This study evaluated the effects of inspiratory muscle training (IMT) on inspiratory muscle fatigue (IMF) and physiological and perceptual responses during trekking-specific exercise. An 8-week IMT program was completed by 21 males (age 32.4 ± 9.61 years, VO2peak 58.8 ± 6.75 mL/kg/min) randomised within matched pairs to either the IMT group (n = 11) or the placebo group [(P), n = 9]. Twice daily, participants completed 30 (IMT) or 60 (P) inspiratory efforts using a Powerbreathe initially set at a resistance of 50% (IMT) or used at 15% (P) of maximal inspiratory pressure (MIP) throughout. A loaded (12.5 kg) 39-minute incremental walking protocol (3–5 km/hour and 1–15% gradient) was completed in normobaric hypoxia (PIO2 = 110 mmHg, 3000 m) before and after training. MIP increased from 164 to 188 cmH2O (18%) and from 161 to 171 cmH2O (6%) in the IMT and P groups (P = 0.02). The 95% CI for IMT showed a significant improvement in MIP (5.21±43.33 cmH2O), but not for P. IMF during exercise (MIP) was*5%, showing no training effect for either IMT or P (P = 0.23). Rating of perceived exertion (RPE) was consistently reduced (*1) throughout exercise following training for IMT, but not for P (P = 0.03). The mean blood lactate concentration during exercise was significantly reduced by 0.26 and 0.15 mmol/L in IMT and P (P = 0.00), with no differences between groups (P = 0.34). Rating of dyspnoea during exercise decreased (*0.4) following IMT but increased (*0.3) following P (P = 0.01). IMT may attenuate the increased physiological and perceived exercise stress experienced during normobaric hypoxia, which may benefit moderate altitude expedition

Bartesaghi, M

Celegato, Barbara

Giardini, G

Lanfranchi, Gerolamo

Laveder, Paolo

Malacrida, S

Millino, Caterina

Pacchioni, Beniamina

Pratali, L

English

Seims, A

O'Hara, J

King, R

Cooke, CB

Leeds Beckett Repository

Inspiratory muscle training and its effect on indices of physiological and perceived stress during incremental walking exercise in normobaric hypoxia Amanda L. Seims, John P. O’Hara, Roderick, F.G.J. King and Carlton B. Cooke. Introduction Methods Findings Conclusions  References  The elevated ventilation and reduced O2 supply in hypoxia increases RB, RPE and BLa during exercise and exacerbates IMF, shown as a reduction in force output of the inspiratory muscles (1). IMF triggers the inspiratory metaboreflex which reduces limb blood flow (2) and may further increase BLa and intensify RPE (1). Reducing IMF can prolong exercise time to exhaustion in hypoxia and reduce RB and RPE (1). Increased inspiratory muscle strength (MIP) following IMT has been shown to attenuate IMF and the metaboreflex (3). Four weeks of IMT  significantly increased MIP by ~25% and reduced IMF by 10% and  RPE and RB by 13% during high-intensity running to fatigue in normobaric hypoxia [FIO2 = 14%,  3200 m (4)].  IMT may benefit trekking expeditions at moderate altitude, but this has not been evaluated in controlled conditions of hypoxia using  trekking specific exercise AIM: To evaluate the effects of inspiratory muscle training (IMT) on inspiratory muscle fatigue (IMF), blood lactate concentration (BLa), rating of perceived exertion (RPE) and rating of breathlessness (RB) during trekking specific exercise completed in moderate hypoxia (3000 m) MIP         Not different between groups (P=0.319)   95% CI P: -3.98 to 24.7 cmH2O IMT: +5.21 to 43.3 cmH2O 17.6 ± 30.1% P IMT 6.20 ± 15.6% IMT may attenuate increased RPE during walking exercise in moderate hypoxia. This may benefit expeditions completed at moderate altitude (~3000 m). The effect of IMT on BLa and RB may be enhanced with severe hypoxia and/or sustained  moderate intensity walking exercise where inspiratory fatigue is likely greater.   No IMT effects in NORM exercise Matched on baseline MIP, randomised to IMT (n=11) or placebo (P, n=9)   Eight weeks, twice daily IMT: 30 efforts @ 50% MIP P: 60 efforts @ 15% MIP Participants: 21 males (age 32.4 ± 9.61 years, V O2peak 58.8 ± 6.75 ml.kg-1.min-1)  Exercise Protocol:  39-min incremental walking exercise (3-min stages), starting at 3 km.hr-1 (1% gradient), increasing to finish on 5 km.hr-1 (16% gradient). Performed in normoxia (NORM) and hypoxia [HYP, (FIO2 ~14.5%, 3000 m altitude)]. BLa, RPE and RB measured every 3 min.  IMF = pre to post exercise decrease in MIP Repeat exercise protocol     PRE: ~5%  ↓ in MIP (P=0.000), for both groups in HYP POST: No significant change (P=0.23) IMF (1) Amman et al. (2007) Inspiratory muscle work in acute hypoxia influences locomotor muscle fatigue and exercise performance of healthy humans. Am. J. Physiol. Regul.Integr.Comp. Physiol., 293, R2036-R2045 (2) Harms et al. (1997) Respiratory muscle work compromises leg blood flow during maximal exercise. Respiratory muscle work compromises leg blood flow during maximal exercise. J. Appl. Physiol., 82, 1573 – 1583 (3) McConnell and Lomax (2006) The influence of inspiratory muscle work history and specific inspiratory muscle training upon human limb muscle fatigue.  J. of Physiol., 577.1, 445-457. (4) Downey et al. (2007) Effects of inspiratory muscle training on exercise responses in normoxia and hypoxia. Respir. Physiol .Neurobiol., 2, 137-146.  RPE: sig. interaction (P=0.03). Sig. ↓ post IMT (P=0.013)  RB: sig. group interaction post training (P=0.01)  BLa: no group interaction post training (P=0.338)   3 6 9 12 15 18 21 24 27 30 33 36 39Time (minutes) ↓ 0.15 ±0.43 mmol.L-1 0123453 6 9 12 15 18 21 24 27 30 33 36 39Time (minutes) BLa  (mmol. L-1) -1012345678RB (scale units) 4681012141618RPE (scale units) PrePostIMT ↓ 1.05 ±1.64 RPE units PrePostSHAM ↓ 0.31 ±1.49 RPE units ↓ 0.26 ±0.48 mmol.L-1 ↓ 0.43 ±0.93 RB units ↑ 0.32 ±1.22 RB units Exercise in HYP (mean change) 

