57 research outputs found
Health-Related Data from a Community Risk Reduction Program: Healthy Uâą of DelMarva
The primary aim of this study was to examine baseline data from participants in a community coalition aiming to reduce disease risk and enhance lifestyle modification. Adults (N = 5,876) residing in the Eastern Shore of Maryland enrolled in the program, and were encouraged to re-enroll the following year. Incentives were offered to enhance participation and program adherence. Cooking demonstrations, exercise classes, and lectures were held, and community-wide messages espousing healthy behavior were spread to increase knowledge of healthy behavior. Participants filled out a survey, and body mass index (BMI) and waist-to-hip ratio (WHR) were measured. Frequency statistics were used to analyze data. BMI (29.73 ± 7.38 kg/m2 ), waist circumference (37.15 ± 6.85 in.), and WHR (0.84 ± 0.09) surpassed healthy values. Intake of fruits and vegetables was low, inactivity was high (50% of members exercised less than two days/week), and diets moderate or high in fat were prevalent (70% of participants). Data confirm the rather unhealthy lifestyle of our local population. Future interventions to enhance wellness and reduce disease in this population are warranted
Continuous Leg Cycling Ergometry Prescribed at Identical Relative Power Output Elicits Different Physiological Responses Versus Arm Cycle Ergometry
PURPOSE: The aim of this study was to compare physiological and perceptual responses to progressive moderate intensity continuous exercise (MICE) between leg (LCE) and arm cycle ergometry (ACE). METHODS: Seventeen active men and women (age and percent body fat = 26 ± 7 yr and 18 ± 3 %) initially performed graded exercise on each modality to assess maximal oxygen uptake (VO2max) and peak power output (PPO). Using a randomized crossover design, they subsequently performed 45 min of MICE consisting of three 15 min bouts at 20, 40, and 60 % PPO on each modality. Gas exchange data (VO2, VCO2, VE, and respiratory exchange ratio (RER), heart rate (HR), blood lactate concentration (BLa), affective valence, and rating of perceived exertion (RPE) were acquired during each bout. RESULTS: Compared to ACE, LCE revealed significantly higher (p \u3c 0.05) peak (94 ± 6 vs. 88 ± 9 %HRmax, d = 0.81) and mean HR (73 ± 6 vs. 66 ± 6 %HRmax, d = 1.20) and VO2 (54 ± 5 vs. 50 ± 7 %VO2max, d = 0.68). Time spent above 70 (22 ± 7 vs. 15 ± 8 min, d = 1.03) and 80 %HRmax (15 ± 6 vs. 9 ± 6 min, d = 1.04) was significantly greater with LCE versus ACE. LCE revealed significantly higher BLa versus ACE (5.5 ± 2.0 vs. 4.7 ± 1.5 mM, d = 0.48). CONCLUSIONS: These results exhibit that progressive leg cycling at identical intensities elicits a greater cardiometabolic stimulus than arm ergometry. Moreover, leg cycling leads to greater duration spent at intensities between 70 â 89 %VO2max which may have application to selecting specific exercise modes when prescribing MICE to increase cardiorespiratory fitness. Lastly, use of %PPO led to participants being classified in different intensity domains which merits prescribing MICE according to various threshold measures rather than relative intensities acquired from incremental exercise
Identifying Maximal Fat Oxidation during Arm Ergometry
Metabolic responses have been extensively studied in response to various exercise modalities, such as treadmill running and cycling. Achten et al. (2002) demonstrated that graded exercise testing in trained cyclists using 3 minute (min) stages led to similar estimates of fat oxidation (FOx) and maximal fat oxidation (MFO) as 5 min stages. However, minimal research has studied FOx responses during exercises using arm cycle ergometry (ACE). PURPOSE: To compare FOx responses during progressive ACE using 3 and 5 min stages. METHODS: Participants consisted of 11 healthy, non-obese men and women (age = 24±9 yr, %BF
