Improved sleep, cognitive processing and enhanced learning and memory task accuracy with Yoga nidra practice in novices

Karuna Datta; Anna Bhutambare; Mamatha V L; Yogita Narawa; Rajagopal Srinath; Madhuri Kanitkar

doi:10.1371/journal.pone.0294678

. 2023 Dec 13;18(12):e0294678. doi: 10.1371/journal.pone.0294678

Improved sleep, cognitive processing and enhanced learning and memory task accuracy with Yoga nidra practice in novices

Karuna Datta ^1,^*, Anna Bhutambare ², Mamatha V L ³, Yogita Narawa ², Rajagopal Srinath ⁴, Madhuri Kanitkar ⁵

Editor: Kallol Kumar Bhattacharyya⁶

PMCID: PMC10718434 PMID: 38091317

Abstract

Complementary and Alternative medicine is known to have health benefits. Yoga nidra practice is an easy-to-do practice and has shown beneficial effects on stress reduction and is found to improve sleep in insomnia patients. Effect of yoga nidra practice on subjective sleep is known but its effect on sleep and cognition objectively is not documented. The aim of the study was to study the effect of yoga nidra practice on cognition and sleep using objective parameters. 41 participants were enrolled, and baseline sleep diary (SD) collected. Participants volunteered for overnight polysomnography (PSG) and cognition testing battery (CTB) comprising of Motor praxis test, emotion recognition task (ERT), digital symbol substitution task, visual object learning task (VOLT), abstract matching (AIM), line orientation task, matrix reasoning task, fractal-2-back test (NBACK), psychomotor vigilance task and balloon analog risk task. Baseline CTB and after one and two weeks of practice was compared. Power spectra density for EEG at central, frontal, and occipital locations during CTB was compared. Repeat SD and PSG after four weeks of practice were done. After yoga nidra practice, improved reaction times for all cognition tasks were seen. Post intervention compared to baseline (95%CI; p-value, effect size) showed a significant improvement in sleep efficiency of +3.62% (0.3, 5.15; p = 0.03, r = 0.42), -20min (-35.78, -5.02; p = 0.003, d = 0.84) for wake after sleep onset and +4.19 μV² (0.5, 9.5; p = 0.04, r = 0.43) in delta during deep sleep. Accuracy increased in VOLT (95% CI: 0.08, 0.17; p = 0.002, d = 0.79), AIM (95% CI: 0.03, 0.12; p = 0.02, d = 0.61) and NBACK (95% CI: 0.02, 0.13; p = 0.04, d = 0.56); ERT accuracy increased for happy, fear and anger (95% CI: 0.07, 0.24; p = 0.004, d = 0.75) but reduced for neutral stimuli (95% CI: -0.31, -0.12; p = 0.04, r = 0.33) after yoga nidra practice. Yoga Nidra practice improved cognitive processing and night-time sleep.

1. Introduction

Complementary and Alternative medicine is known to have benefits in both health and disease [1]. A concept of therapeutic yoga has thus emerged, and a need to build standardised models has become vital. Studies have shown that yoga can be performed in many different ways [2, 3]. However ease of doing yoga is important for its acceptability by the population. Moreover, if any particular yogic practice can be standardised, then it can be easily taught and learnt, thus increasing its effectiveness in promoting wellbeing.

Yoga nidra practice, a kind of pratyahara (withdrawal of senses) technique, is an easy-to-do practice [4]. It has been described as an ‘awake aware sleep’ and thus differs from meditation and hypnosis [4, 5]. Yoga nidra is done in supine posture unlike meditation, which is practiced in seated posture. The practice of yoga nidra in novices showed increased power spectra density of delta frequency band at different areas, like local sleep, during some parts of yoga nidra, while the subject epochs were documenting wake state [6]. This makes yoga nidra unique since it exhibits delta propensity during the practice, unlike meditation which exhibits alpha-theta state effects [4, 7]. Its use has been associated with stress reduction and its role in management of insomnia, menstrual abnormalities, post-traumatic stress disorder, etc and for improved sleep and performance in sportsperson has been documented [8–13]. Yoga nidra practice has been standardised for learning by novices [14], thus improving the effectiveness of its sessions.

Good sleep quality is essential for human performance. Individuals who need to take critical decisions require optimized cognitive functioning. There is evidence that improved sleep enhances cognitive functioning whereas partial sleep deprivation reduces it [15].

Effects of yoga nidra in meditators has been reported earlier [16–19]. However, the effects seen in skilled meditators cannot be compared with those in novices. It is also likely that the effects of meditation itself will confound the effects of yoga nidra in skilled meditators. The methodology for yoga nidra practice by novices has already been laid out [4] and it has been proven to improve sleep in insomnia patients [8, 14]. Novices also reported a subjective improvement of night-time sleep [6, 9, 20] along with an evidence of local sleep during morning yoga nidra practice [6]. Subjective improvement in cognitive scores and self observation notes has also been found using various duration and frequency of yoga nidra practice [20, 21]. However its effect on objective parameters of sleep and cognition in healthy novices is not documented. There was thus a felt need to study the effect of yoga nidra practice by novices on their sleep and cognition objectively.

2. Methods

2.1 Study design and participants

The project was a pre-post interventional cohort study that aimed to study the effect of yoga nidra practice on cognitive function and sleep.

The study was conducted as a pilot project on healthy volunteers and their cognition was assessed at baseline and after yoga nidra practice. Objective sleep parameters using overnight polysomnography (PSG) were also studied at baseline and after yoga nidra practice.

The yoga nidra supervised training model for novices developed by Datta et al [8, 14] was used for this study. Participants were assessed after one and two weeks of practicing yoga nidra. Details of study design are given in Fig 1(A) and 1(B) for both objectives, i.e., the effect of yoga nidra practice on cognitive function and on night-time objective sleep parameters respectively.

The study was conducted during 2021–2022 after institutional ethical clearance (IEC/2019/255 dated 25 Apr 2019). The study was registered in CTRI.in, vide no. CTRI/2021/031349. Local advertisements in the city were placed and volunteers assessed for eligibility. A minimum of 30 participants for each of the objectives were considered for this pilot study.

2.2 Screening of participants & enrollment

Healthy young male volunteers with a consistent sleep wake schedule were recruited. All participants underwent a thorough examination by a medical practitioner. Sleep wake schedule was monitored, and a baseline sleep diary of 14 days obtained. Exclusion criteria included any sleep disorder, depression, h/o psychiatric disorder, and h/o acute illness which were likely to affect sleep wake schedule. Women were excluded from this pilot study due to the confounding effect of the various menstrual phases on sleep [22, 23].

2.3 Intervention: Yoga nidra practice

A pre-recorded yoga nidra audio session was used (available at https://youtu.be/0fmMlELn-Ug). Yoga nidra was practiced for 20 minutes with three minutes of instructions before and after the practice. The practice consisted of seven steps, namely: preparation, samkalpa (resolution), body part awareness, breath awareness, feeling and sensation, visualization, and ending of practice. Initially, yoga nidra training was done using supervised Yoga nidra sessions as per the therapeutic model developed earlier. During these supervised sessions, the investigator followed the ‘guidelines for observer’ developed earlier [8, 14]. These guidelines helped check the compliance and attentiveness of the subject during the session. This was done by looking for visual cues to ascertain that the participant followed the instructions of the audio. Participants having restlessness to an extent of affecting them to concentrate on the practice were asked to discontinue the session by the observer. At the end of the session, the participant was asked to review the audio and identify any portion that may have been missed during the session. This improved the effectiveness and completeness of yoga nidra practice on the subsequent days. After each supervised session any complaints of the participants or inability to do any part of the practice were addressed. The participants continued the practice on their own after the supervised training was done. Follow up testing on participants was done as per the study design given in Fig 1(A) and Fig 1(B).

