Treinar até a Falha x Treinar sem Falhar

[Dr. Fernando Britto Barboza]

vou ver se vejo isso já essa semana.... daí falo pra vcs.

valew.

[Dr. Fernando Britto Barboza]

Prontinho... consegui na iniciação cientifica....

só nao tive nem tempo de ler ou traduzir..se alguem puder fazer as honras da casa....

demorei um poko mas trouxe.

valew.

obs: o que nao ta aparecendo é tabela.

DIFFERENTIAL EFFECTS OF STRENGTH TRAINING LEADING TO FAILURE

VERSUS NOT TO FAILURE ON HORMONAL RESPONSES, STRENGTH AND

MUSCLE POWER GAINS

Mikel Izquierdo1, Javier Ibañez1, Juan José González-Badillo2, Keijo Häkkinen3 ,

Nicholas A. Ratamess4, William J. Kraemer5, Duncan N. French6, Jesus Eslava1, Aritz

Altadill1, Xabier Asiain1 and Esteban M. Gorostiaga1

Running title: Strength training leading to failure and endocrine responses

1Studies, Research and Sport Medicine Center,

Government of Navarra, Spain

2Olympic Center of Sport Studies

Spanish Olympic Committee, Spain

3Department of Biology of Physical Activity

University of Jyväskylä, Finland,

4Department of Health and Exercise Science

The College of New Jersey, Ewing, NJ, USA

5 Department of Kinesiology, Human Performance Laboratory

University of Connecticut, Storrs, CT 06269-1110, USA

6Institute of Sport, Northumbria University, United Kingdom.

Address for Correspondence to:

Mikel Izquierdo, Ph.D.

Studies, Research and Sport Medicine Center

Government of Navarra

C/ Sangüesa 34

31005 Pamplona (Navarra) SPAIN

+ 34 948 292623 tel

+ 34 948 292636 fax

mikel.izquierdo@ceimd.org

1

Articles in PresS. J Appl Physiol (January 12, 2006). doi:10.1152/japplphysiol.01400.2005

Copyright © 2006 by the American Physiological Society.

ABSTRACT

The purpose of this study was to examine the efficacy of 11 weeks of resistance training to

failure vs. non-failure, followed by an identical 5- week peaking period of maximal strength and

power training for both groups as well as to examine the underlying physiological changes in

basal circulating anabolic/catabolic hormones. Forty-two physically-active men were matched

and then randomly assigned to either a training to failure (RF; n=14), non-failure (NRF; n=15) or

control groups (C;n=13). Muscular and power testing and blood draws to determine basal

hormonal concentrations were conducted before the initiation of training (T0), after 6 wk of

training (T1), after 11 wk of training (T2), and after 16 wk of training (T3). Both RF and NRF

resulted in similar gains in 1RM bench press (23% and 23%) and parallel squat (22% and 23%),

muscle power output of the arm (27% and 28%) and leg extensor muscles (26% and 29%) and

maximal number of repetitions performed during parallel squat (66% and 69%). RF group

experienced larger gains in the maximal number of repetitions performed during the bench

press The peaking phase (T2 to T3) followed after NRF resulted in larger gains in muscle power

output of the lower extremities, whereas after RF resulted in larger gains in the maximal number

of repetitions performed during the bench press. Strength training leading to RF resulted in

reductions in resting concentrations of IGF-1 and elevations in IGFBP-3, whereas NRF resulted

in reduced resting cortisol concentrations and an elevation in resting serum total testosterone

concentration. This investigation demonstrated a potential beneficial stimulus of NRF for

improving strength and power, especially during the subsequent peaking training period,

whereas performing sets to failure resulted in greater gains in local muscular endurance.

Elevation in IGFBP-3 following resistance training may have been compensatory to

accommodate the reduction in IGF-1 in order to preserve IGF availability.

Key words: strength training, repetition to failure, IGF-1, IGFBP-3, Testosterone, Cortisol.

2

INTRODUCTION

The optimal manipulation of strength training variables to maximize performance

and to understand the physiological mechanisms underlying training-induced gains in

strength and power is of interest to the strength and conditioning researcher. It appears

that training intensity with loads corresponding to 80-100% of one repetition-maximum

(1RM) (12) of sufficient training volume is most effective for increasing maximal dynamic

strength (5, 8-10,12,16). In addition, training leading to repetition failure (inability to

complete a repetition in a full range of motion due to fatigue) has been of interest within

the strength and conditioning profession. The primary role of training leading to

repetition failure has been related due to increased motor unit activation (3, 32) and

high mechanical stress with its associated gene expression and damage and repair

muscle process (11). However, some studies conclude that training to failure may not

be necessary for optimal strength gains, since fatigue reduces the force a muscle can

generate (6, 24, 33). It appears that the choice of the number of repetitions with a given

load may impact the extent of muscle damage and subsequent decrements in velocity

and force production (21). Thus, the role of resistance training to failure vs. non failure

to optimize strength and power gains is unclear.

The discrepancies between these studies may in part result from differences in

the volume and intensity of training, dependent variable selection, the pre-training

physical fitness status and muscle groups tested. Thus, it may not be feasible to

compare training programs using isokinetic or isometric single-joint training/testing

devices (6,32) with programs using dynamic multiple-joint free weight exercises (e.g.

squat or bench press) (3,24,33) or athletic movements (e.g. jumping performance or

bench throw power) (3,33). In addition, the majority of studies used untrained subjects

(6,32) with non-equated intensity and/or volume of training (24,33) during short term

3

periods (e.g. 6-9 weeks) (3,6,32-33). Therefore, we hypothesized that a training

approach not leading to repetition failure that equates volume and intensity would lead

to similar gains in maximal strength. To date, no studies have isolated the effects of

training leading to failure in a multi-group experimental design while controlling other

variables in a long-term training protocol in elite athletes.

