Eccentric Training Interventions and Team Sport Athletes


Journal of

Functional Morphology 
and Kinesiology

Review

Eccentric Training Interventions and Team
Sport Athletes

Conor McNeill 1,* , C. Martyn Beaven 1, Daniel T. McMaster 1,2 and Nicholas Gill 1,2

1 Te Huataki Waiora School of Health, Adams Centre, The University of Waikato, 3116 Tauranga,
New Zealand; martyn.beaven@waikato.ac.nz (M.B.); dmcmaste@waikato.ac.nz (D.T.M.);
nicholas.gill@nzrugby.co.nz (N.G.)

2 New Zealand Rugby Union, 6011 Wellington, New Zealand
* Correspondence: cmfm1@students.waikato.ac.nz

Received: 29 August 2019; Accepted: 23 September 2019; Published: 27 September 2019
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Abstract: Eccentric resistance training has been shown to improve performance outcomes in a range
of populations, making it a popular choice for practitioners. Evidence suggests that neuromuscular
adaptations resulting from eccentric overload (EO) and accentuated eccentric loading (AEL) methods
could benefit athletic populations competing in team sports. The purpose of this review was to
determine the effects of eccentric resistance training on performance qualities in trained male team
sport athletes. A systematic review was conducted using electronic databases PubMed, SPORTDiscus
and Web of Science in May 2019. The literature search resulted in 1402 initial articles, with 14 included
in the final analysis. Variables related to strength, speed, power and change of direction ability
were extracted and effect sizes were calculated with a correction for small sample size. Trivial,
moderate and large effect sizes were reported for strength (−0.17 to 1.67), speed (−0.08 to 1.06), power
(0.27 to 1.63) and change of direction (0.48 to 1.46) outcomes. Eccentric resistance training appears to
be an effective stimulus for developing neuromuscular qualities in trained male team sport athletes.
However, the range of effect sizes, testing protocols and training interventions suggest that more
research is needed to better implement this type of training in athletic populations.

Keywords: eccentric; overload; training; athlete; team

1. Introduction

There is growing evidence in the literature that suggests eccentric resistance training is an effective
stimulus for enhancing physical performance [1]. During an eccentric contraction, kinetic energy is
transferred and stored as elastic potential energy within the muscle tendon unit [2], which can acutely
enhance force production in the subsequent concentric contraction through the stretch-shortening
cycle [3–5]. Training methods that take advantage of the eccentric phase have been referred to in
the literature as eccentric overload (EO) and accentuated eccentric loading (AEL) [6–8]. These terms
refer to the manipulation of force and time variables during the eccentric phase of exercise through
the application of relatively high force or high velocity [9–11]. Longitudinal eccentric training may
benefit team sport athletes who are required to produce force quickly during rapid movement through
favourable neuromuscular and morphological adaptations [12]. The purpose of this systematic
review was to investigate the effects of EO and AEL on performance qualities in trained male team
sport athletes.

J. Funct. Morphol. Kinesiol. 2019, 4, 67; doi:10.3390/jfmk4040067 www.mdpi.com/journal/jfmk

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J. Funct. Morphol. Kinesiol. 2019, 4, 67 2 of 18

2. Materials and Methods

2.1. Search Strategy

One reviewer conducted the literature search according to the Preferred Reporting Items for
Systematic Reviews and Meta-Analyses (PRISMA) guidelines for systematic reviews [13]. The electronic
databases PubMed, SPORTDiscus and Web of Science were searched up until 23 May 2019. No date
ranges were imposed on the individual databases. Search terms included: ‘eccentric exercise’, ‘eccentric
training’, ‘eccentric contraction’, ‘strength’, ‘power ’, ‘speed’, ‘velocity’, ‘force’, ‘hypertrophy’, ‘athletes’,
and ‘team sports’. Boolean operators ‘AND’ and ‘OR’ were used to combine key search terms. When
applicable, filters were used during the initial literature search to identify relevant articles. Full-text
articles from peer-reviewed academic journals written in English were included, while articles involving
animal (non-human), youth (<17 years old), and older (>44 years old) participants were excluded.

