Polarized Concomitant Training - Will it Help You Make Max. Gains & Improvements in Body Comp. W/ Strength+Cardio?

Polarized Concomitant Training - Will it Help You Make Max. Gains & Improvements in Body Comp. W/ Strength+Cardio?

bench press build muscle cardio concomitant training gain muscle lose fat polarized training squat strength strength training training workouts

Polarized training? Find out more...

Does concurrent / concomitant training intensity distribution matter? Unless you're a first timer at the SuppVersity you will have read at least two or three previous articles of mine about studies investigating the effects of concurrent training, i.e. the combination of strength and cardio training, (i.e. concomitant training) here.

If you recall the results, you will know that previous research has demonstrated the influence of intensity distribution on strength endurance training adaptations.

You can learn more about the optimal exercise order at the SuppVersity

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Strength Training Blueprints

Study: Over-training Exists

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You may also remember that no previous study has addressed the influence of "intensity distribution", i.e. the way intensity and volume are distributed across the training sessions, on the effectiveness of concurrent training (CT | see Figure 1). The goal was to prevent interference of the two types of training:

Figure 1: Training design of the experimental groups during the 8-week training period. Continuous-line and dotted-line circles represent the different training session modalities for the PT and TT groups, respectively. PT: polarized training group; TT: Traditional-based training group; BW: brisk walking; RM: repetition maximum; RNG: running; IST: intermittent sprint training (Varela-Sanz. 2016).

"Another problem which must be solved is the comparison of external training loads. Thus, our independent variable and focus was training intensity distribution with an equivalent total external load [...] of both training programs. A training group performed a combination of strength and endurance training aligned with the current ACSM recommendations of intensity distribution, while another group performed the same amount of external workload but with a polarized intensity distribution. Both ex. groups were evaluated before and after an 8-week training period (weekly training frequency of 3 days), and compared to a control group. To examine the effectiveness of the [...] training regimes, [...] physical (jump capacity, upper- and lower-body strength, running performance, and body composition), physiological (heart rate variability), and perceptual variables (rate of perceived exertion, training impulse, and feeling scale) were examined as dependent variables" (Varela-Sanz. 2016)

Thirty-one healthy sport science students (30 men, 5 women; all moderately active, but training less than 2 days per week apart from their academic activities which included a variable amount of PA on a daily basis) volunteered and were, after a 2-week familiarization phase (training thrice a week for two weeks), evaluated for resting heart rate variability (HRV), countermovement jump, bench press, half squat, and maximum aerobic speed (MAS).

I don't get it. How exactly did this "polarized training" work? Yes, the protocol was different from the one you may remember from Seiler et al. (2006) who tried to quantify training intensity distribution in elite endurance athletes. More specifically, subjects trained thrice a week (i.e. Monday, Wednesday, and Friday) for ~120 min each on Monday and Friday, and ~60 min on Wednesday. The training sessions on Mondays and Fridays consisted of cardiorespiratory exercise training (i.e. brisk walking or running) followed by resistance exercise training; meanwhile on Wednesdays participants only performed cardiorespiratory exercise training.

Each training session started with a standardized warm-up that consisted of 5 min of calisthenics followed by 5 min of brisk walking at 30% of the MAS. Before resistance exercises, participants also performed a specific warm-up that consisted of 2 sets of 8 repetitions of the resistance circuit they performed during the familiarization period with a OMNI-Scale perception of effort of 2-3. Cooling down exercises consisted of 2-3 sets of 15 s of stretching exercises of the muscle groups involved during the session. The exercises during the actual workout were bench press and half squat. Based on the conclusions of Simão et al., whose study had revealed that you will see greater gains on those exercises you do first in your workout, the order of resistance exercises was alternated each week. In that, the TT group performed 3-5 sets of 10-12 RM with 3 min of rest between sets. The PT group performed 3-5 sets of 5 RM on Mondays, and 2-4 sets of 15 RM on Fridays. The rest between sets was always 3 min. Resistance exercise workloads were equated.