Homeostatic hormonal changes in response to strength training have been

thought to play an important role in protein accretion, increased neurotransmitter

synthesis and strength development (17,26,28). The primary hormones studied

typically include testosterone (both total and free), human growth hormone, and cortisol

(25-27). Although the acute response of these hormones has been investigated to a

large extent, periods of substantially-increased volume or intensity have been shown to

elicit alterations (i.e., reduced total testosterone, elevated cortisol) thereby indicating

these hormones to be useful markers of chronic strength training stress (9,17,26,28). In

addition, resting insulin-like growth-factor 1 (IGF-1) and its binding proteins (i.e., IGFBP-

3) concentrations have been studied and used as markers of stress (2,4). In light of

these observations, we hypothesized that a training approach not leading to repetition

failure would result in less stress and subsequently fewer basal anabolic and catabolic

hormonal changes. Therefore, the purpose of this study was to examine the efficacy of

11 weeks of resistance training to failure vs. non-failure, followed by a 5- week peaking

period of maximal and power training for increasing strength and power of the upper

and lower body musculature. A secondary purpose was to examine the underlying

physiological changes in basal circulating anabolic/catabolic hormones.

4

METHODS

Experimental design and approach to the problem

A longitudinal research design using two different resistance training programs (e.g.

training leading to repetition failure versus not to failure) was used to partial out

differential training adaptations in hormonal changes, as well as in strength and power

gains of the upper and lower body musculature. To eliminate any possible effect of

confounding variables, several variables such as maximal relative strength (% of 1RM),

average intensity and frequency of training, type of exercise, and volume were

controlled by equating their values among the treatment groups. This was critical to the

study design as differences in overall training intensity and volume have been proposed

to influence performance adaptations (5,12). Following baseline testing, subjects were

matched according to physical characteristics and muscle strength/power indices, and

then randomly assigned to either a training to failure (RF; n=14) or training to non-failure

(NRF; n=15) training groups. As a control, a third population of subjects (C; n=13) did

not follow a set strength-training intervention, but continued practicing specific Basque

ball games and were tested before and after a 16-wk period to assess the reliability of

the observations. Testing was conducted on four occasions: before the initiation of

training (T0), after 6 wk of training (T1), after 11 wk of training (T2), and after 16 wk of

training (T3).

Subjects. A group of 42 Basque ball players, with 12.5 ± 5yr of regular training and

competition experience in Basque ball volunteered to participate in a 16-week training

study. Basque ball is a name for a variety of court sports played with the bare hand, a

racket, a wooden bat, or a basket propulsor (e.g. Jai-Alai), against a wall. Nowadays,

this game is widely played in several regions of Spain, (including the Basque Country),

as well as in several other Europe and American countries (e.g. Cuba, Mexico or

5

Argentina). Subjects’ initial characteristics are shown in Table 1. All the subjects were

members of the Spanish national team of Basque ball. The study was performed during

the first competitive period (February to June) prior to commencing the XIV World

Basque Ball championship. Each subject was informed carefully of the experimental

procedures and about possible risks and benefits of the study and subsequently signed

and institutionally-approved informed consent document. The experimental procedures

were approved by the Institutional Review Committee of the Instituto Navarro de

Deporte y Juventud, according to the declaration of Helsinki. During the five months

before the experimental period, subjects trained two times a week for Basque ball, twice

a week for strength and endurance training, and played in one official Basque ball game

per week. Basque ball practice sessions lasted 60-90 minutes and usually consisted of

various skill activities at different intensities, and 45 minutes of continuous play with only

brief interruptions by the coach. The strength training program required each subject to

perform a combination of free weight and fixed machine-weight exercises in each

session, mainly consisting of 3 sets of 6-8 repetitions, with a relative intensity of 70-80%

of 1RM. The exercises completed in each weight-training session were the supine

bench press, shoulder press, lateral pull-down, parallel squat, knee flexion, standing leg

curl, abdominal crunch and another exercise for the trunk extensors. The total duration

of each strength training session was 35-40 minutes. The running endurance program

consisted of one training session per week and lasted 20-30 min at a self-adjusted

intensity. The subjects were not taking exogenous anabolic-androgenic steroids or

other drugs (excluded by specific tests) expected to affect physical performance or

hormonal balance prior or during this study.

Testing procedures.

6

Subjects completed a 2-day experimental protocol separated by 2 days. All players

were tested on the same day and the tests were performed in the same order. During

the first testing session, each subject was assessed using two counter-movement jump

(CMJ) protocols, performed on a contact platform; 1) using bodyweight, and 2) with an

external load of 30% of body mass, administered using a weighted barbell positioned

across the shoulders. In addition, each subject was tested for 1RM and the power

output using a relative load 60% of their 1RM in bench press and parallel squat

exercises, respectively.

During the second testing session, each subject performed maximal repetitions to

failure with a submaximal load of 75% of 1RM for the bench press and parallel squat,

respectively. All of the subjects were familiar with the testing protocol, as they had been

previously tested on several occasions during the season with the same testing

procedures. The test-retest intraclass correlations coefficients for all strength and power

variables were greater than 0.91 and the coefficients of variation (CV) ranged from 0.9%

to 2.3%. Training was integrated into the test-week schedules. Body mass and percent

body fat (estimated from the thickness of seven skin-fold sites) were taken at the

beginning of the second testing session (22).