Once the initial search had been conducted, the articles were stored in reference manager software
(Zotero, version 5.0.52, Corporation for Digital Scholarship, Vienna, VA, USA). Duplicate articles were
manually reviewed and merged using the included “Duplicate Items” function. From the company’s
website, “Zotero assesses records for duplicates based on the title, DOI, and ISBN fields to determine
duplicates. If these fields match (or are absent), Zotero also compares the years of publication (if they
are within a year of each other) and author/creator lists (if at least one author last name plus first
initial matches) to determine duplicates” (www.zotero.org). The titles and abstracts of the remaining
records were then screened. Articles not meeting the inclusion/exclusion criteria were removed, and
the remaining records were assessed. Those full-text studies meeting the eligibility criteria were
then assessed for inclusion in the review. An additional search was carried out using the reference
lists of articles; those records identified through the additional search were then subjected to the
same systematic process. Finally, all of the studies deemed to meet the criteria were assessed for
methodological quality and included in the review.

2.2. Eligibility Criteria

Studies meeting the following inclusion criteria were included in the review:

• Participants were healthy, competitive, male team sport athletes above the recreational level (i.e.,
professional, national, elite) and were between 17 and 35 years of age.

• The sports included in the review following the screening process were basketball, soccer, handball,
and rugby union.

• Studies investigated the effects of longitudinal (≥three weeks) EO training interventions. Eccentric
training load (volume, intensity) needed to be quantified.

• Data on at least one of the following outcome measures were reported: strength (e.g., 1RM,
maximal voluntary contraction, peak torque), maximum sprint times (e.g., 10 m, 20 m, 40 m sprint),
power (e.g., jump height, rate of force development), and change of direction (e.g., T-test, cutting).

Studies with the following exclusion criteria were not included in the review:

• Participants were individual sport athletes (i.e., skiing, cycling, running) or untrained (students or
with less than six months training experience). Studies not listing the training experience/sport
status of participants were also excluded.

• Studies investigating male and female athletes were excluded if the results were not
reported separately.

• The training intervention included injured participants.
• Supplements or ergogenic aids were used in the intervention.

www.zotero.org


J. Funct. Morphol. Kinesiol. 2019, 4, 67 3 of 18

2.3. Study Selection

The eligibility assessment was performed in an unblinded manner by a single reviewer. The study
selection process used is visually represented by Figure 1. Those studies identified through the initial
search outlined above or identified through reference lists were then screened for eligibility criteria.
If there was uncertainty about whether a study met the standard for inclusion, an additional reviewer
(C. Martyn Beaven) was consulted and an agreement was reached (n = 5).

J. Funct. Morphol. Kinesiol. 2019, 4, x FOR PEER REVIEW 3 of 19 

2.3. Study Selection 

The eligibility assessment was performed in an unblinded manner by a single reviewer. The 
study selection process used is visually represented by Figure 1. Those studies identified through the 
initial search outlined above or identified through reference lists were then screened for eligibility 
criteria. If there was uncertainty about whether a study met the standard for inclusion, an additional 
reviewer (C. Martyn Beaven) was consulted and an agreement was reached (n = 5). 

 
Figure 1. Flow chart of the literature search process using the Preferred Reporting Items for Systematic 
Reviews and Meta-Analyses (PRISMA) guidelines. 

2.4. Analysis of Results  

The remaining 14 articles were evaluated using a 10 item scale designed for exercise training 
studies [14]. The goal of the scale was to assess the quality of strength and conditioning interventions, 
which might otherwise score poorly in assessments designed for healthcare research and 
interventions. This scale includes a 10 item scale (range 0 to 20) designed for rating the 
methodological quality of exercise training studies (Table 1). Two authors conducted the quality 
assessment independently; any discrepancies between the scores were discussed and a consensus 
was reached (n = 8). The score for each criterion was as follows: 0 = “clearly no”, 1 = “maybe”, and 2 
= “clearly yes”. 