All were then randomly distributed into either a traditional-based training group (TT; n=11; 65-75% of MAS, combined with 10-12RM), polarized training group (PT; n=10; 35-40% and 120% of MAS, combined with 5RM and 15RM), or control group (CG; n=10).

Figure 2: Relative changes in heart rate, jump height, peak power, bench press (1RM) and half squat (1RM) after 8 weeks of traditional (TT), polarized (PT) training or control (Varela-Sanz. 2016).

After 8 weeks of training (3 days.week-1), TT and PT exhibited similar improvements in MAS, bench press and half squat performances. No differences were observed between TT and PT groups for perceived loads. There were no changes in heart rate variability (HRV) for any group although TT exhibited a reduction in resting HR.

Figure 3: Effect sizes corresponding to the relative values in Figure 1 (Varela-Sanz. 2016).

What is worth mentioning, though, is that, compared to other groups, the PT group maintained jump capacity with an increment in body weight and BMI without changes in body fatness, in other words: they gained muscle, but also fat (see Figure in Bottom Line | body fat measured by skinfold "only").

There's one thing we didn't discuss yet: Was the polarized training maybe less taxing or more fun? The findings of the study at hand suggest that this was the case: TT and PT reported similar perceptions of effort, sensations, and internal load levels over the 8-week training period. Briefly, RPE and TRIMPS increased progressively along the 8-week training period. These perceptual levels demonstrated an increase in external load during the 3rd microcycle compared to the 1st and 2nd microcycles of each mesocycle. Thus, "the current findings suggest that different concurrent training regimes of equated loads could be similarly perceived by participants" (Varela-Sanz. 2016).

Effects on body composition; effect sizes and rel. (%) changes (Varela-Sanz. 2016).

Bottom line: The previously outlined observations lead the scientists to conclude that their funky polarization approach to concurrent training "induced similar improvements in physical fitness of physically-active individuals", but that "PT produced a lower interference for jumping capacity despite an increment in body weight, whereas TT induced greater bradycardia" (Varela-Sanz. 2016).

The fact that there were further benefits in terms of peak power, squat and bench press performance, but that those were not statistically significant (see Figure 2), however, is something the scientists don't mention in the abstract, even though these differences could become significant in the longer (>8 weeks) term.

A mistake? No, in view of the conflicting evidence from the calculated effect sizes (see Figure 3), it is absolutely correct to say that there were no meaningful inter-group differences in the most important parameters for most trainees, i.e. the bench press, half squat and the effects on body comp (see Figure on the right) | Comment!

References:

• Seiler, K. Stephen, and Glenn Øvrevik Kjerland. "Quantifying training intensity distribution in elite endurance athletes: is there evidence for an “optimal” distribution?." Scandinavian journal of medicine & science in sports 16.1 (2006): 49-56.
• Simao, Roberto, et al. "Exercise order in resistance training." Sports Medicine 42.3 (2012): 251-265.
• Varela-Sanz, Adrián; Tuimil, José L.; Abreu, Laurinda; Boullosa, Daniel A. "Does concurrent training intensity distribution matter?" Journal of Strength & Conditioning Research: Post Acceptance: May 09, 2016 doi: 10.1519/JSC.0000000000001474.

Cardio Can BOOST Your Gains?! Do it Before Weights and be Rewarded With 28% Increased Fiber Size & VO2 Gains

Cardio Can BOOST Your Gains?! Do it Before Weights and be Rewarded With 28% Increased Fiber Size & VO2 Gains

aerobic exercise build muscle build strength cardio concomitant training resistance training VO2 vo2max

It may be important that the subjects cycled, because a recent review of the potential interference of cardio w/ strength training shows that cycling is the least likely to affect your gains (Murach. 2016).

In previous articles at the SuppVersity, I have written about the still ubiquitous concern that cardio training (or aerobic training, in general) could hamper your size and strength gains - a fear that is, unless you overdo it, unwarranted (learn more about HIIT & "regular" cardio training).