Jumping test. Subjects were asked to perform a maximal vertical counter movement

jump (CMJ) on a contact platform (Newtest OY, Oulu, Finland) without any load and

with an extra load of 30% of body mass loaded on a barbell kept on the shoulders

throughout. Using a preparatory counter-movement, subjects initiated the jump from an

extended leg position, descended to 90o knee flexion, and immediately performed an

explosive concentric action for maximal height. The jumping height was calculated from

7

the flight time. Two maximal jumps were recorded interspersed with approximately 10 s

of rest and the peak value was used for further analysis.

Bench press and parallel squat muscular performance. A detailed description of the

maximal strength and muscle power testing procedures can be found elsewhere (20). In

brief, lower and upper body maximal strength was assessed using 1RM bench press

(1RMBP) and parallel squat (1RMHS) actions. In the 1RMBP protocol, the test began with

the subject lowering the bar from a fully extended arm position above the chest until the

bar was positioned 1cm above the subject’s chest. From that position (supported by the

bottom stops of the measurement device), the subject was instructed to perform a

purely concentric action (as fast as possible) maintaining a shoulder position of 90º

abduction position. This completed a successful repetition. No bouncing or arching of

the back was allowed.

The 1RMHS began with the bar on the shoulders with the knees and hips in the

extended position. The subjects descended to the parallel to the floor thigh position. On

the verbal command “up”, the subject ascended (as fast as possible) to a full knee

extension of 180º. All tests were performed using a Smith machine in which the barbell

was attached at both ends with linear bearings allowing only vertical movements.

A warm-up for both half squat and bench press consisted of a set of 5 repetitions

at loads of 40-60% of the perceived maximum. Thereafter, 4-5 separate single attempts

were performed until 1RM was attained. The rest between maximal attempts was

always 2 min.

8

Power output of the leg and arm extensor muscles was measured in the

concentric portion of the parallel-squat and bench-presses actions using a relative load

60% of 1RM. The subject was instructed to lift the bar as fast as possible.. Two testing

trials were recorded and the best trial was taken for further analyses.

During the parallel-squat test, bar displacement, average velocity (m·s-1) and

mean power (W) were recorded by linking a rotary encoder to the end of the bar. The

rotary encoder (Computer Optical Products Inc, California, USA) recorded the position

and direction of the bar within an accuracy of 0.2mm and timed events with an accuracy

of 1 ms. Customized software (JLML I+D, Madrid, Spain) was used to calculate the

power output and average velocity for each repetition.

Parallel squat and bench press endurance test. Upper and lower body muscular

endurance was assessed at pretraining by measuring the maximal number of

repetitions until failure with 75% of 1RM for both the bench press and parallel-squat

exercises, respectively. During training (e.g. at T1, T2 and T3) muscle endurance test

were performed with the same absolute load (75% of 1RM) used at pretraining. The

subjects were asked to move the bar as fast as possible during the concentric phase of

each repetition until failure. Failure was defined at the time point when the bar ceased to

move, if the subject paused more than 1 s when the leg or arms were in the extended

position, or if the subject was unable to complete each repetition in a full range of

motion. During the first repetitions the cadence was controlled with a metronome at a

frequency of 19 Hz. As fatigue increased and performance of repetitions became

progressively more difficult, a self-selected cadence under 19Hz was allowed with the

time of rest between the repetitions remaining constant (1 second).

9

Assessment of resting hormone concentrations. Resting blood samples were collected

between 0800-0900hrs on the first testing day following a 12-hour over night fast and

abstinence from strenuous exercise for 36-48 hours. In all cases blood samples were

obtained via venipuncture from an antecubital forearm vein using a 20-gauge needle

and vacutainers®. Whole blood was centrifuged at 3000 rpm (4°C) for 15 minutes and

the resultant serum was then removed and stored at -20°C until subsequent analysis.

Circulating concentrations of total testosterone and cortisol were determined using

commercially available enzyme immunoassay (EIA) kits (Diagnostic Systems

Laboratories, Webster, TX). Plasma growth hormone (GH) concentrations were

determined using 125I liquid-phase immunoradiometric assay (IRA) (Nichols Institute

Diagnostics, San Juan, Capistrano, Calif.). Insulin-like Growth Factor-1 (IGF-1), and

IGF binding protein-3 (IGFBP-3) concentrations were established by enzyme-linked

immunosorbent assay (ELISA) kits (Diagnostic Systems Laboratories, Webster, TX)

according to the manufacturers procedures. All samples were assayed in duplicate and

were decoded only after analyses were completed (i.e. blinded analysis procedure).

The minimum EIA detection limits for total testosterone and cortisol were 0.14nmol/L,

and 2.76nmol/L, respectively. IRA detection limits for GH were 0.04ng/mL. Minimum

ELISA detection limits for IGF-1, and IGFBP-3 were 0.0013nmol/L and 0.0014nmol/L.

The coefficient of intra-assay variation was 4.4% for total testosterone, 5.1% for cortisol,

and 6.0% and 6.4% for IGF-1 and IGFBP-3, respectively. All samples were analyzed in

the same assay for each analyte. For all procedures, samples were only thawed once

before the analysis.

Training programs. All training sessions started with a general warm-up and included

cool-down periods of 5-10 min of low intensity aerobic and stretching exercises. A

trained researcher supervised each workout session carefully and recorded the

10

compliance and individual workout data during each training session so that exercise

prescriptions were properly administered during each training session (e.g. number of

repetitions, rest and velocity of movement). Compliance with the study was 100% of the

programmed sessions.

Both treatment groups were asked to train 2 times per week for 16 weeks to perform

dynamic resistance exercise from 45 to 60 minutes per session. A minimum of 2 days

elapsed between 2 consecutive training sessions. Resistance exercise choice and order

were identical for the two treatment groups. During the whole training period, the core

exercises were the parallel-squat and bench press, in addition to supplementary

strengthening exercises for selected muscle groups (shoulder press, lateral pull-down,

abdominal crunch, trunk extension, and standing leg curl). In addition, the training

program included ballistic exercises (i.e. counter-movement vertical jumps, loaded

vertical jumps, sprints, and various throwing exercises with a 1 kg ball) during the last 5

peaking weeks of explosive strength training (from T2 to T3). Subjects performed all

free-weight bench-press and squat training using a standard 20-kg barbell.