The items included:  

1 Inclusion criteria were clearly stated;  
2 Subjects were randomly allocated to groups;  
3 Intervention was clearly defined;  
4 Groups were tested for similarity at baseline;  
5 Use of a control group;  
6 Outcome variables were clearly defined;  
7 Assessments were practically useful;  
8 Duration of intervention was practically useful;  
9 Between-group statistical analysis was appropriate;  
10 Point measures of variability. 

 

Figure 1. Flow chart of the literature search process using the Preferred Reporting Items for Systematic
Reviews and Meta-Analyses (PRISMA) guidelines.

2.4. Analysis of Results

The remaining 14 articles were evaluated using a 10 item scale designed for exercise training
studies [14]. The goal of the scale was to assess the quality of strength and conditioning interventions,
which might otherwise score poorly in assessments designed for healthcare research and interventions.
This scale includes a 10 item scale (range 0 to 20) designed for rating the methodological quality of
exercise training studies (Table 1). Two authors conducted the quality assessment independently; any
discrepancies between the scores were discussed and a consensus was reached (n = 8). The score for
each criterion was as follows: 0 = “clearly no”, 1 = “maybe”, and 2 = “clearly yes”.

The items included:

1. Inclusion criteria were clearly stated;
2. Subjects were randomly allocated to groups;
3. Intervention was clearly defined;
4. Groups were tested for similarity at baseline;
5. Use of a control group;
6. Outcome variables were clearly defined;
7. Assessments were practically useful;
8. Duration of intervention was practically useful;
9. Between-group statistical analysis was appropriate;
10. Point measures of variability.



J. Funct. Morphol. Kinesiol. 2019, 4, 67 4 of 18

Table 1. Quality assessment for each study included in the analysis.

Author
Inclusion
Criteria

Random
Allocation

Intervention
Defined

Groups Tested
for Similarity at

Baseline

Control
Group

Outcome
Variables
Defined

Assessments
Practically

Useful

Duration of
Intervention

Practically Useful

Between-Group
Stats Analysis
Appropriate

Point
Measures of
Variability

Askling et al. (2003) 2 2 2 2 2 2 1 2 2 2
Brughelli et al. (2010) 1 2 1 1 2 2 1 2 2 2

Cook et al. (2013) 0 2 2 1 2 2 2 2 1 2
de Hoyo et al. (2015) 2 0 2 0 2 2 2 2 2 2
de Hoyo et al. (2016) 2 0 2 0 2 2 0 2 2 2

Iga et al. (2012) 0 2 2 2 2 2 1 2 2 2
Ishøi et al. (2018) 2 2 2 0 2 2 1 2 2 2

Krommes et al. (2017) 2 2 2 0 2 2 2 2 0 2
Maroto-Izquierdo et al. (2017) 2 2 2 0 2 2 2 2 2 1

Mendiguchia et al. (2015) 2 2 2 1 2 2 1 2 2 2
Mjølsnes et al. (2004) 0 2 2 0 2 2 1 2 1 2
Sabido et al. (2017) 0 0 2 2 2 2 2 2 2 2

Suarez-Arrones et al. (2018) 2 0 2 0 0 2 2 2 1 1
Sanchez-Sanchez et al. (2019) 0 2 2 0 2 2 2 2 2 2



J. Funct. Morphol. Kinesiol. 2019, 4, 67 5 of 18

One reviewer created a data extraction form based on several existing literature reviews [1,6,15,16]
and variables of interest related to the research questions. This extraction form was created using
Microsoft Excel 2016 (Microsoft Corporation, Redmond, WA, USA). The reviewer then manually extracted
data from each study for the following physical qualities: strength, speed, power and change of direction.
Where possible the mean, standard deviation, percent difference and effect size statistic were calculated.
If the relevant information (sample size, standard deviation, change in means) was not available, then
the authors’ reported values were used. Effect size was calculated for each treatment to determine the
magnitude of change in the outcome variable using the mean difference (Mdiff), pooled pre- (SD1)
and post-test (SD2) standard deviation and pre- and post-test sample size pairs (n) [17]. A majority of
studies meeting the inclusion criteria had a sample size of fewer than 20 participants; as such, Hedges’
g correction was applied to Cohen’s d, as it has been shown to correct for small sample bias [17].