Now, a recent study from the Mid Sweden University shows that the opposite could be the case, i.e. that the hypertrophy response to exercise can actually be stimulated by combining resistance training not just with "cardio", but with "cardio" (=continuous cycling) and HIIT - at least if it's done not after, but before resistance training.

Are you looking for muscle builders for the year 2016? Find inspiration in these articles:

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Study Indicates Cut the Volume Make the Gains!

The authors of the study, Zuzanna Kazior, Sarah J. Willis, Marcus Moberg, William Apró, José A. L. Calbet, Hans-Christer Holmberg, andn Eva Blomstrand were (just like you?) unhappy with the contradictory outcomes of existing studies on the effect of endurance exercise on the anabolic response to strength training. Accordingly, they designed a study to "re-investigated this issue, focusing on training effects on indicators of protein synthesis and degradation" (Kazior. 2016).

Figure 1: Overview of the resistance (top) and cardio training (bottom) protocols in the study at hand (Kazior. 2016).

In said study, two groups of previously not regularly trained male subjects performed 7 weeks of resistance exercise alone (R; n = 7) or in combination with preceding endurance exercise, including both continuous and interval cycling (ER; n = 9). You can see the exact protocols in Figure 1, with the resistance training part being on the top and the endurance / HIIT part on the bottom (the number of training sessions in the ER and R group were identical; importantly, the endurance training was performed before the resistance training and included an extra 5-min warm-up + cool-down before and after the E-part.

Did carbohydrates make the difference? Within 20 min after completion of a training session, subjects in the R-group received a protein supplement (Kolozzeum Pure Whey, Stockholm, Sweden), 20 g dissolved in 500 ml of water to enhance muscle recovery. The ER-group were given this same supplement, but with addition of maltodextrin (Fairing Fast Carbs, Järfälla, Sweden) in an amount corresponding to the individual´s calculated energy expenditure during the endurance training - did the maltodextrin make a difference? Based on the results of previous studies, this seems very unlikely. While carbs alone can enhance the protein synthetic response to resistance training (Børsheim. 2004), studies show no benefit of adding it to a sufficient amount of protein that is consumed right after resistance training workouts (Koopmann. 2007). 

Biopsies were taken from the lateral part of m. quadriceps, i.e., the vastus lateralis, both before and after 7 weeks of training. To ensure the results were not messed up, ...

"[t]he subjects were instructed to refrain from training for 2 days prior to the pre-training biopsies and the post-training biopsies were taken approximately 2 to 3 days after the final session in 15 subjects, but in one subject the post-training biopsy was taken 90 hours after the final session. During this period the subjects also refrained from training" (Kazior. 2016).

All data are expressed as means ± SD and were checked for normal distribution before performing parametric statistical analyses. A two-way repeated measures ANOVA (time, group) was applied to evaluate and compare the effect of training in the R and ER groups. When the ANOVA showed a significant main effect or interaction between time and group, Fisher’s LSD post hoc test was applied to identify where the differences occurred. A P-value <0.05 was considered to be statistically significant.

Figure 2: Levels of proteins in the Akt signaling pathway before and after 7 weeks of training. (A) Akt, (B) mTOR and (C) S6K1 in skeletal muscle before (Pre) and after (Post) 7 weeks of strength training only (R) or combined endurance and resistance exercise (ER). Representative immunoblots from two subjects. *P < 0.05 for Post vs. Pre (Kazior. 2016).

While similar increases in leg-press 1 repetition maximum (30%; P<0.05) were observed in both groups, irrespective of the maximal muscle gains - a discrepancy of which the scientists say that it "suggests that the improvement in maximal strength (1RM) observed following our relatively short 7-week period of training is due largely to neuromuscular adaptation" (Kazior. 2016), the scientists observed a striking and highly significant difference between the changes of the subject's maximal oxygen uptake (a marker of cardiovascular fitness) in the two groups. As you may already have expected, the latter was elevated (8%; P<0.05) only in the ER group, while the strength training only group saw no increase in this important fitness marker.

Figure 3: Pre- vs. post changes in fiber are and capillary density in both groups (Kazior. 2016).