Both groups performed a 16-wk periodized resistance training program divided into

three periods of 5-6 wk. One group performed high-fatigue strength training exercise to

failure (RF), whereas the other performed the same volume and intensity but did not

complete sets leading to failure (NRF). The assigned training intensities were gradually

increased during the course of the 16-week training period on the basis of the athletes’

10RM and 6RM testing, using a repetition maximum approach. In the RF training group,

the load was reduced and the training continued immediately when the load was

paused for more than 1 s or if the subject was unable to reach the full extension position

of the arms or leg. The training load was reduced 3-4 times in a training session during

RF training, whereas load remained constant in the NRF group.

11

During the first six weeks of training (from T0 to T1), the RF group trained with 3 sets of

10RM for the bench press and 80% of 10RM for the parallel-squat, whereas the NRF

group performed 6 sets of 5 repetitions at a similar intensity (10RM). During the mid 5

weeks of training (from T1 to T2), subjects in the RF group trained at 6RM and 80% of

6RM and performed 3 sets for the bench press and parallel-squat, respectively,

whereas the NRF group performed 6 sets of 3 repetitions at a similar intensity. During

the final 5 weeks of training (from T2 to T3), both groups trained at 85%-90% of 1RM

(~5RM), 2-4 repetitions per set and performed 3 sets for both upper and lower extremity

exercises and performed the ballistic training program (i.e. vertical countermovement

jumps, loaded vertical jumps, sprint runs and various throwing exercises with ball of

1kg). In addition, the subjects performed bench press sets with loads ranging from 40%-

45% of 1RM. During this phase, subjects performed 3-4 repetitions per set and 3-5 sets

of each exercise in a ballistic manner. Approximately 2-min rest periods were allowed

between each set and each exercise. This ballistic strength training was included

because it has been shown the most effective way to enhance explosive strength and

speed (5). During the first 11 weeks (from T0 to T2), these different trainings protocols

(RF vs. NRF) enabled comparison of two equal volume and relative training intensity

programs on hormonal responses and muscle power/strength training-induced changes

of the upper and lower extremity muscles. In addition, the last five peaking weeks (from

T2 to T3), was used to produce a similar “rebound effect” for all groups and to avoid

overreaching (8-10,12).

During the squat lifts and bench press exercises, the subjects were instructed carefully

to perform all the concentric actions at the highest possible speed, The eccentric

actions were performed at low velocity during the ‘‘lowering’’ phase of the movement.

Apart from the formal requirements of this study, both groups performed similar whole-

12

body strength training programs (60-70% of 1RM, 8-10 repetitions) involving selected

muscle groups (shoulder press, lateral pull-down, for the upper body; abdominal crunch

and another exercise for the trunk extensors; and the standing leg curl).

Statistical analyses

Standard statistical methods were used for the calculation of the means and standard

deviations (SD). One-way analysis of variance (ANOVA) was used to determine any

differences among the three groups´ initial strength, power and hormonal profile. The

training-related effects were assessed using a two-way ANOVA with repeated

measures (groups x time). When a significant F-value was achieved, Sheffé post hoc

procedures were performed to locate the pairwise differences between the means.

Selected absolute changes were analyzed via one-way analysis of variance. Statistical

power calculations for this study ranged from 0.75 to 0.80. The p<0.05 criterion was

used for establishing statistical significance.

RESULTS

Body Composition. At the beginning of the training program, no significant differences

were observed between the groups in age, height, body mass, or percent body fat. A

significant decrease in percent body fat was observed at T3 for NRF compared with T0,

and T1, as well as at T3 for RF compared with T0 and T2. A significant decrease in

body mass was observed at T3 for RF whereas no significant differences in body mass

were observed for NRF at any point (Table 1).

Table 1 here

Maximal muscle strength and power. The maximal strength results are presented in

Figure 1. No significant differences were observed between the groups in 1RMHS and

1RMBP at T0. Significant increases took place in 1RMBP for the RF and NRF groups at

T1 and T2. No significant differences were observed in the magnitude of the increase in

13

1RMBP between RF and NRF at T1 (9% and 8%) and T2 (20% and 20%), respectively

(Figure 1A). During the peaking phase (from T2 to T3), no significant changes occurred

in 1RMBP in either RF or NRF. Significant increases in 1RMHS were observed in the RF

and NRF groups at T1 and T2. No significant differences were observed in the

magnitude of the increase in 1RMHS between RF and NRF at T1 (9% and 10% ) and T2

(19% and 20%) compared with T0, as well as at T3 (3% and 3%) compared with T2,

respectively (Figure 1B). No significant differences for any variable were observed in

the Control group over the training period.

Figures 1A and 1B here

No significant differences were observed between the groups in muscle power

output of either the lower or upper extremity at T0. Significant increases were observed

in muscle power output for 60% of 1RMBP for the RF and NRF groups at T2. No

significant differences were observed in the magnitude of the increase between RF and

NRF at T2 (20% and 23%) compared with T0, respectively (Figure 2A). During the

peaking phase (from T2 to T3), no significant changes occurred in muscle power output

for 60% of 1RMBP either in RF or NRF.