= 23±5%, VO2peak and PPO = 23.5±5.7 ml/kg/min and 103.2±40.4 W) who are physically active (PA = 5±2 h/wk) but unfamiliar with ACE. Participants initially underwent graded exercise testing to determine peak oxygen uptake (VO2peak) and peak power output (PPO) on the ACE. Utilizing a randomized crossover design, on two separate days, following a 12 h fast, participants performed progressive exercise on the ACE with gradually increasing intensities every 3 or 5 min, starting at 15%PPO and PO increasing by 10% per stage. Gas exchange data, heart rate (HR), and blood lactate concentration (BLa) were obtained throughout exercise. RESULTS: Paired t-test showed no significant differences in MFO between 3 and 5 min stages (0.16±0.07 vs 0.13±0.07 g/min, p=0.07), and there was a strong, positive correlation between these values (r=0.82, p =0.002). There were no significant differences between protocols in BLa at MFO (1.94 ±1.0 vs. 1.95±0.8 mM, p= 0.93), MFO expressed as percent of peak HR (%HRpeak) (59±9 vs. 58±11 %HRpeak, p= 0.80), % VO2peak (38±8 vs. 42±15% VO2peak, p= 0.24) or power output (PO) at MFO (26±12 vs. 24±10
%PPO, p= 0.17). However, RER at MFO was significantly different between 3 and 5 min stages (0.83±0.05 vs. 0.86±0.03, p= 0.04). Results showed no significant duration X time interaction for BLa (p= 0.25), FOx (p= 0.44), carbohydrate oxidation (CHOOx) (p= 0.057), RER (p= 0.61), or blood glucose (p= 0.24) between stage durations. CONCLUSION: As no significant differences in FOx were revealed between stage durations, we recommend 3 min stages to identify metabolic responses during progressive ACE. However, more study is merited to elucidate the individual variability in the FOx response to exercise
Comparing Physiological Responses During Rowing High Intensity Interval Training (HIIT) versus High Intensity Functional Training (HIFT)
High intensity interval training (HIIT) improves cardiorespiratory fitness, glycemic control, and body composition, yet the majority of studies used cycling which employs a smaller muscle mass. Less data have examined the acute response to whole-body HIIT. PURPOSE: To compare physiological responses between HIIT rowing and high intensity functional training (HIFT). METHODS: Healthy, non-obese men and women (N=18, age=25±8 yr) who are physically active (PA=7±2hr, VO2max=39±8mL/kg/min) underwent graded exercise testing to determine VOâmax and peak power output (PPO) on the rowing ergometer. On two separate days, subjects performed a time-matched bout of HIFT or HIIT rowing. HIIFT required 6 âall-outâ sets of 10 push-ups, 10 jump squats, 20 mountain climbers, and 20 body-weight squats separated by 75 s recovery. HIIT rowing consisted of six 1min bouts at 85% PPO with 75 s of recovery. Gas exchange data, heart rate (HR), affective valence, and RPE were obtained during exercise. Blood lactate concentration (BLa) was measured at rest, bout 3, and 5, 10, and 15 min post-exercise. RESULTS: There were significant differences (p2 was higher (p=0.03) with HIIT rowing versus HIFT (1.88 ± 0.51 vs. 1.67 ± 0.35 L/min) as was total O2 (31±8 vs. 28±6L). GroupXtime interactions (pE, and RPE occurred, with higher values demonstrated to HIFT. CONCLUSION: HIFT elicited a higher peak HR, BLa, and RER, suggesting a higher peak cardiovascular stimulus and greater activation of glycolysis, likely due to greater recruitment of fast twitch fibers. Yet, HIIT rowing elicited higher energy expenditure and mean VO2 versus HIFT. The eccentric nature of HIFT may explain the blunted VO2 response, although more studies are needed to verify this result
Progressive Arm Cycling Ergometry With 3- And 5-Minute Stage Durations Yields Similar Estimates of Substrate Oxidation in Healthy Adults