2.4 Sleep Diary (SD) analysis

All participants filled a baseline sleep diary for 14 days. The sleep diary was filled twice a day, once in the morning just after getting up and again at night just before bedtime. The participants continued to fill the sleep diary during the intervention. The sleep diary parameters obtained were: time in bed (sdTIB), total sleep time (sdTST), sleep onset latency (sdSOL), wake after sleep onset (sdWASO), sleep quality (sdSQ), and sleep efficiency (sdSE)[14]. These parameters were extracted from the baseline two-week data and also from the post-intervention two week data.

Data Analysis: Sleep diary data was checked for normality using Shapiro-Wilks test. If data was normally distributed, paired t-test was used to compare baseline sleep diary parameters with post intervention values. For non-normal data several transformations like square, square root, log, and exponential were tried. If normality was not achieved, the Wilcoxon signed rank test was used. Statistical significance was considered at alpha 0.05. All statistical analyses were done using R-software (version 4.1.2).

2.5 Methodology for assessing the effect of yoga nidra practice on cognitive function

The cognition test battery (CTB) was employed using the Joggle Research Platform (USA) [24]. Our CTB paradigm consisted of ten tests in a standard sequence of motor praxis task (MPT), visual object learning task (VOLT), fractal-2-back (NBACK), abstract matching (AIM), line orientation task (LOT), emotion recognition task (ERT), matrix reasoning task (MRT), digital symbol substitute task (DSST), balloon analog risk task (BART), and psychomotor vigilance task (PVT:10min). The various cognition domains that were assessed by these 10 tests were: MPT–sensory motor speed, VOLT–spatial learning and memory, NBACK–working memory, AIM–abstraction and concept information, LOT–spatial orientation, ERT–emotion identification, MRT–abstract reasoning, DSST–complex scanning and visual tracking, BART–risk decision making, and PVT–vigilant attention [24].

CTB was performed on four test condition days which were control with eyes open (CEO), control with eyes close (CEC), at the end of 1^st week of yoga nidra practice (YN1W), and at the end of 2^nd week of yoga nidra practice (YN2W). All the participants completed the CTB tests three times on each test condition day i.e., at 1000h (First test of morning: Mr1), immediately after the test condition of CEC, CEO, yoga nidra practice at YN1W, or yoga nidra practice at YN2W (Second test of morning: Mr2) and then in the afternoon at 1500h (post lunch: PL). All participants received similar food and working environment on each test condition day. Detailed representation of study design is shown in Fig 1(A).

CTB outcome variables studied were reaction time (for all 10 tests) and accuracy score for nine tests, except BART. For BART–‘Adjusted Number of Pumps’, ‘Number of Explosions’, ‘Risk Propensity’ and ‘Cash collected’ were analyzed [25]. ‘Adjusted Pumps’ is the average number of pumps on each balloon during BART when the balloon did not burst, ‘Number of Explosions’ is the total number of balloons exploded during BART, ‘Risk Propensity’ is the ratio of total pumps/balloons collected, and ‘Cash collected’ is the amount of reward earned in BART [24].

The standard accuracy outcome was ‘proportion correct’ ranging from ‘zero’ to ‘one’, where ‘zero’ and ‘one’ represented worst and best possible performance respectively. For the MPT, the distance from the center of the square to the point where participant touches was used as an accuracy score. The center of square translates to ‘one’ accuracy score and an edge of square to ‘zero’ accuracy score, with linear scaling between center and edges. For LOT, the accuracy score was calculated as ‘three’ minus the average number of clicks off, which was then divided by ‘three’. For tests with average number of clicks off is more than ‘three’, the accuracy score was set to ‘zero’. For PVT, the accuracy score was calculated as ‘one’–[(number of lapses + number of false starts) / (number of stimuli + number of false starts)]. PVT- number of false starts was analyzed apart from reaction time and accuracy [24]. ERT was also studied for various types of stimuli apart from reaction time and accuracy.

Data Analysis: One-Way Repeated Measures (RM) Analysis of Variance (ANOVA) for checking significant change in each of the outcome variable between different test conditions (CEO, CEC, YN1W, and YN2W) and at different times (Mr1, Mr2, or PL) was used for normal data. If the data was not normal, Friedman’s test was used. In instances where the sphericity assumption was not met, the reported p-values associated with the F-statistics were adjusted via the Greenhouse-Geisser correction. If the ANOVA model was significant, post-hoc analysis (pair wise comparison) was done using paired t-test with Bonferroni Correction. Wilcoxon Signed Rank Test with Bonferroni Correction was used for post-hoc analysis (pair wise comparison) if Friedman’s Test was significant. Bonferroni Correction was used to reduce the probability of type-1 error. All reported p-values were two-tailed and statistical significance was assumed if p-value < 0.05. For t-test, effect size was calculated using Cohen’s d (d) where d < 0.5 was small effect, 0.5 ≤ d < 0.8 was moderate effect, and d ≥ 0.8 was large effect. For Wilcoxon Signed Rank Test, effect size was calculated using Wilcoxon effect size (r) where r < 0.3 was small effect, 0.3 ≤ r < 0.5 was moderate effect, and r ≥ 0.5 was large effect. For ANOVA, generalized eta-squared (ƞ²) was used as effect size, where ƞ² < 0.06 was small effect, 0.06 ≤ ƞ² < 0.14 was medium effect, and ƞ² ≥ 0.14 was large effect.

All statistical analyses were done using R (version 4.1.2).

2.6 Power spectral density (PSD) of EEG daytime recording during CTB

The power spectral analysis of EEG data was performed using MNE-Python, an open-source library for visualizing, analyzing and exploring the raw EEG signal [26]. PSD analysis was planned out for the EEG data of 12 participants who volunteered for the EEG acquisition during CTB. This included loading data, pre-processing, and segmentation of the continual data on the obtained epoched data. Time-Frequency investigation was performed and finally spectral-parameters of the EEG signal was extracted [27]. Spectral investigation was based on frequency bands. PSD is the reflection of frequency components of EEG signal [28]. Preprocessing included low and high frequency filtering of the EEG signal, notch filtering and removal of bad segments of the data (made by visual screening of data for sudden artifacts). Eye movements were repaired using the artifacts repair regression technique, custom re-referencing, and segmentation of the EEG data to epochs. Filtering was done at low-frequency (1Hz), high-frequency (90Hz) and notch-filter at 50Hz. After manual marking of artifacts and bad segments, MNE-Python library was used to automatically exclude annotated spans of data while creating the epochs from the continual EEG data. Special care was taken to avoid segments with artifacts or noise so that artifact free data would be extracted for further analysis. The EEG signal acquisition was based on the domain of time and future extraction. Slow eye movement artifacts in the EEG were repaired using computed coefficients [29].

Segmentation was performed on the clean raw EEG data to segment the EEG data to epochs. ‘Feature extraction’ was done based on ‘Time-Frequency domain’ [27, 30]. The time-frequency domain depicts the distribution of power of the EEG signal with respect to Time-Frequency plane. The computation of PSD was carried out using Welch’s Technique. The decomposition of signal to frequency bands were done using Fourier transforms [27]. The ranges of the bands were delta (1-4Hz), theta1 (4-6Hz), theta2 (6-8Hz), alpha1 (8-10Hz), alpha2 (10–12.5Hz) and beta (13-30Hz) [6]. The features used in the EEG signal analysis were relative-band-power and ratios between the bands [31]. On each test segment spectral analysis was performed for all the EEG channels. Using 256Hz sampling rate of EEG, feature extraction was done from the desired test segments for all the EEG channels on every individual participant using 512ms window duration. The specified spectral analysis methodology was employed for all the participants on all test conditions i.e., CEC, CEO, YN1W, and YN2W for all the times i.e., Mr1, Mr2, and PL. PSD values were compared for various frequency bands and as ratios. The various parameters thus studied were PSD values of delta, theta1, theta2, alpha1, alpha2, beta and ratios of delta/beta, theta1/beta, theta2/beta, theta1/alpha1, theta2/alpha1, theta1/alpha2, theta2/alpha2, delta/theta1, delta/theta2, delta/alpha1, and delta/alpha2.