Effects of inspiratory muscle training on exercise responses in normoxia and hypoxia.

PRE: ~5% ↓ in MIP (P=0.000), for both groups in HYP POST: No significant change (P=0.23) IMF (1) Amman

Respiratory muscle work compromises leg blood flow during maximal exercise.

Inspiratory muscle training and its effect on indices of physiological and perceived stress during incremental walking exercise in normobaric hypoxia

Crossref

High Altitude Medicine & Biology

AbstractsX World Congress on High Altitude Medicine and Physiology &amp; Mountain Emergency Medicine<i>Hypoxia and Cold—From Science to Treatment</i>May 25–31, 2014Bozen/Bolzano, Italy

This study evaluated the effects of inspiratory muscle training (IMT) on inspiratory muscle fatigue (IMF) and physiological and perceptual responses during trekking-specific exercise. An 8-week IMT program was completed by 21 males (age 32.4 – 9.61 years, VO2peak 58.8 – 6.75 mL/kg/min) randomised within matched pairs to either the IMT group (n = 11) or the placebo group [(P), n = 9]. Twice daily, participants completed 30 (IMT) or 60 (P) inspiratory efforts using a Powerbreathe initially set at a resistance of 50% (IMT) or used at 15% (P) of maximal inspiratory pressure (MIP) throughout. A loaded (12.5 kg) 39-minute incremental walking protocol (3–5 km/hour and 1–15% gradient) was completed in normobaric hypoxia (PIO2 = 110 mmHg, 3000 m) before and after training. MIP increased from 164 to 188 cmH2O (18%) and from 161 to 171 cmH2O (6%) in the IMT and P groups (P = 0.02). The 95% CI for IMT showed a significant improvement in MIP (5.21–43.33 cmH2O), but not for P. IMF during exercise (MIP) was ~5%, showing no training effect for either IMT or P (P = 0.23). Rating of perceived exertion (RPE) was consistently reduced (~1) throughout exercise following training for IMT, but not for P (P = 0.03). The mean blood lactate concentration during exercise was significantly reduced by 0.26 and 0.15 mmol/L in IMT and P (P = 0.00), with no differences between groups (P = 0.34). Rating of dyspnea during exercise decreased (~0.4) following IMT but increased (~0.3) following P (P = 0.01). IMT may attenuate the increased physiological and perceived exercise stress experienced during normobaric hypoxia, which may benefit moderate altitude expeditions