International Journal of Exercise Science 17(2): 468-479, 2024. Arm cycling ergometry (ACE) leads to a lower maximal oxygen uptake (VO2max) than cycling which is related to a smaller active muscle mass. This study compared estimates of fat and carbohydrate oxidation (FOx and CHOOx) between progressive exercise protocols varying in stage duration in an attempt to create a standard exercise protocol for determining substrate metabolism using ACE. Four men and seven women (age = 24 ± 9 yr) unfamiliar with ACE completed incremental exercise to determine peak power output and VO2peak. During two subsequent sessions completed after an overnight fast, they completed progressive ACE using 3- or 5-min stages during which FOx, CHOOx, and blood lactate concentration (BLa) were measured. Results showed no difference (p \u3e 0.05) in FOx, CHOOx, or BLa across stage duration, and there was no difference in maximal fat oxidation (0.16 ± 0.08 vs. 0.13 ± 0.07 g/min, p = 0.07). However, respiratory exchange ratio in response to the 3 min stage duration was significantly lower than the 5 min duration (0.83 ± 0.05 vs. 0.86 ± 0.03, p = 0.04, Cohenâs d = 0.76). Results suggest that a 3 min stage duration is preferred to assess substrate metabolism during upper-body exercise in healthy adults
Verification Testing To Confirm VO2max Attainment in Inactive Women With Obesity
International Journal of Exercise Science 13(4): 1448-1458, 2020. Incidence of obesity is increasing worldwide which is deleterious to health due to its association with increased risk of cardiovascular disease, diabetes, and some cancers. Completion of regular physical activity in individuals with obesity increases maximal oxygen uptake (VO2max). However, whether individuals with obesity can exhibit âtrueâ VO2max is unresolved. This study examined efficacy of verification testing (VER) to identify âtrueâ VO2max in 17 inactive women with obesity (age, body fat, and VO2max = 37 ± 10 yr, 48.7 ± 3.5 %, and 19.4 ± 3.0 mL/kg/min, respectively). They performed ramp exercise (RAMP) to volitional fatigue followed by VER at 105 percent peak power output (%PPO) at baseline and after 3 and 6 wk of high intensity interval training. Results showed no difference in ramp and verification-derived VO2max (1.99 ± 0.37 L/min vs. 1.98 ± 0.32 L/min, 2.00 ± 0.40 L/min vs. 2.04 ± 0.38 L/min, and 2.08 ± 0.34 L/min vs. 2.08 ± 0.32 L/min at 0, 3 and 6 wk of training), although in 40 % of VER tests, VO2max was greater than the RAMP value. Overall, verification testing may be adopted as an additional approach to confirm âtrueâ VO2max attainment in obese women as ramp exercise frequently underestimates VO2max in this population
Burpee interval training is associated with a more favorable affective valence and psychological response than traditional high intensity exercise
Acute psychological responses to physical activity may help explain long-term adherence to it. Thus, we compared acute psychological responses to different exercise protocols with identical durations. Eighteen moderately active young adults [Mage = 23, SD = 3 years; MVO2max (maximum oxygen consumption) = 42.8, SD = 4.3 mL kg1 min1 ; MBMI (body mass index) = 24, SD = 2 kg m2 ] completed three low-volume exercise sessions in a crossover research design: (a) sprint interval training (SIT), (b) burpee interval training (BIT) requiring 10 Ă 5 second efforts with 35 seconds of passive recovery, and (c) a single bout of vigorous intensity continuous training (VICT) requiring 6 minutes and 5 seconds of running at âŒ85% of peak heart rate (HRpeak). We assessed participantsâ ratings of perceived exertion (RPE), affective valence, enjoyment, intention, preference, and self-reported recovery and wellness before, during, and after each session. BIT was associated with significantly greater enjoyment, preference, and exercise intention (at 5 Ă week) than VICT (p †.05). SIT elicited greater RPE (M = 5.38, SD = 2.00) than both BIT (M = 2.88, SD = 1.23) and VICT (M = 3.55, SD = 1.38) (p †.05), and we observed a higher increase in RPE over time with SIT versus BIT (p = .019). For affective valence, SIT (M = 0.55, SD = 2.12) elicited a more aversive response than both BIT (M = 2.55, SD = 1.09) and VICT (M = 1.94, SD = 1.51) (p †.05), and there was a higher increase in this aversive response to SIT over time (p < .05). Forty-eight-hour postexercise session muscle soreness was significantly lower with VICT than with BIT (p = .03). Overall, BIT was associated with more positive psychological responses than SIT and VICT