Data Analysis: One-way ANOVA model was used for checking significance of difference in the PSD outcome parameters and post-hoc analysis using Tukey post-hoc test was done, if the data was normal. Otherwise Kruskal Wallis test was used with Wilcoxon test for post-hoc analysis. Statistical significance was considered at alpha 0.05. All statistical analyses were done using R (version 4.1.2).

2.7 Methodology for assessing the effect of yoga nidra practice on objective sleep parameters

Overnight PSG was done in 30 participants to assess the effect of yoga nidra on objective sleep parameters. PSG was conducted according to AASM criteria [32] using ‘SOMNOMEDICS©, Germany PSG System’. EEG, EOG, EMG channels were placed for scoring sleep-wake stages using DOMINO© software version 3.0.0.6. F3, F4, C3, C4, O1, and O2 EEG channels were placed as per the 10–20 system. PSG study was done during the night under standard conditions. The impedance was tried to be kept below 5KΩ. PSG was performed twice, at baseline (BL PSG) and post-intervention i.e., after four weeks of yoga nidra practice after initial training (PI PSG).

PSG data files were analyzed by KD in groups of 15–20 files and each was coded to blind KD from the identity state of subject data i.e., of baseline (BL) or post-intervention (PI). The files once analyzed were decoded by AB for further analysis.

Various parameters obtained using PSG were time in bed (TIB), total sleep time (TST), wake duration, wake after sleep onset (WASO), and duration of various stages of sleep (i.e., N1, N2, N3 and REM). Amplitude of alpha, beta, theta and delta waves was recorded in μV². Percentages for sleep, wake, REM, and Non-REM sleep were calculated and analyzed.

Data Analysis: Normality of data was checked using Shapiro-Wilk’s test. Quantile-Quantile plot for each of the outcome parameter was made. If normality was not obtained even after square root, square, log, and exponential transformations then analysis was done using Wilcoxon Signed Rank Test. All statistical analyses were done using R (version 4.1.2).

3. Results and discussion

41 participants were enrolled in the study. Details of number of participants screened, allocated, and finally analyzed are shown in Fig 2. Three participants could not report for testing due to the COVID pandemic during the time of study, though they continued the intervention. No adverse effects were reported. Those participants who were unable to report for either CTB or PSG were not included in the analysis as shown in Fig 2. The demographic profile of participants is provided in S1 Table. In four participants, sleep diary data for some days was missing in either the baseline or post-intervention data but was < 10%. This was imputed with the mean of rest data values. This was either in baseline (n = 3) or in post-intervention (n = 1) and none in both baseline and post-intervention. Analysis was done on these completed sleep diaries (n = 38). Sleep diary analysis is shown in Table 1. We found a significant improvement in total sleep time, sleep quality, sleep onset latency, and WASO which was reported subjectively by the patients using sleep diary.

Table 1. Sleep diary parameters of participants before (baseline) and after four weeks of Yoga nidra practice (post intervention) after training.

Variables	Baseline		Post-intervention		Wilcoxon test (P-value)	Effect size (r)	Difference: PI-BL		95% CI (PI-BL)		%Change = (PI-BL)/BL*100
Variables	Mean	SD	Mean	SD	Wilcoxon test (P-value)	Effect size (r)	Mean	SD	LL	UL	%Change = (PI-BL)/BL*100
sdTIB(min)	409.39	80.28	427.51	66.96	<0.001	0.24	18.12	98.99	9.69	26.55	4.43%
sdTST(min)	383.95	80.27	408.96	69.59	<0.001	0.32	25.01	100.72	16.44	33.59	6.52%
sdSOL(min)	21.75	21.05	16.31	17.90	<0.001	0.25	-5.45	25.32	-7.60	-3.29	-25.03%
sdWASO(min)	3.99	9.93	2.29	5.72	<0.001	0.18	-1.70	10.69	-2.61	-0.79	-42.59%
sdSQ	7.94	1.29	8.25	1.16	<0.001	0.21	0.31	1.49	0.18	0.43	3.84%
sdSE (%)	93.75	5.61	95.57	4.63	<0.001	0.32	1.82	6.70	1.25	2.39	1.94%

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Note. Wilcoxon signed rank test was used to compare baseline with post-intervention and effect size was calculated using Wilcoxon effect siI(r) where r < 0.3 (small effect), 0.3 ≤ r < 0.5 (moderate effect), and r ≥ 0.5 (large effect).

sdTIB(min): Time in bed in minutes, sdTST(min): Total sleep time in minutes, sdSOL(min): Sleep onset latency in minutes, sdWASO(min): Wake after sleep onset in minutes, sdSQ: Sleep quality (subjective rating between 0–10), sdSE(%): Sleep efficiency calculated as (TIB/TST)*100, PI: Post intervention reading, BL: Baseline reading, CI: Confidence interval, LL: Lower limit, UL: Upper limit.

Polysomnography data (baseline; post-intervention; p-value, effect size) of TIB (428·09±82·13; 423·02±72·96; 0·67, d = 0.09), TST (372·36±68·46; 387·70±74·94; 0·24, d = 0.24), and of Total Non-REM (340·73±111·95; 341·88±73·48; 0·95, d = 0.01) was not significant. Pre-post-intervention analysis of other PSG parameters is shown in Fig 3. Our results showed an objective improvement in nighttime sleep after yoga nidra practice in novices. We found an increase in sleep efficiency, improvement in WASO and a significant improvement in delta sleep (%) of slow wave sleep. It is likely that a reduction in sympathetic drive and an increase in parasympathetic drive occurred due to the practice of yoga nidra during the morning hours, resulting in improved slow wave sleep later in the night [33]. However, the exact mechanism is still not elucidated. The objective improvement of the delta sleep in slow wave sleep has been an important factor in improvement of sleep quality. Enhancement of slow wave sleep is reported using auditory stimuli during sleep, gaboxadol, tiagabine and transcranial direct cranial stimulation [34–36]. Slow wave sleep enhancement has been found to improve attention, learning, memory and performance [35–37]. Slow waves during sleep have been directly or indirectly linked to synaptic strength as a part of synaptic homeostasis theory [38].

Fig 3 — (Note- $: p-values computed using Wilcoxon signed rank test. Rest all p-values are computed using two-tailed paired t-test).

Cognition testing battery results for test condition wise and testing time wise comparisons in reaction time are shown in Figs 4 and 5 respectively. The comparisons of condition wise and testing time in accuracy scores are shown in S1 and S2 Figs respectively. Master sheet of CTB results in Mean (SD) is given in S2 Table. BART results for ‘adjusted number of pumps’, ‘risk propensity’, ‘cash collected’, and ‘number of balloons burst’ are shown in S3 and S4 Figs for test condition and testing time wise comparisons respectively. PVT result of ‘number of false starts’ is shown in S5 Fig.