LAVEDER, PAOLO

CELEGATO, BARBARA

PACCHIONI, BENIAMINA

MILLINO, CATERINA

LANFRANCHI, GEROLAMO

MALACRIDA S

GIARDINI G

PRATALI L

BARTESAGHI M

Archivio istituzionale della ricerca - Università di Padova

Human Genomics and Hypoxia Adaptive Response

The effects of inspiratory muscle training (IMT) were evaluated at rest and during exercise in normobaric hypoxia (NH) and then an 11-day trek to 5300m. A 7-week IMT program was completed by 6 females and 3 males (age 34.8 ± 10.0 years) randomized to IMT (n = 4) or placebo [P (n = 5)]. A Powerbreathe was initially set at a resistance of 50% (IMT) or used at 15%ofmaximal inspiratory pressure (MIP) throughout (P). A self-paced walking test was completed before and after training at PIO2 = 104.1mmHg, 3440m (NH1); PIO2 = 85.9 mmHg, 4930m (NH2); and at 3440m during the trek (HH). Exercise data were interpolated to 4.8 km/hour to evaluate training effects. Patterns of change suggest possible benefits of IMT, but due to small group sizes and variability, these trends are not significant. MIP increased by 6% and 4% following IMT and P. Pulse oxygen saturation (SaO2) during exercise in NH2 increased by*4% following IMT, with no change in P. Decreases in resting SaO2 during the expedition (4930m) were attenuated in IMT (85.0 ± 3.61%) compared to P (80.0 ± 5.87%). Comparisons between NH1 exercise post-training and HH showed a decrease in perceived dyspnoea and effort in IMT ( - 0.3 and - 0.7) but an increase in P ( + 0.7 and + 2.6). Nonsignificant trends within the data suggest that the altitude-induced decrease in resting and exercise SaO2 and intensified perceived effort and dyspnoea during exercise were attenuated following IMT. However, further research is required to establish any beneficial effect of IMT

Inspiratory muscle training and its effect on oxygen saturation and perceptions of effort and dyspnoea during a trek to Everest Base Camp Amanda L. Seims, John P. O’Hara, Roderick, F.G.J. King and Carlton B. Cooke.  Introduction Methods Findings Conclusions  References  Increasing ascent during high-altitude expeditions is typically associated with a significant 16% decrease in SaO2 and inspiratory muscle strength (MIP) which can exacerbate breathlessness (1). Weaker inspiratory muscles are associated with greater inspiratory muscle fatigue (2) which exacerbates physiological and perceived stress during exercise (3). IMT has been shown to attenuate the fall in MIP with ascent to 5050 m altitude and reduced breathlessness associated with daily activities (4). Resting SaO2 between 4800 and 5550 m altitude was 6% higher following  IMT compared to placebo, but RB at rest was not different between groups (5). Increased SaO2 during high-altitude expeditions following IMT may attenuate physiological and perceptual stress during exercise. AIM: To evaluate the effects of inspiratory muscle training (IMT) on oxygen saturation (SaO2), rating of perceived exertion (RPE) and rating of breathlessness (RB) during exercise in normobaric hypoxia (NH) and then an 11-day trek to 5300 m MIP        Not different between groups (P=0.887)   Completion of training P: 68.1 ± 16.7% IMT: 78.8 ± 13.5% (NS) 5.56 ± 8.34% P IMT 3.52 ± 9.84% IMT may attenuate the expected decrease in resting SaO2 with ascent to altitude above 4900 m similarly to previous research. Large variability and small sample sizes, along with sub-optimal completion of IMT may have negated the training response. Further research should evaluate effects of IMT on exercise SaO2 and other responses during trekking expeditions above 4900 m altitude. Supervised IMT may enhance the training response. No training effects in NORM Matched on baseline MIP, randomised to IMT (n=4) or placebo (P, n=5)   Seven weeks, twice daily IMT: 30 efforts @ 50% MP P: 60 efforts @ 15% MIP Participants: 3 M, 6 F (age 34.8 ± 10.0 years)  Exercise Protocol:  Bassey’s self-paced walking test was completed three times (slow, normal and fast) in normoxia (NORM) and twice in normobaric hypoxia [NH1 (PIO2 = 104.1 mmHg, 3440 m altitude) and NH2 (PIO2 = 85.9 mmHg, 4930 m altitude]. RPE, RB and SaO2 interpolated to 4.8 km.h-1).  Repeat exercise protocol   (1) Romer and McConnell (2000) Changes in respiratory muscle strength and endurance are significantly reduced at high altitude compared to sea-level. J. of Physiol., 523, 216-217. (2) McConnell, Caine and Sharpe (1997) Inspiratory muscle fatigue following running to volitional fatigue: the influence of baseline strength. Int. J. Sp. Med., 3, 169-173. (3) Amman et al. (2007) Inspiratory muscle work in acute hypoxia influences locomotor muscle fatigue and exercise performance of healthy humans. Am. J. Physiol. Regul. Integr. Comp. Physiol., 293, R2036-R2045 (4) Nickol et al. (2001) The effects of specific inspiratory muscle training upon respiratory muscle function and dyspnoea at high altitude. High Alt. Med. Biol., 2, 116 (5) Lomax (2010) Inspiratory muscle training, altitude, and arterial oxygen desaturation: a preliminary investigation, Aviat. Space Environ. Med.,  81, 498-501. No change in MIP at  3440 m Daily measurements of SaO2 MIP and repeat of exercise protocol at 3400 m altitude (HH). Expedition 96.7 85.0 92.3 95.0 80.0 90.8 707580859095100105D1(1373)D2(1373)D4(2800)D6(3440)D8(4240)D11(4240)D13(4930)D14(5140)D16(3820)D17(3440) Oxygen Saturation (%) IMTSHAM     D1           D2            D4           D6            D8           D11       D13          D14         D16          D17    (1373 )   (1373)       (2800)     (3440)      (4240)      (4240)     (4930)      (5140)     (3820)       (3440) KTM Expedition Trekking Days (N=3) Across exped: IMT = 91.4 ± 4.87%,  P = 89.3 ± 5.64%, (P=0.023) NS Exercise and Resting SaO2 Exercise RB, SaO2 and RPE in NH1 and HH (3400 m) RB: IMT (n=3): ↓ from NH1 pre-training to HH of 0.30 ± 0.60 RB units P: ↑ from NH1 pre-training to HH of 0.70 ± 1.50 RB units  RPE: IMT (n=3): ↓ from NH1 pre-training to HH of 0.67 ± 0.58 RPE units P: ↑ from NH1 pre-training to HH of 2.60 ± 2.41 RPE units  SaO2: No change across NH1 trials and HH for either group 88.373.383.870.487.077.084.470.460657075808590NH1 NH2 NH1 NH2Exercise SaO2(%) Pre PostIMT (N=3) SHAMNot different to P     NORMOBARIC HYPOXIA (LABORATORY) HYPOBARIC HYPOXIA (EXPEDITION) 