Cohen′s dav =
Mdi f f

SD1+SD2
2

(1)

Hedge′s gav= Cohen
′s dav ×

(
1 −

3
4(n)− 9

)
(2)

Values were interpreted as trivial 0.00 < trivial < 0.20, 0.20 ≤ small < 0.60, 0.60 ≤ moderate < 1.20,
1.20 ≤ large < 2.00, 2.00 ≤ very large < 4.00 [18].

3. Results

3.1. Participant Characteristics

Data for participant and training intervention characteristics are reported as mean ± standard
deviation, unless otherwise stated. A total of 14 studies met the inclusion criteria and were included
in the review, with a summary of the participant characteristics provided in Table 2. A total of
357 participants were recruited and included in the analysis. Of the 357 total participants, 203 were
included in the experimental group, with the remaining 154 participants serving as controls; one study
used a crossover design with participants serving as their own controls (n = 20). Background variables
were provided in all studies except one [19]. Participants took part in a range of team sports including
basketball, soccer, handball, and rugby union. Elite junior or academy athletes were recruited in four
studies [20–23]. Athletes from professional or Division I sport organisations were recruited in six
studies [19,24–28]. The remainder of studies recruited semi-professional or lower division athletes.

3.2. Intervention Characteristics

Training programs lasted from 3 to 10 weeks (8.1 ± 2.6), including 7 to 18 training sessions
(13.3 ± 3.1), with the exception of Suarez-Arrones et al. [23], whose intervention included 54 sessions
over 27 weeks. Studies utilised a wide range of equipment including free weights typically
found in performance settings, inertial flywheel devices or bodyweight-exercise based equipment.
The prescribed training volume ranged from one to six sets of 5 to 12 repetitions. One study reported
the number of sets (four) but not the number of repetitions [29]. Five studies in total followed the
Nordic hamstring exercise protocol (NORD) as described by Mjølsnes et al. [19], which is a 10 week
intervention progressively increasing volume from two to three sets of 5 to 12 repetitions utilising the
NORD, performed concurrently with soccer specific training.

The prescription method of exercise intensity used in the experimental groups was quantified
in only three studies. These authors prescribed intensity based on percentage of one repetition
maximum (1RM) [30], percentage of bodyweight [31] or through a familiarisation protocol [23].
The remaining studies verbally encouraged participants to produce a maximal effort either against
a flywheel device of varying inertial resistance [15,20,21,24,28], or during the eccentric phase of
bodyweight exercise [19,22,26,29,32]. Compliance to the training intervention was reported in all
but three studies [22,24,30]. Compliance values ranged from 70% to 100% (94.5% ± 10.5%). All
studies reporting concurrent sport practice in addition to the intervention reported no differences in
sport-specific training volume between the experimental and control groups.



J. Funct. Morphol. Kinesiol. 2019, 4, 67 6 of 18

Table 2. Study characteristics for eccentric overload training interventions with male team sport athletes.

Study (Year) Sample Size Population Age (Years) Height (m) Body Mass (kg) Sport Quality Assessment

Askling et al. (2003) Exp = 15
Swedish Premier league

24.0 ± 2.6 1.82 ± 0.06 78.0 ± 5.0 Soccer 19
Con = 15 26.0 ± 3.6 1.81 ± 0.07 77.0 ± 6.0

Brughelli et al. (2010) Exp =13
Division 2 Spanish soccer

20.7 ± 1.6 1.80 ± 0.07 73.1 ± 6.0 Soccer 16
Con = 11 21.5 ± 1.3 1.79 ± 0.07 72.5 ± 7.5