Is a verification phase useful for confirming maximal oxygen uptake in apparently healthy adults? A systematic review and meta-analysis
BackgroundThe 'verification phase' has emerged as a supplementary procedure to traditional maximal oxygen uptake (VO2max) criteria to confirm that the highest possible VO2 has been attained during a cardiopulmonary exercise test (CPET).ObjectiveTo compare the highest VO2 responses observed in different verification phase procedures with their preceding CPET for confirmation that VO2max was likely attained.MethodsMEDLINE (accessed through PubMed), Web of Science, SPORTDiscus, and Cochrane (accessed through Wiley) were searched for relevant studies that involved apparently healthy adults, VO2max determination by indirect calorimetry, and a CPET on a cycle ergometer or treadmill that incorporated an appended verification phase. RevMan 5.3 software was used to analyze the pooled effect of the CPET and verification phase on the highest mean VO2. Meta-analysis effect size calculations incorporated random-effects assumptions due to the diversity of experimental protocols employed. I2 was calculated to determine the heterogeneity of VO2 responses, and a funnel plot was used to check the risk of bias, within the mean VO2 responses from the primary studies. Subgroup analyses were used to test the moderator effects of sex, cardiorespiratory fitness, exercise modality, CPET protocol, and verification phase protocol.ResultsEighty studies were included in the systematic review (total sample of 1,680 participants; 473 women; age 19-68 yr.; VO2max 3.3 ± 1.4 L/min or 46.9 ± 12.1 mL·kg-1·min-1). The highest mean VO2 values attained in the CPET and verification phase were similar in the 54 studies that were meta-analyzed (mean difference = 0.03 [95% CI = -0.01 to 0.06] L/min, P = 0.15). Furthermore, the difference between the CPET and verification phase was not affected by any of the potential moderators such as verification phase intensity (P = 0.11), type of recovery utilized (P = 0.36), VO2max verification criterion adoption (P = 0.29), same or alternate day verification procedure (P = 0.21), verification-phase duration (P = 0.35), or even according to sex, cardiorespiratory fitness level, exercise modality, and CPET protocol (P = 0.18 to P = 0.71). The funnel plot indicated that there was no significant publication bias.ConclusionsThe verification phase seems a robust procedure to confirm that the highest possible VO2 has been attained during a ramp or continuous step-incremented CPET. However, given the high concordance between the highest mean VO2 achieved in the CPET and verification phase, findings from the current study would question its necessity in all testing circumstances.Prospero registration idCRD42019123540
Confirming the attainment of maximal oxygen uptake within special and clinical groups: a systematic review and meta-analysis of cardiopulmonary exercise test and verification phase protocols
Background and aim A plateau in oxygen uptake (VÌO2) during an incremental cardiopulmonary exercise test (CPET) to volitional exhaustion appears less likely to occur in special and clinical populations. Secondary maximal oxygen uptake (VÌO2max) criteria have been shown to commonly underestimate the actual VÌO2max. The verification phase protocol might determine the occurrence of âtrueâ VÌO2max in these populations. The primary aim of the current study was to systematically review and provide a meta-analysis on the suitability of the verification phase for confirming âtrueâ VÌO2max in special and clinical groups. Secondary aims were to explore the applicability of the verification phase according to specific participant characteristics and investigate which test protocols and procedures minimise the differences between the highest VÌO2 