Fig 4 — (Comparison model for test condition i.e. CEC, CEO, YN1W, and YN2W is shown below each time i.e. Mr1, Mr2, and PL. Significant post-hoc p-values are also depicted). #: One-Way Repeated Measure (RM) Analysis of Variance (ANOVA) p-values $: Post-hoc analysis (pairwise comparison) is done using paired t-test with Bonferroni correction (significant changes indicated by p-values given above the bars). @: Friedman’s test p-value (if data is not normally distributed) &: Post-hoc analysis (pairwise comparison) is done using Wilcoxon Signed-Rank test with Bonferroni correction (significant changes indicated by p-values given above the bars). Mr1: Test just before CEC, CEO, YN1W or YN2W; Mr2: Tests conducted just after CEO, C EC, YN1W or YN2W; PL: Test conducted after the lunch.

Fig 5 — (Comparison model for time i.e. Mr1, Mr2, and PL is shown below each test condition i.e. CEC, CEO, YN1W, and YN2W. Significant post-hoc p-values are also depicted)#: One-Way Repeated Measure (RM) Analysis of Variance (ANOVA) p-values $: Post-hoc analysis (pairwise comparison) is done using paired t-test with Bonferroni correction (significant changes indicated by p-values given above the bars). @: Friedman’s test p-value (if data is not normally distributed) &: Post-hoc analysis (pairwise comparison) is done using Wilcoxon Signed-Rank test with Bonferroni correction (significant changes indicated by p-values given above the bars). Mr1: Test just before CEC, CEO, YN1W or YN2W; Mr2: Tests conducted just after CEO, C EC, YN1W or YN2W; PL: Test conducted after the lunch.

Yoga nidra practice resulted in significant improvement in reaction time with no deterioration in accuracy of all cognitive battery tests i.e., MPT, VOLT, NBACK, AIM, LOT, ERT, MRT, DSST, BART, and PVT. This implies an increase in processing speed. Certain tests like AIM, ERT, NBACK, and VOLT actually showed an increase in accuracy too. This is possible due to the effects of the practice either directly or indirectly on the various brain regions involved in performing these tests. It is also possible that these effects are due to the local sleep seen in central, occipital and parietal areas during the rotation of consciousness in yoga nidra practice as brought out by Datta et al in a previous study on novices [6]. Following local sleep, task performance is found to be enhanced [39]. Though not examined in this study, but probably the increase in synaptic strength as per the synaptic hypothesis might also be responsible for these findings [38].

Accuracy improved in Abstract Matching test which is specifically related to prefrontal cortex and includes abstraction and concept formation. This accuracy was found to be increased in early morning which may be as a direct or indirect effect related to improved sleep after yoga nidra practice. Slow wave sleep is essential for enhanced prefrontal cortex activity. Working memory as shown with NBACK test also showed significant improvement with yoga nidra practice. The actual number of ‘adjusted number of pumps’ on balloons collected as cash, showed a significant increase in post lunch session after two weeks of practice. This meant that the number of bursts on the balloons only which were encashed was higher. ERT showed a significant deterioration in the early morning task scores, though, immediately after yoga nidra practice, it did not show any significant change in scores as compared to baseline. This was further studied by analyzing the type of stimuli where there was a change. ERT analysis for various types of stimuli is shown in S3 Table. On further analysis, it was evident that yoga nidra intervention only showed deterioration in neutral stimuli recognition without affecting the emotion recognition of happy stimuli and in fact improved recognition of anger and fear stimuli. The exact mechanism of this cannot be understood and would require further study. The relative improvement in non-neutral emotional recognition task is also interesting and requires more deliberation with special emphasis on emotion recognition and thus future study may aim at the effects of yoga nidra practice on social interaction.

12 participants volunteered for daytime EEG recording during CTB. To understand the mechanism of the effect of the yoga nidra practice during these cognitive tasks EEG PSD values at O1, F3, and C3 were analyzed. Summary of significant test results in EEG analysis of power spectra density using Python are shown in Table 2. These showed significant changes in VOLT, in which accuracy of CTB was also found to be increased. Significant increase in PSD in delta and theta frequencies was seen at O1 location after two weeks of yoga nidra practice. At C3 location also, PSD of theta remained significantly increased, immediately after yoga nidra practice during VOLT. A local sleep type phenomenon with some direct or indirect effects on areas associated with VOLT i.e. middle-temporal cortex and hippocampus, might explain this positive effect on spatial learning in memory. In our study, it is also interesting to note that after the practice also, delta propensity continued without reduction in accuracy, rather improvement in reaction time. It can only be postulated that increased PSD of delta waves implying enhancement of slow waves may be due to the increased strength of synapses [40] as highlighted by Tononi et al. Increased delta propensity during tasks on EEG PSD values, especially in the early morning readings after two weeks of yoga nidra practice, hints also at a not so immediate effect of practice, and might be a post good night sleep effect after practicing yoga nidra for two weeks in the mornings.

Table 2. EEG PSD significant results in frequency bands during CTB at various EEG locations.