Cook et al. (2013) Exp = 5

Semiprofessional rugby union

19.4 ± 0.5 1.85 ± 0.03 93.8 ± 7.0

Rugby Union

16
Exp = 5 19.8 ± 0.8 1.87 ± 0.05 96.6 ± 9.3
Exp = 5 19.6 ± 0.9 1.85 ± 0.04 95.8 ± 7.7
Exp = 5 19.8 ± 0.4 1.83 ± 0.05 92.8 ± 6.0

de Hoyo et al. (2015) Exp = 18
Division 1 Spanish academy soccer

18.0 ± 1.0 1.78 ± 0.03 70.9 ± 3.9 Soccer 16
Con = 15 17.0 ± 1.0 1.78 ± 0.01 73.1 ± 2.6

de Hoyo et al. (2016) Exp = 17
Division 1 Spanish academy soccer

17.0 ± 1.0 1.78 ± 0.02 71.4 ± 3.9 Soccer 14
Con = 14

Iga et al. (2012) Exp = 10
English Professional League

23.4 ± 3.3 1.77 ± 0.07 78.0 ± 8.2 Soccer 17
Con = 8 22.3 ± 3.9 1.85 ± 0.09 78.0 ± 11.1

Ishøi et al. (2018) Exp = 11
Division 4 Danish academy soccer

19.1 ± 1.8 1.81 ± 0.07 76.2 ± 11.9 Soccer 17
Con = 14 19.4 ± 2.1 1.81 ± 0.07 77.0 ± 8.7

Krommes et al. (2017) Exp = 9
Division 1 Danish professional soccer

23.0 ± 3.9 1.83 ± 0.05 73.1 ± 5.8 Soccer 16
Con = 10 25.1 ± 4.9 1.81 ± 0.07 77.9 ± 9.9

Maroto-Izquierdo et al. (2017) Exp = 15
Division 1 professional handball

19.8 ± 1.0 1.86 ± 0.08 82.3 ± 3.3 Handball 17
Con = 14 23.8 ± 1.6 1.84 ± 0.01 85.6 ± 3.7

Mendiguchia et al. (2015) Exp = 27
Semiprofessional Spanish soccer

22.7 ± 4.8 1.75 ± 0.06 71.6 ± 8.7 Soccer 18
Con = 24 21.8 ± 2.5 1.77 ± 0.06 71.0 ± 7.7

Mjølsnes et al. (2004) Exp = 11
Division 1–4 Danish soccer

Soccer 14
Exp = 9

Sabido et al. (2017) Exp = 11 Division 1 handball 23.9 ± 3.8 1.83 ± 0.07 79.5 ± 7.7 Handball 16
Con = 10

Sanchez-Sanchez et al. (2019) Exp = 12
Regional

22.5 ± 2.2 1.76 ± 0.07 72.6 ± 9.1
Soccer/Basketball

16
Con = 10

Suarez-Arrones et al. (2018) Exp = 14 Serie A Professional 17.5 ± 0.8 1.80 ± 0.06 70.6 ± 5.3 Soccer 12



J. Funct. Morphol. Kinesiol. 2019, 4, 67 7 of 18

3.3. Outcome Measures

3.3.1. Strength

Strength outcomes were assessed in 9 of the 14 studies included in the literature review
(Table 3). Five of the nine studies used an isokinetic dynamometer to perform the strength assessment.
Training interventions utilised inertial flywheel devices [20,21,23,24,27,28,33], traditional isoinertial
equipment [30,31] or exercises performed with bodyweight [19,22,25,26,29]. Mendiguchia et al. [31]
used both isoinertial and bodyweight exercises. Studies including the NORD reported effect sizes
ranging from trivial (−0.17) [29] to moderate (0.60) [19]. Effect sizes (0.81 to 1.06) were calculated for
research involving inertial flywheel devices. Only Cook et al. [30] reported outcome data for strength
testing and training with isoinertial equipment. The authors found large (1.22, bench press) to very
large (2.16, back squat) effects when eccentric training was compared to traditional training.

3.3.2. Speed

Nine of the fourteen studies reported outcomes measures of speed (Table 4): these measures
included velocity [31], top speed [31] and time variables [15,20,22–24,26,28,30]. For clarity, positive
effect sizes represent a favourable change. Training interventions with flywheel devices reported effect
sizes ranging from 0.19 [20] to 0.98 [27]. There were mixed results for NORD training interventions
with some unfavourable (−0.07 to −0.60) and favourable (0.20 to 0.81) changes in speed outcomes.
EO effects on short sprint (<10 m) times (0.19 to 0.81) [20,22,23,26] were also compared to longer sprint
times (>10 m) (−0.60 to 0.98) [20,24,26–28].