values attained in the CPET and verification phase. Methods Electronic databases (PubMed, Web of Science, SPORTDiscus, Scopus, and EMBASE) were searched using specific search strategies and relevant data were extracted from primary studies. Studies meeting inclusion criteria were systematically reviewed. Meta-analysis techniques were applied to quantify weighted mean differences (standard deviations) in peak VÌO2 from a CPET and a verification phase within study groups using random-effects models. Subgroup analyses investigated the differences in VÌO2max according to individual characteristics and test protocols. The methodological quality of the included primary studies was assessed using a modified Downs and Black checklist to obtain a level of evidence. Participant-level VÌO2 data were analysed according to the threshold criteria reported by the studies or the inherent measurement error of the metabolic analysers and displayed as Bland-Altman plots. 3 Results Forty-three studies were included in the systematic review, whilst 30 presented quantitative information for meta-analysis. Within the 30 studies, the highest mean VÌO2 values attained in the CPET and verification phase protocols were similar (mean difference = -0.00 [95% confidence intervals, CI = -0.03 to 0.03] L·min-1 , p = 0.87; level of evidence, LoE: strong). The specific clinical groups with sufficient primary studies to be meta-analysed showed a similar VÌO2max between the CPET and verification phase (p > 0.05, LoE: limited to strong). Across all 30 studies, VÌO2max was not affected by differences in test protocols (p > 0.05; LoE: moderate to strong). Only 23 (53.5%) of the 43 reviewed studies reported how many participants achieved a lower, equal, or higher VÌO2 value in the verification phase versus the CPET or reported or supplied participant-level VÌO2 data for this information to be obtained. The percentage of participants that achieved a lower, equal, or higher VÌO2 value in the verification phase was highly variable across studies (e.g. the percentage that achieved a higher VÌO2 in the verification phase ranged from 0% to 88.9%). Conclusion Group-level verification phase data appear useful for confirming a specific CPET protocol likely elicited VÌO2max, or a reproducible VÌO2peak, for a given special or clinical group. Participant-level data might be useful for confirming whether specific participants have likely elicited VÌO2max, or a reproducible VÌO2peak, however, more research reporting participant-level data is required before evidence-based guidelines can be given
Physiological and perceptual responses to sprint interval exercise using arm versus leg cycling ergometry
Increases in power output and maximal oxygen consumption (VO2max) occur in response to sprint interval exercise (SIE), but common use of âall-outâ intensities presents a barrier for many adults. Furthermore, lower-body SIE is not feasible for all adults. We compared physiological and perceptual responses to supramaximal, but ânon-all-outâ SIE between leg and arm cycling exercise. Twenty-four active adults (meanâŻÂ±âŻSD age: [25âŻÂ±âŻ7] y; cycling VO2max: [39âŻÂ±âŻ7] mL·kgâ1·minâ1) performed incremental exercise using leg (LCE) and arm cycle ergometry (ACE) to determine VO2max and maximal work capacity (Wmax). Subsequently, they performed four 20âŻs (s) bouts of SIE at 130âŻ% Wmax on the LCE or ACE at cadenceâŻ=âŻ120â130âŻrev/min, with 2âŻmin (min) recovery between intervals. Gas exchange data, heart rate (HR), blood lactate concentration (BLa), rating of perceived exertion (RPE), and affective valence were acquired. Data showed significantly lower (pâŻâŻ0.42), and lowest affective valence recorded (2.0âŻÂ±âŻ1.8) was considered âgood to fairly goodâ. Data show that non âall-outâ ACE elicits lower absolute but higher relative HR and VO2 compared to LCE. Less aversive perceptual responses could make this non-all-out modality feasible for inactive adults
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