CBT Task	EEG channel	Test time	Frequency band	ANOVA (p-value)	Effect size (ƞ²)	Post-hoc analysis test (only significant results)				Difference^*	95% CI for Difference^*		% Change
CBT Task	EEG channel	Test time	Frequency band	ANOVA (p-value)	Effect size (ƞ²)	Test condition	Mean	SD	(p-value)	Difference^*	L	U	% Change
VOLT	O1	Mr1	delta/alpha1	0.04	0.24	CEC	5.80	4.57	0.03	-3.25	-6.21	-0.29	-56.08%
			delta/alpha1	0.04	0.24	CEO	2.55	1.08	0.03	-3.25	-6.21	-0.29	-56.08%
			delta/alpha2	0.04	0.24	CEC	6.55	5.05	0.03	-3.77	-7.19	-0.36	-57.58%
			delta/alpha2	0.04	0.24	CEO	2.77	1.15	0.03	-3.77	-7.19	-0.36	-57.58%
			delta/theta2	0.03	0.26	CEC	4.20	2.94	0.03	-2.06	-3.97	-0.15	-49.02%
						CEO	2.14	0.78	0.03	-2.06	-3.97	-0.15	-49.02%
						CEC	4.20	2.94	0.04	-2.12	-4.18	-0.05	-50.45%
						YN2W	2.08	0.50	0.04	-2.12	-4.18	-0.05	-50.45%
			Theta1(4-6Hz)	0.01	0.33	CEO	0.12	0.02	0.01	0.04	0.01	0.07	33.05%
						YN2W	0.16	0.03	0.01	0.04	0.01	0.07	33.05%
						YN1W	0.11	0.02	0.01	0.05	0.01	0.08	39.82%
						YN2W	0.16	0.03	0.01	0.05	0.01	0.08	39.82%
			Theta2(6-8Hz)	0.02	0.29	CEC	0.07	0.03	0.03	0.04	0.00	0.07	55.07%
						YN2W	0.11	0.02	0.03	0.04	0.00	0.07	55.07%
						YN1W	0.07	0.02	0.05	0.03	0.00	0.07	44.60%
						YN2W	0.11	0.02	0.05	0.03	0.00	0.07	44.60%
			theta2/alpha2	0.02	0.28	CEO	1.33	0.44	0.02	0.73	0.08	1.38	54.78%
			theta2/alpha2	0.02	0.28	YN2W	2.06	0.80	0.02	0.73	0.08	1.38	54.78%
		PL	Theta2(6-8Hz)	0.03	0.30	CEO	0.08	0.02	0.02	0.03	0.00	0.05	37.33%
		PL	Theta2(6-8Hz)	0.03	0.30	YN2W	0.10	0.02	0.02	0.03	0.00	0.05	37.33%
	C3	Mr2	Theta2(6-8Hz)	0.04	0.26	CEC	0.06	0.02	0.04	0.04	0.00	0.08	72.73%
	C3	Mr2	Theta2(6-8Hz)	0.04	0.26	YN1W	0.10	0.04	0.04	0.04	0.00	0.08	72.73%
BART	O1	Mr2	delta/beta	0.03	0.27	CEC	0.95	0.46	0.04	1.11	0.04	2.18	116.72%
						YN2W	2.06	1.28	0.04	1.11	0.04	2.18	116.72%
						CEO	0.95	0.50	0.03	1.11	0.09	2.13	117.34%
						YN2W	2.06	1.28	0.03	1.11	0.09	2.13	117.34%
PVT	O1	Mr2	Theta2(6-8Hz)	0.02	0.28	CEO	0.07	0.02	0.04	0.03	0.00	0.05	38.03%
PVT	O1	Mr2	Theta2(6-8Hz)	0.02	0.28	YN1W	0.10	0.03	0.04	0.03	0.00	0.05	38.03%
ERT	F3	PL	delta/alpha1	0.02	0.34	CEC	4.51	1.48	0.03	5.75	0.57	10.90	127.61%
			delta/alpha1	0.02	0.34	YN1W	10.26	5.90	0.03	5.75	0.57	10.90	127.61%
			delta/alpha2	0.02	0.34	CEC	6.41	2.64	0.04	8.93	0.48	17.40	139.25%
						YN1W	15.35	10.09	0.04	8.93	0.48	17.40	139.25%
						CEO	6.61	3.54	0.03	8.73	0.53	16.90	132.01%
						YN1W	15.35	10.09	0.03	8.73	0.53	16.90	132.01%
			delta/theta1	0.03	0.32	CEC	1.74	0.22	0.03	0.49	0.04	0.93	28.04%
			delta/theta1	0.03	0.32	YN1W	2.22	0.39	0.03	0.49	0.04	0.93	28.04%
			delta/theta2	0.03	0.32	CEC	3.08	0.64	0.03	2.27	0.17	4.37	73.75%
			delta/theta2	0.03	0.32	YN1W	5.35	2.18	0.03	2.27	0.17	4.37	73.75%
			Theta1/alpha2	0.03	0.31	CEO	3.44	1.42	0.04	3.31	0.09	6.53	96.22%
			Theta1/alpha2	0.03	0.31	YN1W	6.75	3.81	0.04	3.31	0.09	6.53	96.22%
LOT	F3	PL	Delta/theta1	0.03	0.31	CEC	1.82	0.46	0.05	0.53	0.00	1.05	29.14%
LOT	F3	PL	Delta/theta1	0.03	0.31	YN1W	2.35	0.23	0.05	0.53	0.00	1.05	29.14%
MPT	C3	Mr2	Theta1(4-6Hz)	0.03	0.29	CEC	0.07	0.03	0.02	0.05	0.01	0.09	75.39%
MPT	C3	Mr2	Theta1(4-6Hz)	0.03	0.29	YN1W	0.11	0.02	0.02	0.05	0.01	0.09	75.39%
MRT	C3	Mr1	Delta/beta	0.04^$	0.20	CEC	1.67	0.37	0.05^$	-0.74	-1.29	-0.18	-44.16%
MRT	C3	Mr1	Delta/beta	0.04^$	0.20	CEO	0.93	0.42	0.05^$	-0.74	-1.29	-0.18	-44.16%

Open in a new tab

Note. One-way ANOVA model was used for checking significant change and post-hoc analysis is done using Tukey post hoc test except at $ where Kruskal Wallis test was used and post-hoc analysis is done using Wilcoxon test. Effect size was calculated using generalized eta-squared (ƞ²), where ƞ² < 0.06 (small effect), 0.06 ≤ ƞ² < 0.14 (medium effect), and ƞ² ≥ 0.14 (large effect).VOLT: Visual Object Learning Task, BART: Balloon Analog Risk Task, PVT: Psychomotor Vigilance Task, ERT: Emotion Recognition Task, LOT: Line Orientation Task, MPT: Motor Praxis Task, MRT: Matrix Reasoning Task, CEO: Control with Eyes Open, CEC: Control with Eyes Close, YN1W: At the end of one week of Yoga nidra practice after training, YN2W: At the end of two weeks of Yoga nidra practice after training·, Mr1: Test just before CEC, CEO, YN1W or YN2W, Mr2: Tests conducted just after CEO, CEC, YN1W or YN2W, PL: Tests conducted after the lunch.

*Difference is calculated as difference between two PSD parameters of two test conditions given in ‘Test Condition’ column, CI: Confidence interval, L: Lower limit, U: Upper limit.

The study highlights the important effect of yoga nidra practice on cognitive processing. However, this study demonstrates the effect of only two weeks of yoga nidra practice. Another drawback is the limited number of EEG locations used for analysis of cognitive tests. This pilot study was done using a pre-post intervention design to analyze the effects of this practice in novices and no active control groups were taken in this study. Though this study discusses the effect of practice as a pre-post intervention design, but studies with a larger sample, active control groups, longer exposure to yoga nidra, several EEG locations, and a randomized controlled trial may give a better perspective in analyzing the effects of this practice on cognitive processing. This study opens up an opportunity for the use of an easy-to-do practice of yoga nidra for population health using standardized supervised model [8,14, 41]. The study highlights the possible role of this practice in improving sleep and in promoting learning and memory amongst healthy participants. It might hold promise for patients with mild learning disability and mild cognition deterioration and possibly in its prevention specially in the aging population [42]. In the post-pandemic times, sleep is commonly found to be affected, which creates a risk of multiple disorders including neuropsychiatric disorders [43]. Planning large population based studies of different cultures [5] may also help assess its effects on insomnia globally. It has an immense role in improving sleep of the population at large and might be a way ahead for improving productivity at workplace [44]. An increased awareness of sleep problems and their management amongst primary healthcare physicians is vital [45]. Yoga nidra practice using formulated guidelines might ensure wellbeing of the society as it emerges from the effects of pandemic [41].

Supporting information

S1 Fig. Cognitive Testing Battery Results Showing Accuracy Measure (Mean (SD)) in (A)MPT, (B)VOLT, (C)NBACK, (D)AIM, (E)LOT, (F)ERT, (G)MRT, (H)DSST, and (I)PVT with Test Condition Wise Comparison.

(Comparison model for each test condition i.e. CEC, CEO, YN1W, and YN2W is shown below each time i.e. Mr1, Mr2, and PL. Significant post-hoc p-values are also depicted) #: One-Way Repeated Measure (RM) Analysis of Variance (ANOVA) p-values $: Post-hoc analysis (pairwise comparison) is done using paired t-test with Bonferroni correction (significant changes indicated by p-values given above the bars). @: Friedman’s test p-value (if data is not normally distributed) &: Post-hoc analysis (pairwise comparison) is done using Wilcoxon Signed-Rank test with Bonferroni correction (significant changes indicated by p-values given above the bars). Mr1: Test just before CEC, CEO, YN1W or YN2W Mr2: Tests conducted just after CEO, C EC, YN1W or YN2W PL: Test conducted after the lunch CEO: Control with Eyes Open CEC: Control with Eyes Close YN1W: At the end of one week of Yoga Nidra practice after training YN2W: At the end of two weeks of Yoga Nidra practice after training.

(TIF)

Click here for additional data file.^{(712.7KB, tif)}

S2 Fig. Cognitive Testing Battery Results Showing Accuracy Measure (Mean (SD)) in (A)MPT, (B)VOLT, (C)NBACK, (D)AIM, ILOT, (F)ERT, (G)MRT, (H)DSST, and (I)PVT with Time Wise Comparison.