Significant increases were observed in muscle power output at the 60% of

1RMHS for the RF and NRF groups at T1 and T2 compared with T0 and T1,

respectively. No significant differences were observed in the magnitude of the increase

in muscle power output at the 60% of 1RMHS between RF and NRF at T2 (26% and

29%) compared with T0 (Figure 2B). However, only NRF showed a significant increase

at T3 compared with T2

Figures 2A and 2B here

Significant increases were observed in the height of CMJ and CMJ30% for the

RF and NRF groups at T2 compared with T0. No significant differences for any lower or

14

upper body maximal muscle power variables were observed in the Control group over

the training period (Figure 3).

Figure 3 here

The number of repetitions performed with 75% of 1RMBP increased significantly

at T1 and T2 in both RF and NRF. Significant group x time interaction was observed for

the number of repetitions performed with 75% of 1RMBP, with a significantly larger

(p<0.01) magnitude of increase for RF at T1 (46%) and T2 (85%) compared with T0

than that recorded in NRF (28% and 69%, respectively) (Figure 4A). Only RF showed a

significant increase at T3 compared with T2.

The number of repetitions performed with 75% of 1RM for the parallel squat

increased significantly at T2 compared with T0 in both RF and NRF. No significant

differences were observed in the magnitude of increase between RF and NRF at T2

(66% and 69%, respectively), compared with T0, as well as at T3 compared with T0

(Figure 4B).

Figure 4A and 4B here

Hormonal Data. Resting serum hormonal data are presented in Figures 5-8. No

significant differences were observed between the groups in hormonal data at T0

Serum total testosterone concentrations were significantly elevated in NRF at T2

compared with T0 and T1. There was a significant group x time interaction, with a

significantly larger (p<0.05) mean improvement in the serum total testosterone

concentration for NRF at T2 compared with T0 and T1 (6% and 12%; p<0.05,

respectively) than that recorded in RF (0% and -1%) (Figure 5). In addition, there was a

significant group x time interaction with a larger (p<0.05) magnitude of reductions in

serum total testosterone concentration for NRF at T3 (-11%) compared with T2 than

15

that recorded in RF (2%). Serum cortisol concentrations were significantly reduced in

NRF at T2 compared with T0, while in RF a tendency (p=0.07) for elevation was

observed at T2 and T3 compared with T0. In addition, there was a significant group x

time interaction with a larger (p<0.05-0.01) magnitude of reductions in NRF at T2 and

T3 compared with T0 than that recorded in RF (Figure 6). No significant changes were

observed at any point in the testosterone/cortisol ratio. Serum IGF-1 concentrations

decreased significantly in RF at T2 and T3 compared with T0, T1, and T2 respectively

(Figure 7). Serum IGFBP-3 concentrations were elevated significantly in RF at T1, T2

and T3 compared with T0, while NRF only showed a significant elevation at T3 (Figure

. No significant differences in serum GH were observed in either training group at any

time point. In addition, no significant hormonal changes were observed in the C group at

any time point.

Figure 5-8 here

DISCUSSION

The major findings of this study were that after the 11 wk training period (from T0

to T2): 1) similar gains in bench press 1RM, parallel squat 1RM, muscle power output

of the arm and leg extensor muscles and maximal number of repetitions performed

during parallel squat were observed between RF and NRF; and 2) the RF group

experienced larger gains in the maximal number of repetitions performed during the

bench press. During the peaking phase (from T2 to T3): 3) larger gains in muscle power

output of the lower extremity were observed after the NRF training approach and, 4)

larger gains in the maximal number of repetitions performed during the bench press

after RF training approach. In addition, long-term strength training leading to repetition

to failure resulted in reductions in resting serum IGF-1 concentrations and elevations in

16

IGFBP-3, whereas the NRF group experienced an elevation in resting serum

testosterone concentrations and reductions in cortisol. These data indicated that

performing repetitions not to failure provided favorable conditions for improving muscle

power whereas performing sets to failure resulted in greater gains in local muscular

endurance.

Few studies have isolated the effects of training leading to repetition failure using

a multi-group experimental design, while controlling other variables, in resistancetrained

individuals (3,6,24,32,33). These studies have shown that short-term training (<9

weeks) leading to repetition failure produces greater improvements in strength (3,32), or

may not be necessary for optimal strength gains (6,32-33) when compared with a nontraining

to repetition failure approach. The discrepancies between the results of these

studies may in part result from differences with respect to the volume and intensity of

training, dependent variable selection, the pre-training physical fitness status, and

muscle groups tested. Thus, it may not be feasible to compare training programs using

isokinetic or isometric single-joint training/testing devices (6-32) with training programs

using dynamic multi-joint free weight (e.g. squat or bench press) (3,32-33) or power

(e.g. vertical jumps, ballistic bench press (3-33) exercises. In addition, the majority of

studies have used untrained subjects (6-32) and involved a non-equated high intensity

and/or volume of training (24,33) during short term periods (e.g. 6-9 weeks)(3,6,32-33).

Our results support previous studies showing that training to failure did not result in

greater gains in strength in resistance-trained men. Therefore, the role of performing

sets to failure (and how many) requires further research in the strength-trained

population.

Strength training consisting of repetitions performed to failure has been shown to

lead to greater strength gains in some studies. Rooney et al (32) showed that untrained

17

subjects who performed repetitions to failure without rest intervals between repetitions

attained significantly greater (56%) mean increases in dynamic strength of the elbow

flexors than subjects training without assistance but permitted resting for 30 seconds

between repetitions (41%) during a short-term training program (6 weeks). Both training

groups performed the same number of lifts at the same relative intensity. Likewise,

Drinkwater and coworkers (3) reported greater bench press strength and power gains

following 6 wks of training consisting of training to failure with 4 sets of 6 repetitions

every 260 seconds (9.5% and 10.6%, respectively) compared to training with 8 sets of 3

repetitions every 113 seconds (5% and 6.8%, respectively). Both studies suggested that

training to failure was a critical strength training stimulus. The authors hypothesized that

greater accumulation of metabolites (with no rest in between repetitions) and to recruit

additional motor units in order to maintain force output as fatigue increases (3,21,32)

could potentially maximize strength gains, which in theory would support training to

muscular failure. However, it is unclear whether motor unit activity is enhanced and the

impact of accumulative fatigue potentially resulting in overtraining needs to be

considered. Thus, evidence does support training to failure but it is unclear how to

optimally include it into program design (i.e., number of sets per workout or number of

repetitions performed to failure). On the contrary, other studies have shown that training

to failure may not be necessary for optimal training gains (6,24,33). However, the

experimental groups were not carefully equated and controlled for volume and intensity.