3.3.3. Power

Explosive movement was measured using a variety of tests (counter-movement jump (CMJ),
triple jump, leg press and throwing) in 7 of the 14 studies included in this review (Table 5). CMJ was
assessed in six of the studies investigating power. Effect sizes for jump height (CMJ) ranged from
small (0.27) to moderate (0.69). Cook et al. [30] combined isoinertial eccentric training with overspeed
exercises (1.22). Flywheel studies investigating lower-body power measures reported effect sizes of
0.29 to 1.63. Krommes et al. [26] reported an effect size of 0.27 after a NORD intervention. One study
examined upper-body power despite not including upper-body training (−0.13) [28].

3.3.4. Change of Direction

Only three studies investigated the effects of eccentric training on change of direction performance
(Table 6). The investigation by de Hoyo et al. [21] used force plates to capture kinetic data in crossover
and sidestep tasks. Contact time (0.48 to 1.43) and braking time (0.60 to 0.95) both displayed small to
moderate effects. Effect size for peak braking force (0.72 to 0.84) and braking impulse (0.53 to 0.92)
ranged from small to moderate. Two studies reported [27,33] moderate to large effect sizes (0.93 to
1.46) for changes in Illinois and T-test performance.



J. Funct. Morphol. Kinesiol. 2019, 4, 67 8 of 18

Table 3. Eccentric training intervention characteristics for strength outcomes.

Study (Year) Weeks Sessions Sets × Reps Equipment Intensity
Prescription

Method
Results

Askling et al. (2003) 10 16 4 × 8 Flywheel 60◦ s−1 or 1.5 s “Max Effort”
EKFPT (28, 18.9%, g = 1.06);
CKFPT (20, 15.3, g = 0.81)

Brughelli et al. (2010) 4 12 4–5 × ? Bodyweight n/a “Max Effort”
CKFPT (−4, −2%, g = −0.17);

CKEPT (6, 2.1%, g = 0.17)

Cook et al. (2013) 3 12 4 × 5 Isoinertial 80–120% 1RM %1RM
Bench1RM (g = 1.22);
Squat1RM (g = 0.9)

Iga et al. (2012) 4 9 2–3 × 5–8 Bodyweight 30◦ s−1 or 1 s “Max Effort”
EKFPT (9 to 20, 7.4% to 20.2%,

g = 0.19 to 0.54)

Ishøi et al. (2018) 10 12 2–3 × 5–12 Bodyweight n/a “Max Effort” EKFPT (61.7, 19.2%, g = 0.94)

Maroto-Izquierdo et al. (2017) 6 15 4 × 7 Flywheel
Two 6.5 kg flywheels
with moment inertia

of 0.145 kg·m2
“Max Effort”

LegPress1RM
(31.6, 12.2%, g = 0.69)

Mendiguchia et al. (2015) 7 14 1–3 × 2–8 Isoinertial + Bodyweight 5–15 kg or 10–70% BW
Absolute Load + %

Bodyweight

CKFPT (16.3 to 18.4, −12.1%
to 13.1, g = 0.67 to 0.70);

EKFPT (31.3 to 42.3, 13.2% to
17.2%, g = 0.68 to 0.96)

Mjølsnes et al. (2004) 10 12 2–3 × 5–12 Bodyweight n/a “Max Effort” EKFPT (27, 11.3%, g = 0.60)

Sabido et al. (2017) 7 7 2–4 × 8 Flywheel
Flywheel disc with
inertia moment of

0.05 kg m2
“Max Effort”

HalfSquat1RM
(16.5, 14.2%, g = 1.67)

Notes. Results are reported as (change in mean, % difference, Hedges’ g). Abbreviations. EKFPT (Eccentric Knee Flexor Peak Torque), CKFPT (Concentric Knee Flexor Peak Torque), CKEPT
(Concentric Knee Extensor Peak Torque), Bench1RM (Bench Press 1RM), Squat1RM (Back Squat 1RM), HalfSquat1RM (Half Squat 1RM), and LegPress1RM (Leg Press 1RM).