(TIF)

Click here for additional data file.^{(743KB, tif)}

S3 Fig. BART results (Mean (SD)) of A) Adjusted Number of Pumps, B) Total cash collected ($), C) Risk Propensity, and D) Number of Balloons Burst Before (baseline) and After (post-intervention) Yoga Nidra Practice Test Condition Wise.

(P-values for time wise and test condition wise comparison model is shown below i.e. for Mr1, Mr2, and PL; and CEC, CEO, YN1W, and YN2W respectively. Significant post-hoc p-values are also depicted) Notes- #: One-Way Repeated Measure (RM) Analysis of Variance (ANOVA) p-values, $: Post-hoc analysis (pairwise comparison) is done using paired t-test with Bonferroni correction (significant changes indicated by p-values given above the bars)., @: Friedman’s test p-value (if data is not normally distributed), &: Post-hoc analysis (pairwise comparison) is done using Wilcoxon Signed-Rank test with Bonferroni correction (significant changes indicated by p-values given above the bars). Mr1: Test just before CEC, CEO, YN1W or YN2W Mr2: Tests conducted just after CEO, C EC, YN1W or YN2W PL: Test conducted after the lunch CEO: Control with Eyes Open CEC: Control with Eyes Close YN1W: At the end of one week of Yoga Nidra practice after training YN2W: At the end of two weeks of Yoga Nidra practice after training.

(TIF)

Click here for additional data file.^{(645.1KB, tif)}

S4 Fig. BART results (Mean (SD)) of A) Adjusted Number of Pumps, B) Total cash collected ($), C) Risk Propensity, and D) Number of Balloons Burst Time Wise Before (baseline) and After (post-intervention) Yoga Nidra Practice.

(P-values for time wise and test condition wise comparison model is shown below i.e., for Mr1, Mr2, and PL; and CEC, CEO, YN1W, and YN2W respectively. Significant post-hoc p-values are also depicted). Notes- #: One-Way Repeated Measure (RM) Analysis of Variance (ANOVA) p-values, $: Post-hoc analysis (pairwise comparison) is done using paired t-test with Bonferroni correction (significant changes indicated by p-values given above the bars)., @: Friedman’s test p-value (if data is not normally distributed), &: Post-hoc analysis (pairwise comparison) is done using Wilcoxon Signed-Rank test with Bonferroni correction (significant changes indicated by p-values given above the bars). Mr1: Test just before CEC, CEO, YN1W or YN2W Mr2: Tests conducted just after CEO, C EC, YN1W or YN2W. PL: Test conducted after the lunch CEO: Control with Eyes Open. CEC: Control with Eyes Close YN1W: At the end of one week of Yoga Nidra practice after training. YN2W: At the end of two weeks of Yoga Nidra practice after training.

(TIF)

Click here for additional data file.^{(671.3KB, tif)}

S5 Fig. PVT-Number of False Starts (Mean (SD)) of Participants Before (baseline) and After (post-intervention) Yoga Nidra Practice Comparison in Test Condition wise (6(A)) and Time wise (6(B)).

Comparison model for each test condition i.e. CEC, CEO, YN1W, and YN2W is shown below each time i.e. Mr1, Mr2, and PL. Significant post-hoc p-values are also depicted.

(TIF)

Click here for additional data file.^{(334.4KB, tif)}

S1 File

(ZIP)

Click here for additional data file.^{(1.9MB, zip)}

S1 Table. Demographic profile of participants.

(XLSX)

Click here for additional data file.^{(11.6KB, XLSX)}

S2 Table. Cognitive Testing Battery (CTB) parameters (Mean (SD)) of all tests in the participants.

(DOCX)

Click here for additional data file.^{(29.9KB, DOCX)}

S3 Table. Emotion Recognition Task (ERT) Emotion-wise Analysis of Accuracy.

(DOCX)

Click here for additional data file.^{(19.8KB, docx)}

Acknowledgments

Authors thank the study participants for their time and the lab staff for their support in conducting the study. Authors also thank Dr CV Apte for reviewing the manuscript.

Data Availability

All relevant data are within the paper and its Supporting information files.

Funding Statement

KD received the funding from Department of Science and Technology under Science and Technology for Yoga and Meditation (SATYAM), India available at https://dst.gov.in/, and was received vide their sanction order DST Satyam 2018/457 dated 28 May 2020. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

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PLoS One. doi: 10.1371/journal.pone.0294678.r001

Decision Letter 0

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PONE-D-23-21201Improved Sleep, Cognitive Processing and Enhanced Learning and Memory Task Accuracy with Yoga Nidra Practice in NovicesPLOS ONE

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“Authors acknowledge Department of Science and Technology, Government of India for financial support vide Reference No. DST Satyam 2018/457 dated 28 May 2020 under Science and Technology for Yoga and Meditation (SATYAM) to carry out this work. Authors thank Dr CV Apte for reviewing the manuscript and thank the participants and staff for the support in conducting the study.”

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Comments to the Author

1. Is the manuscript technically sound, and do the data support the conclusions?

The manuscript must describe a technically sound piece of scientific research with data that supports the conclusions. Experiments must have been conducted rigorously, with appropriate controls, replication, and sample sizes. The conclusions must be drawn appropriately based on the data presented.

Reviewer #1: Partly

Reviewer #2: Partly

Reviewer #3: Yes

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2. Has the statistical analysis been performed appropriately and rigorously?

Reviewer #1: N/A

Reviewer #2: I Don't Know

Reviewer #3: Yes

**********

3. Have the authors made all data underlying the findings in their manuscript fully available?

The PLOS Data policy requires authors to make all data underlying the findings described in their manuscript fully available without restriction, with rare exception (please refer to the Data Availability Statement in the manuscript PDF file). The data should be provided as part of the manuscript or its supporting information, or deposited to a public repository. For example, in addition to summary statistics, the data points behind means, medians and variance measures should be available. If there are restrictions on publicly sharing data—e.g. participant privacy or use of data from a third party—those must be specified.

Reviewer #1: Yes

Reviewer #2: Yes

Reviewer #3: No

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4. Is the manuscript presented in an intelligible fashion and written in standard English?

PLOS ONE does not copyedit accepted manuscripts, so the language in submitted articles must be clear, correct, and unambiguous. Any typographical or grammatical errors should be corrected at revision, so please note any specific errors here.

Reviewer #1: No

Reviewer #2: No

Reviewer #3: Yes

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5. Review Comments to the Author

Please use the space provided to explain your answers to the questions above. You may also include additional comments for the author, including concerns about dual publication, research ethics, or publication ethics. (Please upload your review as an attachment if it exceeds 20,000 characters)

Reviewer #1: Dear authors, thank you for the possibility to review this very interesting paper. I find it very relevant for publication as objective parameters of testing always expand knowledge of subjective questionnaires. Yet, there are some remarks I would find really important to add before publication as they would strengthen the scientific standards of your work:

Please report effect sizes, at abstract as well as at result’s section. Please discuss the very important limitation of not using an active control group as literature suggests the effects could also occur through other positive interventions. Also please discuss thoroughly why you exclude women and state this as limitation. I would find it very helpful to have an extra section strengths and limitations at an extra discussion’s section and not mixed at results’ section.

Please make clear why you decide to not call it yoga nidra meditation as a lot of other literature would do so.

There are some small spelling mistakes I have marked at the document attached. There are also some sections where there are words missing to complete a sentence or when a technical term needs to be explained for the reader's better understanding. I wouldn't use that many statistical values at abstract but rather state very clear your results and effects sizes / meaningfulness. Also state limitations as an outlook here.

Please consider APA guidelines for table e.g. table 1 and use dois for your literature section whereever possible.

All the best!