The use of the upper and lower body maximal strength training followed by a 5-

week peaking period of maximal/power training in the present study is unique and

provides meaningful data for program design in strength/power athletes. Performing

each set not to muscular failure led to larger gains in muscle power output of the lower

extremity. These data indicate that during the peaking phase (from T2 to T3), after a

18

training period leading to repetition to failure does not provide a better stimulus for

improving muscle power and may lead to reduced power output during long-term

strength training. Maximum effort to each repetition is critical to power training. Many

programs targeting maximal power (e.g. weightlifting) perform few explosive repetitions

per set. The rationale is to minimize fatigue so maximal effort (and power output) can

be applied to each repetition (21). Our results indirectly support this training philosophy

as greater gains in power were observed when training was not performed to muscular

failure.

A different pattern of strength and power gains was observed when performing

repetitions to failure between the upper and leg extremity muscles. Similar to previous

studies (13), these differences may have been explained by a difference in the initial

level of conditioning between knee extensors and upper body muscles, and may be

related to differences in the pattern and/or intensity of daily physical use in normal life

(13), as well as in practicing Basque ball training. The quadriceps muscle, owing to its

weight bearing role during habitual physical activity, would be more likely to be at a

higher initial level of conditioning than the upper body muscles, which have been shown

to be used less frequently. From our results, it appears that the use of training not to

failure might be more efficient for training the upper and specially the lower extensor

muscles. In addition, one may hypothesize that the aerobic nature of the Basque ball

training and games in addition to repetition to failure approach might interfere with

optimal gains in maximal and explosive strength in the legs (13), especially during

prolonged training periods.

The results of the present study demonstrated that training to failure did provide

an advantage, for upper body musculature during maximal number of repetitions

performed for the bench press, for improving local muscular endurance. In this case,

19

training for enhanced muscle endurance implies the athlete needs to train in a semi- to

fatigued state. Thus, training to failure for upper-body musculature may provide a novel

stimulus as the greater fatigue encountered may further enhance muscle endurance. It

is unclear as to why similar results were not observed during lower-body muscle

endurance assessment (e.g., maximal parallel-squat repetitions). It may be argued that

the lower extremities in these elite athletes were highly conditioned. Thus, the added

effects of training to failure were not evident based on the level of conditioning.

However, further research is warranted to examine the role of training to failure in

different muscle groups.

Examination of resting concentrations of anabolic and catabolic hormones may

provide insight as to the physiological mechanisms involved for higher levels of

muscular performance and subsequent adaptations. Large increases in the volume

and/or intensity of resistance training may overstress the neuroendocrine system

leading to altered circulating hormonal concentrations (9). However, less is known

concerning the effects of resistance training to failure vs. not resistance training to

failure on resting hormonal concentrations. It may be hypothesized that performing each

set to failure may increase the risk of overtraining over long-term periods. Thus, a

change in hormonal profile may ensue.

No significant differences in resting serum GH concentrations were observed in

either training group in the present study. This was not surprising considering that

resting GH concentrations typically do not change during traditional strength training

(25), despite the enhanced adaptation ability for tissue remodeling to acute exerciseinduced

response after resistance exercise (27). Our data support previous

investigations demonstrating a lack of change in resting GH concentrations. Although

overnight pulsatility profiles and other molecular weight GH variants were not measured

20

in the present investigation, these have been shown to be altered by high volume

strength training (29) and require further investigation..

The response of IGF-1 to chronic resistance training is less clear. Short-term

strength training studies have reported no change in resting concentration of IGF-1 (25-

27) whereas long-term studies in men and women have reported significant elevations

in resting IGF-1 (2,23,28). Acute overreaching, resulting from a dramatic increase in

volume and/or intensity of training, has been shown to reduce IGF-1 concentrations by

11% (30), but return to baseline when normal training resumed over the next cycle (30).

In the present study, resting serum IGF-1 concentrations were significantly reduced in

RF at T2 and T3 compared with T0, T1, and T2 respectively, whereas no significant

reductions were observed in the NRF group. Collectively, our results indicate that

chronic IGF-1 adaptations following resistance training may be mediated, in part, by

volume and intensity manipulation (26,30).

IGF-1 concentrations are highly regulated by GH secretion. Although the

mechanisms of GH-activated IGF-1 gene expression remain unclear, the GH

superfamily stimulates IGF-1 secretion by the liver and other tissues. Although no

resting GH changes were observed in the present study, it is possible that nonmeasured

alterations in GH pulsatility (i.e., overnight or at a time of day not examined in

the present study) or other non-22 kD molecular weight GH variants could have

occurred. Nindl et al. (29) showed reduced GH pulsatility overnight following highvolume

resistance exercise presumably due to the high level of stress. In addition,

delayed secretion of IGF-1, i.e., 3-9 hours, following GH-stimulated messenger RNA

synthesis has been shown (26). Therefore, the IGF-1 concentrations observed in the

present study may have reflected a delayed response in conjunction with GH alterations

(e.g., reduced pulsatility) which could explain a reduction in IGF-1 independent of GH

21

changes considering that each hormone was sampled at the same time point.

