISCUSSION AND CONCLUSIONSIn this study, we evaluated the level of fragmentationobserved in heartbeat time series and how they are affectedby intermittent hypoxia. To performed this analysis, weevaluated three fragmentation indices on RR interval timeseries, extracted from the initial and final periods of an OSAmodel in rats. The results obtained shown that the level offragmentation significantly increased (between 5% and 10%,p < 0.05) after completion of several sequences of recurrentapnea episodes, which caused intermittent hypoxia duringthe whole experiment.A important finding of the study is related to the fact thatboth the respiratory rate and its relationship to heart rate arehighly correlated with fragmentation parameters (|R| > 0.9).Comparable results were also obtained when HR/BR changeswere correlated with these parameters. This finding suggeststhat these variables could be used to obtain indirect measuresof fragmentation levels, or at least should be consideredduring their calculation.Costa et al. [5] reported that fragmentation of heartbeattime series increases with aging in healthy subjects as wellas in patients with heart diseases such as coronary arterydisease (CAD). However, fragmentation tends to be higherin patients with CAD than in healthy subjects of similar ages.They also showed that fragmentation seems not to be affectedby the mean heart rate, however, our study showed a highcorrelation with respiratory rate and the ratio between HRand BR, even under different conditions. Nevertheless, ourresults should be interpreted with caution due to the smallsize of the population.It is known that intermittent hypoxia caused by obstructivesleep apnea may contribute to impaired autonomic cardiacfunction. These alterations are mainly driven by the sympa-thetic activation and may represent mechanisms for increasedoccurrence of cardiac arrhythmias in OSA patients. Weconcluded that the investigated parameters could be useful toassess how much the HRV is affected after recurrent hypoxiaepisodes, and they should be analyzed and compared to othertraditional HRV markers to determine their added value inpatients with OSA.ACKNOWLEDGMENTThe authors are grateful to Ramon Farre´, Daniel Navajas,Josep Maria Montserrat, Isaac Almendros, Marta Torresand Puy Ruiz for their excellent help in designing andimplementing the animal model.REFERENCES[1] N.R. Prabhakar. Invited Review: Oxygen sensing during intermittenthypoxia: cellular and molecular mechanisms. J Appl Physiol, vol. 90,pp. 1986-1994, 2001.[2] L. Lavie. Obstructive sleep apnoea syndrome - an oxidative stressdisorder. Sleep Med Rev, vol. 7, pp. 35-51, 2003.[3] L. Lavie. Sleep-disordered breathing and cerebrovascular disease: amechanistic approach. Neurol Clin, vol. 23, pp. 1059–1075, 2005.[4] E.C. Fletcher. Invited review: Physiological consequences of intermit-tent hypoxia: systemic blood pressure. J Appl Physiol, vol. 90, pp.1600-1605, 2001.[5] M.D. Costa, R.B. Davis, A.L. Goldberger. Heart rate fragmentation: anew approach to the analysis of cardiac interbeat interval dynamics.Front Physiol, vol 8, pp. 255. 2017.[6] A. Shimokawa, T. Kunitake, M. Takasaki, H. Kannan. Differentialeffects of anesthetics on sympathetic nerve activity and arterial barore-ceptor reflex in chronically instrumented rats. J. Auton. Nerv. Syst.,vol. 72, pp. 46–54, 1998.[7] S.J. Kim, A.Y. Fong, P.M. Pilowsky, S.B. Abbott. Sympathoexcita-tion following intermittent hypoxia in rat is mediated by circulatingangiotensin II acting at the carotid body and subfornical organ. J.Physiol, vol. 596, pp. 3217–3232, 2018.[8] Farre´, R., Ncher, M., Serrano-Mollar, A., Gldiz, J. B., Alvarez, F. J.,Navajas, D., Montserrat, J. M. Rat model of chronic recurrent airwayobstructions to study the sleep apnea syndrome. Sleep, vol. 30, pp.930–933, 2007.[9] A. Carreras, I. Almendros, I. Acerbi, J.M. Montserrat, D. Navajas, R.Farr. Obstructive apneas induce early release of mesenchymal stemcells into circulating blood. Sleep, vol. 32, pp. 117–119, 2009.[10] R. Jane´ R, J. La´zaro, P. Ruiz, E. Gil, D. Navajas, R. Farre´, P. Laguna.Obstructive Sleep Apnea in a rat model: Effects of anesthesia onautonomic evaluation from heart rate variability measures. In proc.Computing in Cardiology (CinC), pp. 1011-1014, 2013.[11] Martı´nez, J. P., Almeida, R., Olmos, S., Rocha, A. P., Laguna, P.A wavelet-based ECG delineator: evaluation on standard databases.IEEE Trans. Biomed. Eng, vol. 51, pp. 570-581, 2004.

https://upcommons.upc.edu/bitstream/2117/181019/1/EMBC19_2305_FI.pdf

Non-linear HRV analysis to quantify the effects of intermittent hypoxia using an OSA rat model

Abstract

Similar works

Full text

Available Versions

UPCommons (Universitat Politècnica de Catalunya)

UPCommons

Crossref

UPCommons. Portal del coneixement obert de la UPC