Reviewer #2: Although this manuscript reflects a great amount of work and important findings, there are a number of glaring omissions that significantly reduce my enthusiasm for this study because a reviewer is unable to adequately gauge its methodological rigor.

1. The English used is sub-standard and negatively affects readability. The manuscript needs a thorough review for grammatical issues.

2. The authors assume a familiarity with the yoga nidra technique and some of the methodological details of the study that appears unwarranted and makes it difficult to evaluate. For example, how is yoga nidra different from other yoga and meditative techniques? What did supervised training consist of?

3. No validity data is given for the cognitive and sleep outcome measures. Has research been conducted on the subtests of the CTB? Explain in more detail about the PSG and EEG measures and why they were specifically chosen to evaluate sleep in this study.

Reviewer #3: The paper offers a compelling exploration of the cognitive and sleep-related consequences of Yoga Nidra practice, with the intention of addressing a knowledge gap about the measurable outcomes of this particular practice. The novelty of the study comes in its investigation of a relatively unexplored element of the effects of Yoga Nidra. The manuscript exhibits the author's comprehension of pertinent scholarly works, citing the stress-reducing advantages of Yoga Nidra and its ability to enhance sleep quality. Nevertheless, it is imperative to incorporate citations to contemporary research papers that specifically examine the cognitive impacts of Yoga Nidra.

The study demonstrates a strong methodological framework, incorporating thorough evaluations of cognitive function and sleep patterns using a range of tasks and polysomnography techniques. The selected methodologies are in accordance with the aims of the study, and the statistical analysis provides evidence in favor of the stated outcomes. Nevertheless, it would be beneficial to improve methodological clarity by providing more comprehensive explanations of the cognition testing battery and EEG analysis methods.

The findings are presented in a manner that effectively demonstrates the observed enhancements in cognitive tasks and sleep parameters subsequent to the practice of Yoga Nidra. The conclusions reached are consistent with the findings and discussion of the study. The article demonstrates the significance it holds for future research and the integration of complementary and alternative medicine (CAM) practices into healthcare initiatives. However, further elaboration on the study's wider societal implications and potential limitations would augment the manuscript's comprehensiveness.

The text has a generally well-structured organization, while particular portions might benefit from more refinement to enhance overall readability. The linguistic style employed is inappropriate for a scholarly readership since it effectively presents the data analysis and findings in a manner that is not easily understood. In general, the paper provides significant insights into the impact of Yoga Nidra practice on cognition and sleep, thereby enhancing the comprehension of the potential advantages of complementary and alternative medicine (CAM) techniques. In order to enhance the quality of the paper, it is suggested that a more thorough incorporation of contemporary scholarly works be undertaken, along with certain modifications to improve the clarity of the methodology and the explanation of the consequences. Authors are requested in their discussion to include the following references: https://doi.org/10.3390/bioengineering10020249, https://cdn.techscience.cn/files/jnm/2023/TSP_JNM-5-1/TSP_JNM_37583/TSP_JNM_37583.pdf

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Reviewer #1: No

Reviewer #2: No

Reviewer #3: No

**********

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Attachment

Submitted filename: PONE-D-23-21201 Rev.pdf

Click here for additional data file.^{(2.3MB, pdf)}

PLoS One. 2023 Dec 13;18(12):e0294678. doi: 10.1371/journal.pone.0294678.r002

Author response to Decision Letter 0

27 Sep 2023

Dear Editor,

The response to reviewer's comments letter has been uploaded with the re-submission.

Regards

Attachment

Submitted filename: plosResponse to Reviewer.docx

Click here for additional data file.^{(16.6KB, docx)}

PLoS One. doi: 10.1371/journal.pone.0294678.r003

Decision Letter 1

Kallol Kumar Bhattacharyya

16 Oct 2023

PONE-D-23-21201R1Improved Sleep, Cognitive Processing and Enhanced Learning and Memory Task Accuracy with Yoga Nidra Practice in NovicesPLOS ONE

Dear Dr. Datta,

==============================

A few additional minor revisions requested. We are getting closer.

==============================

Please submit your revised manuscript by Nov 30 2023 11:59PM. If you will need more time than this to complete your revisions, please reply to this message or contact the journal office at plosone@plos.org. When you're ready to submit your revision, log on to https://www.editorialmanager.com/pone/ and select the 'Submissions Needing Revision' folder to locate your manuscript file.

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We look forward to receiving your revised manuscript.

Kind regards,

Kallol Kumar Bhattacharyya, MBBS MA PhD

Academic Editor

PLOS ONE

Journal Requirements:

Please review your reference list to ensure that it is complete and correct. If you have cited papers that have been retracted, please include the rationale for doing so in the manuscript text, or remove these references and replace them with relevant current references. Any changes to the reference list should be mentioned in the rebuttal letter that accompanies your revised manuscript. If you need to cite a retracted article, indicate the article’s retracted status in the References list and also include a citation and full reference for the retraction notice.

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Reviewers' comments:

Reviewer's Responses to Questions

Comments to the Author

1. If the authors have adequately addressed your comments raised in a previous round of review and you feel that this manuscript is now acceptable for publication, you may indicate that here to bypass the “Comments to the Author” section, enter your conflict of interest statement in the “Confidential to Editor” section, and submit your "Accept" recommendation.

Reviewer #1: All comments have been addressed

Reviewer #3: All comments have been addressed

**********

2. Is the manuscript technically sound, and do the data support the conclusions?

Reviewer #1: Yes

Reviewer #3: Yes

**********

3. Has the statistical analysis been performed appropriately and rigorously?

Reviewer #1: Yes

Reviewer #3: Yes

**********

4. Have the authors made all data underlying the findings in their manuscript fully available?

Reviewer #1: Yes

Reviewer #3: Yes

**********

5. Is the manuscript presented in an intelligible fashion and written in standard English?

Reviewer #1: Yes

Reviewer #3: No

**********

6. Review Comments to the Author

Reviewer #1: Dear author, thank you for your remarks.

- statistical abbreviations have to be italic (APA)

- lines 57-59, this is not precise, one part of yn is pratyahara but not all of it, and there are studies that highlight alpha waves !

- line 68/69, there is the same source two times, online first and print versions are the same. please doublecheck your literature if there are more doubles like this

- line 70, there are two dots. Also at 273

- 84 ff important information has always to appear also at running text, e.g. how many males took part in this study; 89 ff how long was the yn

- did you perform a power analysis to find out about the sufficient sample size for your study? please report about the power of your study, at least at discussion's section about strengths/weaknesses - there ist still missing a comment on the value of active control groups!

- line 180 (also 248) numbers are written as numbers when above 10 (APA); how many is "some"?

- why do you report different effect sizes? d, r and eta - please either choose one or explain why you choose three and differentiate the thresholds of small, medium, big either way

Thank you and kind regards

Reviewer #3: The article is well written. all technical comments were included in the revised version. A proper English review is requested before publication.

**********

7. PLOS authors have the option to publish the peer review history of their article (what does this mean?). If published, this will include your full peer review and any attached files.

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Reviewer #1: No

Reviewer #3: No

**********

PLoS One. 2023 Dec 13;18(12):e0294678. doi: 10.1371/journal.pone.0294678.r004

Author response to Decision Letter 1

21 Oct 2023

Dear Reviewers,

Thanks for your comments and the journal office email dated 16 Oct regarding revision in the submitted manuscript.

The response to reviewers dated 21 Oct 2023 has been uploaded and necessary modifications done in the revised manuscript.