Nevertheless. the higher stress of training may have led to reduced IGF-1

concentrations in the RF group.

Few studies have examined chronic circulating concentrations of IGFBP-3

following long-term resistance training. The reduction in resting IGF-1 observed in RF

occurred parallel to elevations in serum IGFBP-3 concentrations with only small

elevations observed at T3 in the NRF group in the present study. Interestingly, Elloumi

et al (4) have proposed that a reduction in resting IGFBP-3 may be used as a marker of

overtraining. Borst et al. (2) demonstrated a reduction in IGFBP-3 concentrations that

paralleled a concomitant elevation in IGF-1 concentrations following a 25-week training

period. Based on our data, it may be hypothesized that the elevation in IGFBP-3 may

have been compensatory to accommodate the reduction in IGF-1 in order to preserve

IGF availability (26). However, further research is required to examine the impact of

resistance training intensity and volume manipulation on training-related changes in

IGFBPs.

Circulating testosterone and cortisol have been proposed as physiological

markers to evaluate the tissue-remodeling process during a strength training period

(17,26). In the present study, an elevation in total testosterone was observed at T2 in

NRF whereas no differences were observed in RF. It is unclear as to why an elevation

was only observed at T2 in NRF. However, changes in resting total testosterone

concentrations have shown variable responses such that no apparent consistent

patterns have been observed. Rather, it appears that resting concentrations reflect the

current state of muscle tissue (or perhaps the response to the previous workout

performed before blood sampling) such that elevations or reductions may occur at

various stages depending on the volume and intensity of the training stimulus (17).

22

Elevated resting serum concentrations of testosterone (25,28) have been reported

during resistance training studies, whereas several studies have shown reductions (1).

In contrast, several studies have shown no change in testosterone (15,19). In addition,

resting total testosterone concentrations have been shown moderately to correlate with

strength performance (31), thereby suggesting that the acute response may play a more

prominent role. Therefore, the lack of change observed in RF was not surprising;

however, the elevation at T2 in NRF may have reflected this inconsistency as a

transient response to the previous workouts. Lastly, the free testosterone response was

not measured in the present study. Therefore, any potential changes in the biologicallyactive

form of testosterone were not identified.

Significant reductions were observed at T2 in NRF in resting serum cortisol

concentrations whereas no changes were observed in RF. In addition, there were no

changes observed in the testosterone/cortisol ratio. Elevations (18), reductions (15,28),

and no changes (16-17) in resting cortisol concentrations have been reported during

resistance training. Thus, the cortisol response may also show great inter-individual

variability. It may be hypothesized that not training to failure may reduce the overall

stress of resistance training; consequently the cortisol response may be attenuated, and

therefore, the anabolic status of skeletal muscle enhanced. However, although is

attractive the use of the testosterone/cortisol ratio as a common marker used to indicate

a potential anabolic or catabolic state, positively related with performance improvements

it appears to be an oversimplification. In fact, It has been suggested that a transient

drop in the testosterone/cortisol ratio below 45% cannot be interpreted as a sign of

overstrain or neuroendocrine dysfunction and may not be associated with decreased

performance (9,14,26). Indeed, in some circumstances it may be related to a temporary

positive stress stimulus and may even be expressed in a beneficial effect on

23

performance (14). Thus, some authors have shown a decrease in the

testosterone/cortisol ratio or the free testosterone/cortisol ratio to be associated with an

increase (8-9,34) or no change in performance (16). Our data support this hypothesis to

a certain extent. Although a cortisol reduction was observed in NRF, no changes were

observed in the testosterone/cortisol ratio. Thus, the use of the testosterone/cortisol

ration remains questionable.

In conclusion, both training to failure and not to training failure resulted in similar

gains in 1RM strength, muscle power output of the arm and leg extensor muscles, and

maximal number of repetitions performed during the parallel squat. However, during the

peaking phase (from T2 to T3) larger gains in muscle power output of the lower

extremity were observed after the preceding NRF training approach. Training to failure

resulted in larger gains in the number of repetitions performed in the bench press.

Strength training leading to repetition to failure resulted in reductions in resting

concentrations of IGF-1 and elevations in IGFBP-3, whereas not training to failure

resulted in reduced resting cortisol concentrations, an elevation in resting serum total

concentration at T2, and an elevation IGFGB-3. Briefly, this investigation demonstrated

a potential beneficial stimulus of resistance training not leading to failure for improving

strength and power, especially during the subsequent peaking training period.

However, training leading to repetition failure seemed to more beneficial for enhancing

upper-body local muscular endurance.

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27

RF NRF Control

(N=14) (N=15) (N=13)

Age (yr) 24.8 + 2.9 23.9 + 1.9 24.4 + 2.1

Height (m) 1.80 + 0.01 1.81 + 0.01 1.80 + 0.02

Body mass (Kg)

T0 81.1 ± 4,2 80.5 ± 7.4 81.1 ± 7.2

T1 80.7 ± 4,4 80.3 ± 7.5

T2 81.5 ± 5,1 80.9 ± 7.6

T3 80.3 ± 3,9$ 80.1 ± 7.2 82.4 ± 6.7

Body fat (%)

T0 13.4 ± 4,1 11 ± 3.4 13 ± 5.2

T1 13.5 ± 3,7 10.8 ± 3.2

T2 12.7 ± 3,2 11.1 ± 3.4

T3 12.1 ± 3,8*$ 10.3 ± 3.1*# 13.1 ± 5.2

BMI

T0 24.9 ± 2,5 24.6 ± 1.9 25.2 + 2.3

T1 25 ± 2,5 24.5 ± 1.8

T2 24.8 ± 2,3 24.6 ± 1.9

T3 24.6 ± 2,3 24.4 ± 1.8 25.1 + 9.2

Table 1. Physical characteristics during the experimental period. * p<0.05 from the

corresponding time point T0. # p<0.05 from the corresponding time point T1. $ p<0.05

from the corresponding time point T2. NRF – non repetition to failure group, RF -

repetition to failure group, C – control group. Data presented are means ± SD.