Exercise Protocol: Bassey’s self-paced walking test was completed three times (slow, normal and fast) in normoxia (NORM) and twice in normobaric hypoxia

Inspiratory muscle fatigue following running to volitional fatigue: the influence of baseline strength.

Inspiratory muscle work in acute hypoxia influences locomotor muscle fatigue and exercise performance of healthy humans.

No change in MIP at 3440 m Daily measurements of SaO2 MIP and repeat of exercise protocol at 3400 m altitude (HH).

Inspiratory muscle training and its effect on oxygen saturation and perceptions of effort and dyspnoea during a trek to Everest base camp.

The effects of inspiratory muscle training (IMT) were evaluated at rest and during exercise in normobaric hypoxia (NH) and then an 11-day trek to 5300m. A 7-week IMT program was completed by 6 females and 3 males (age 34.8 ± 10.0 years) randomized to IMT (n = 4) or placebo [P (n = 5)]. A Powerbreathe was initially set at a resistance of 50% (IMT) or used at 15% of maximal inspiratory pressure (MIP) throughout (P). A self-paced walking test was completed before and after training at PIO2 = 104.1mmHg, 3440m (NH1); PIO2 = 85.9 mmHg, 4930m (NH2); and at 3440m during the trek (HH). Exercise data were interpolated to 4.8 km/hour to evaluate training effects. Patterns of change suggest possible benefits of IMT, but due to small group sizes and variability, these trends are not significant. MIP increased by 6% and 4% following IMT and P. Pulse oxygen saturation (SaO2) during exercise in NH2 increased by*4% following IMT, with no change in P. Decreases in resting SaO2 during the expedition (4930m) were attenuated in IMT (85.0 ± 3.61%) compared to P (80.0 ± 5.87%). Comparisons between NH1 exercise post-training and HH showed a decrease in perceived dyspnoea and effort in IMT ( - 0.3 and - 0.7) but an increase in P ( + 0.7 and + 2.6). Nonsignificant trends within the data suggest that the altitude-induced decrease in resting and exercise SaO2 and intensified perceived effort and dyspnoea during exercise were attenuated following IMT. However, further research is required to establish any beneficial effect of IMT

Inspiratory muscle training and its effect on oxygen saturation and perceptions of effort and dyspnoea during a trek to Everest base camp

Inspiratory muscle training and its effect on indices of physiological and perceived stress during incremental walking exercise in normobaric hypoxia

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Archivio istituzionale della ricerca - Università di Padova

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Leeds Beckett Repository