And what about the gains? As far as those were concerned, Kazior et al. observed significantly larger increases in the ER training group as well. More specifically, the ER group saw gains in both, the areas of both type I and type II fibers. The R protocol, on the other hand, increased only the area of the type II fibers, which is why it is not exactly surprising that the mean fiber area increased by 28% (P<0.05) in the ER group, whereas no significant increase was observed in the R group - a difference that appears to be in line with the expression of the anabolic proteins Akt and mTOR, which were both enhanced in the ER group, whereas only the level of mTOR was elevated following R training. The scientists further analyses showed that...

"[the t]raining-induced alterations in the levels of both Akt and mTOR [both anabolic] protein were correlated to changes in type I fiber area (r = 0.55–0.61, P<0.05), as well as mean fiber area (r = 0.55–0.61, P<0.05), reflecting the important role played by these proteins in connection with muscle hypertrophy. Both training regimes reduced the level of MAFbx protein (P<0.05) and tended to elevate that of MuRF-1 [both catabolic]" (Kazior. 2016).

In view of these findings, it is only logical that the authors conclude that "the present findings indicate that the larger hypertrophy observed in the ER group is due more to pronounced stimulation of anabolic rather than inhibition of catabolic processes" (Kazio. 2016) - irrespective of the fact that they cannot tell for sure what it was that triggered these practically relevant differences.

Can the increase in IGF1, GH and testosterone as it was observed W/ Cardio first by Rosa et al. (2014) explain the increased size gains?

So what's going on, here? While you may expect that the addition of carbohydrates after the workout in the ER group could have something to do with the increased size gains, the data discussed in the red box shows that this is relatively unlikely (even though it could be the reason why AKT increased only in the ER group).

As far as the reasons for the surprising differences to other studies are concerned, we are thus left with two options: (1) the cardio protocol with steady state + HIIT could be special, or (2) doing cardio before not after strength training could be special. Interestingly enough, I've written about potential anabolic benefits of doing your cardio before weights, before: In a 2014 study, Rosa et al. observed significant increases in the purportedly muscle building hormones GH, IGF1 and testosterone when cardio was done before weights.

Whether it's in fact a pro-anabolic response to reversing the more common order of resistance training > cardio to cardio > resistance training does yet seem questionable - irrespective of the fact that the acute GH response was in fact one out of two parameters of which West et al. have found that it correlates with the actual muscle gains in their seminal 2012 study (discussed here) | Maybe you've got better explanations? If so, leave them in a comment on Facebook!

References:

• Børsheim, Elisabet, et al. "Effect of carbohydrate intake on net muscle protein synthesis during recovery from resistance exercise." Journal of Applied Physiology 96.2 (2004): 674-678.
• Kazior Z, Willis SJ, Moberg M, Apró W, Calbet JAL, Holmberg H-C, et al. "Endurance Exercise Enhances the Effect of Strength Training on Muscle Fiber Size and Protein Expression of Akt and mTOR." PLoS ONE 11.2 (2016) : e0149082. doi:10.1371/journal.pone.0149082
• Koopman, René, et al. "Coingestion of carbohydrate with protein does not further augment postexercise muscle protein synthesis." American Journal of Physiology-Endocrinology and Metabolism 293.3 (2007): E833-E842.
• Murach, Kevin A., and James R. Bagley. "Skeletal Muscle Hypertrophy with Concurrent Exercise Training: Contrary Evidence for an Interference Effect." Sports Medicine (2016): 1-11.
• Rosa C, Vilaça-Alves J, Fernandes HM, Saavedra FJ, Pinto RS, Machado Dos Reis V. "Order effects of combined strength and endurance training on testosterone, cortisol, growth hormone and IGFBP-3 in concurrent-trained men". J Strength Cond Res. (2014): Jul 15 Ahead of Print. 
• West, Daniel WD, and Stuart M. Phillips. "Associations of exercise-induced hormone profiles and gains in strength and hypertrophy in a large cohort after weight training." European journal of applied physiology 112.7 (2012): 2693-2702.