28

(A)

0

20

40

60

80

100

120

140

1 2 3

Bench press 1RM (Kg)

T0

T1

T2

T3

C RF NRF

*

#*

#*

*

#*

#*

0

50

100

150

200

250

1 2 3

Parallel-Squat 1RM (Kg)

TO

T1

T2

T3

C RF NRF

*

#*

$#*

#*

*

$#*

(

Figure 1. Maximal bench press (A) and parallel squat strength ( during the experimental

period. * p<0.05 from the corresponding time point T0. # p<0.05 from the corresponding

time point T1. $ p<0.05 from the corresponding time point T2. NRF – no repetition to failure

group, RF - repetition to failure group, C – control group. Data presented are means ± SD.

29

(A)

0

100

200

300

400

500

600

1 2 3

Bench press 60% Power (W)

T0

T1

T2

T3

C RF NRF

*

#*

*

#*

(

0

200

400

600

800

1000

1200

1 2 3

Half-Squat 60% Power (W)

TO

T1

T2

T3

C RF NRF

*

#*

#*

#*

#*

$,†

#*

*

Figure 2. Bench press (A) and parallel squat ( muscle power output during the

experimental period. * p<0.05 from the corresponding time point T0. # p<0.05 from the

corresponding time point T1. $ p<0.05 from the corresponding time point T2. † p<0.05 from

relative change at point time T1 between the groups. NRF – no repetition to failure group,

RF - repetition to failure group, C – control group. Data presented are means ± SD.

30

(A)

0

10

20

30

40

50

60

1 2 3

Height in CMJ (cm)

TO

T1

T2

T3

C RF NRF

*

#*

* *

(

0

5

10

15

20

25

30

35

40

1 2 3

Height in CMJ 30% of BM (cm)

TO

T1

T2

T3

C RF NRF

* * *

#*

Figure 3. Height in the countermovement jump (CMJ) without load (A) and with extra load of

30% of body mass ( during the experimental period. * p<0.05 from the corresponding

time point T0. # p<0.05 from the corresponding time point T1. NRF – no repetition to failure

group, RF - repetition to failure group, C – control group. Data presented are means ± SD.

31

(A)

0

5

10

15

20

25

1 2 3

Bench press reps to Failure (75% of 1RM)

T0

T1

T2

T3

C RF NRF

@*

@#*

$#*

*

*

#

*

#

(

0

5

10

15

20

25

30

1 2 3

Half-Squat reps to Failure (75% of 1RM)

TO

T1

T2

T3

C RF NRF

#*

#*

#*

#*

Figure 4. Maximal number of repetitions until failure with 75% of 1RM for both the bench

press (A) and parallel-squat ( exercises during the experimental period. * p<0.05 from the

corresponding time point T0. # p<0.05 from the corresponding time point T1. $ p<0.05 from

the corresponding time point T2. @ p<0.05 from relative change at time point T0 between

the groups. NRF – no repetition to failure group, RF - repetition to failure group, C – control

group. Data presented are means ± SD.

32

0

5

10

15

20

25

30

35

40

45

1 2 3

Total Testosterone (nmol/l)

T0

T1

T2

T3

C RF NRF

* #

@ †

Figure 5. Resting serum total testosterone concentrations during the experimental period. *

p<0.05 from the corresponding time point T0. # p<0.05 from the corresponding time point

T1. @ p<0.05 from relative change at time point T0 between the groups. † p<0.05 from

relative change at point time T1 between the groups. NRF – no repetition to failure group,

RF - repetition to failure group, C – control group. Data presented are means ± SD.

33

0

100

200

300

400

500

600

700

1 2 3

Cortisol (nmol/l)

T0

T1

T2

T3

C RF NRF

@*

@

Figure 6. Resting serum cortisol concentrations during the experimental period. * p<0.05

from the corresponding time point T0. @ p<0.05 from relative change at time point T0

between the groups. NRF – no repetition to failure group, RF - repetition to failure group, C

– control group. Data presented are means ± SD.

34

0

10

20

30

40

50

60

70

80

1 2 3

IGF-1 (nmol/l)

T0

T1

T2

T3

C RF NRF

#*

$

Figure 7. Resting serum Insulin-like Growth Factor-1 (IGF-1) concentrations during the

experimental period. * p<0.05 from the corresponding time point T0. # p<0.05 from the

corresponding time point T1. $ p<0.05 from the corresponding time point T2. NRF – no

repetition to failure group, RF - repetition to failure group, C – control group. Data

presented are means ± SD.

35

0

0.5

1

1.5

2

2.5

3

3.5

1 2 3

IGFBP-3 (nmol/l)

T0

T1

T2

T3

C RF NRF

*

* * *

Figure 8. Resting serum Insulin-like binding protein-3 (IGFBP-3) concentrations during the

experimental period. * p<0.05 from the corresponding time point T0. NRF – non repetition

to failure group, RF - repetition to failure group, C – control group. Data presented are

means ± SD.

[__ORACULO__]

Muito obrigado pela colaboração Baby o Foca, caminhando nessa trilha do compartilhamento de conhecimento temos todos a ganhar.

Se não for muito incômodo, gostaria de ter em mãos esse artigo.

metalcentrismo@yahoo.com.br

Vou postar algo na lista de Discussão do Gease e ver qual o posicionamento do Paulo Gentil sobre esse achado.