Regards

Karuna Datta

Attachment

Submitted filename: plosResponse to Reviewer1 (1).docx

Click here for additional data file.^{(17.2KB, docx)}

PLoS One. doi: 10.1371/journal.pone.0294678.r005

Decision Letter 2

Kallol Kumar Bhattacharyya

7 Nov 2023

Improved Sleep, Cognitive Processing and Enhanced Learning and Memory Task Accuracy with Yoga Nidra Practice in Novices

PONE-D-23-21201R2

Dear Dr. Datta,

We’re pleased to inform you that your manuscript has been judged scientifically suitable for publication and will be formally accepted for publication once it meets all outstanding technical requirements.

Within one week, you’ll receive an e-mail detailing the required amendments. When these have been addressed, you’ll receive a formal acceptance letter and your manuscript will be scheduled for publication.

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Kind regards,

Kallol Kumar Bhattacharyya, MBBS MA PhD

Academic Editor

PLOS ONE

Additional Editor Comments (optional): As the reviewer suggested, please write consistently yoga nidra, not yoga-nidra during proofreading or when submitting your final version of the manuscript.

Reviewers' comments:

Reviewer's Responses to Questions

Comments to the Author

Reviewer #1: All comments have been addressed

**********

2. Is the manuscript technically sound, and do the data support the conclusions?

Reviewer #1: Yes

**********

3. Has the statistical analysis been performed appropriately and rigorously?

Reviewer #1: Yes

**********

4. Have the authors made all data underlying the findings in their manuscript fully available?

Reviewer #1: Yes

**********

5. Is the manuscript presented in an intelligible fashion and written in standard English?

Reviewer #1: Yes

**********

6. Review Comments to the Author

Reviewer #1: - Please write consistently yoga nidra, not yoga-nidra

- Please double check your literature and add “dois” whereever available

**********

7. PLOS authors have the option to publish the peer review history of their article (what does this mean?). If published, this will include your full peer review and any attached files.

If you choose “no”, your identity will remain anonymous but your review may still be made public.

Do you want your identity to be public for this peer review? For information about this choice, including consent withdrawal, please see our Privacy Policy.

Reviewer #1: No

**********

PLoS One. doi: 10.1371/journal.pone.0294678.r006

Acceptance letter

Kallol Kumar Bhattacharyya

20 Nov 2023

PONE-D-23-21201R2

Improved Sleep, Cognitive Processing and Enhanced Learning and Memory Task Accuracy with Yoga Nidra Practice in Novices

Dear Dr. Datta:

I'm pleased to inform you that your manuscript has been deemed suitable for publication in PLOS ONE. Congratulations! Your manuscript is now with our production department.

If your institution or institutions have a press office, please let them know about your upcoming paper now to help maximize its impact. If they'll be preparing press materials, please inform our press team within the next 48 hours. Your manuscript will remain under strict press embargo until 2 pm Eastern Time on the date of publication. For more information please contact onepress@plos.org.

If we can help with anything else, please email us at customercare@plos.org.

Thank you for submitting your work to PLOS ONE and supporting open access.

Kind regards,

PLOS ONE Editorial Office Staff

on behalf of

Dr. Kallol Kumar Bhattacharyya

Academic Editor

PLOS ONE

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

S1 Fig. Cognitive Testing Battery Results Showing Accuracy Measure (Mean (SD)) in (A)MPT, (B)VOLT, (C)NBACK, (D)AIM, (E)LOT, (F)ERT, (G)MRT, (H)DSST, and (I)PVT with Test Condition Wise Comparison.

(TIF)

Click here for additional data file.^{(712.7KB, tif)}

S2 Fig. Cognitive Testing Battery Results Showing Accuracy Measure (Mean (SD)) in (A)MPT, (B)VOLT, (C)NBACK, (D)AIM, ILOT, (F)ERT, (G)MRT, (H)DSST, and (I)PVT with Time Wise Comparison.

(TIF)

Click here for additional data file.^{(743KB, tif)}

(TIF)

Click here for additional data file.^{(645.1KB, tif)}

(TIF)

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S5 Fig. PVT-Number of False Starts (Mean (SD)) of Participants Before (baseline) and After (post-intervention) Yoga Nidra Practice Comparison in Test Condition wise (6(A)) and Time wise (6(B)).

Comparison model for each test condition i.e. CEC, CEO, YN1W, and YN2W is shown below each time i.e. Mr1, Mr2, and PL. Significant post-hoc p-values are also depicted.

(TIF)

Click here for additional data file.^{(334.4KB, tif)}

S1 File

(ZIP)

Click here for additional data file.^{(1.9MB, zip)}

S1 Table. Demographic profile of participants.

(XLSX)

Click here for additional data file.^{(11.6KB, XLSX)}

S2 Table. Cognitive Testing Battery (CTB) parameters (Mean (SD)) of all tests in the participants.

(DOCX)

Click here for additional data file.^{(29.9KB, DOCX)}

S3 Table. Emotion Recognition Task (ERT) Emotion-wise Analysis of Accuracy.

(DOCX)

Click here for additional data file.^{(19.8KB, docx)}

Attachment

Submitted filename: PONE-D-23-21201 Rev.pdf

Click here for additional data file.^{(2.3MB, pdf)}

Attachment

Submitted filename: plosResponse to Reviewer.docx

Click here for additional data file.^{(16.6KB, docx)}

Attachment

Submitted filename: plosResponse to Reviewer1 (1).docx

Click here for additional data file.^{(17.2KB, docx)}

Data Availability Statement

All relevant data are within the paper and its Supporting information files.

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Improved sleep, cognitive processing and enhanced learning and memory task accuracy with Yoga nidra practice in novices

Karuna Datta

Anna Bhutambare

Mamatha V L

Yogita Narawa

Rajagopal Srinath

Madhuri Kanitkar

Roles

Abstract

1. Introduction

2. Methods

2.1 Study design and participants

Fig 1. Study Design for Effect of Yoga Nidra Practice on Cognitive Function (Fig 1A) and on Objective Sleep Parameters (Fig 1B).

2.2 Screening of participants & enrollment

2.3 Intervention: Yoga nidra practice

2.4 Sleep Diary (SD) analysis

2.5 Methodology for assessing the effect of yoga nidra practice on cognitive function

2.6 Power spectral density (PSD) of EEG daytime recording during CTB

2.7 Methodology for assessing the effect of yoga nidra practice on objective sleep parameters

3. Results and discussion

Fig 2. Details of the participants screened and finally analyzed.

Table 1. Sleep diary parameters of participants before (baseline) and after four weeks of Yoga nidra practice (post intervention) after training.

Fig 3. Comparison of objective sleep parameters using polysomnography in participants before (baseline) and after (post intervention) Yoga Nidra Practice.

Fig 4. Cognitive Testing Battery Results Showing Reaction Time (Mean (SD)) in (A)MPT, (B)VOLT, (C)NBACK, (DIM, (E)LOT, (F)ERT, (G)MRT, (H)DSST, (I)BART, and (J)PVT with Test Condition Wise Comparison.

Fig 5. Cognitive Testing Battery Results Showing Reaction Time (Mean (SD)) in (A)MPT, (B)VOLT, (C)NBACK,I)AIM, (E)LOT, (F)ERT, (G)MRT, (H)DSST, (I)BART, and (J)PVT with Time Wise Comparison.

Table 2. EEG PSD significant results in frequency bands during CTB at various EEG locations.

Supporting information

Acknowledgments

Data Availability

Funding Statement

References

Decision Letter 0

Kallol Kumar Bhattacharyya

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Author response to Decision Letter 0

Decision Letter 1

Kallol Kumar Bhattacharyya

Roles

Author response to Decision Letter 1

Decision Letter 2

Kallol Kumar Bhattacharyya

Roles

Acceptance letter

Kallol Kumar Bhattacharyya

Roles

Associated Data

Supplementary Materials

Data Availability Statement

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