J. Funct. Morphol. Kinesiol. 2019, 4, 67 9 of 18

Table 4. Eccentric training intervention characteristics for speed outcomes.

Study (Year) Weeks Sessions Sets × Reps Equipment ECC Load/Intensity
Prescription

Method
Results

Askling et al. (2003) 10 16 4 × 8 Flywheel 60◦ s−1 or 1.5 s “Max Effort” F30 m (−0.08, −2.4%, g = 0.73)

Cook et al. (2013) 3 12 4 × 5 Isoinertial 80–120% 1RM %1RM
Eccentric + Overspeed vs.

Traditional 40 m (0.01, g = 1.06)

de Hoyo et al. (2015) 10 18 3–6 × 6 Flywheel
Concentric = optimal power

output (per inertia = 0.11
kg/m2)

“Max Effort”
10 m (−0.02, 1%, g = 0.18);

F10 m (−0.04, 3.3%, g = 0.84);
20 m (−0.04, 1.5%, g = 0.30)

Ishøi et al. (2018) 10 12 2–3 × 5–12 Bodyweight n/a “Max Effort” 10 m (−0.04, 2.6%, g = 0.54)

Krommes et al. (2017) 10 12 2–3 × 5–12 Bodyweight n/a “Max Effort”
5 m (−0.09, −10%, g = 0.81);
10 m (−0.10, −6%, g = 0.64);
30 m (0.10, 2.4%, g = −0.60)

Maroto-Izquierdo et al. (2017) 6 15 4 × 7 Flywheel
Two 6.5 kg flywheels with

moment inertia of 0.145 kg·m2
“Max Effort” 20 m (−0.40, −10.8%, g = 0.98)

Mendiguchia et al. (2015) 7 14 1–3 × 2–8
Isoinertial +
Bodyweight

5–15 kg or 10–70% BW
Absolute Load + %

Bodyweight

v5 m (0.20, 1.0%, g = 0.20);
v20 m (−0.1, −0.4%, g = −0.08);

TS (−0.1, −0.3%, g = −0.08)

Sabido et al. (2017) 7 7 2–4 × 8 Flywheel
Flywheel disc with inertia

moment of 0.05 kg m2
“Max Effort” 20 m (−0.08, −2.5%, g = 0.82)

Suarez-Arrones et al. (2018) 27 54 1–2 × 5–10
Inertial +

Bodyweight
Inertia 0.05 kg/m2

Highest power
output between

two loads during
familiarization

10 m (g = 0.41);
30 m (g = 0.38);
40 m (g = 0.31)

Notes. Results are reported as (change in mean, % difference, Hedges’ g). Abbreviations. 5 m (5 m Sprint), 10 m (10 m Sprint), F10 m (Flying 10 m Sprint), 30 m (30 m Sprint) F30 m (Flying
30 m Sprint), v5 m (5 m velocity), v20 m (20 m velocity), and TS (Top Speed velocity).



J. Funct. Morphol. Kinesiol. 2019, 4, 67 10 of 18

Table 5. Eccentric training intervention characteristics for power outcomes.

Study (Year) Weeks Sessions Sets × Reps Equipment ECC Load/Intensity
Prescription

Method
Results

Cook et al. (2013) 3 12 4 × 5 Isoinertial 80–120% 1RM %1RM
Eccentric + Overspeed CMJPP

(g = 1.22)

de Hoyo et al. (2015) 10 18 3–6 × 6 Flywheel
Concentric = optimal

power output (per
inertia = 0.11 kg/m2)

“Max Effort” CMJ (2.6, 7.3%, g = 0.60)

Krommes et al. (2017) 10 12 2–3 × 5–12 Bodyweight n/a “Max Effort” CMJ (1.15, 2.6%, g = 0.27)

Maroto-Izquierdo et al. (2017) 6 15 4 × 7 Flywheel
Two 6.5 kg flywheels

with moment inertia of
0.145 kg·m2

“Max Effort”

PWR90 (167.5, 21.5%, g = 0.71);
PWR80 (165.6, 19.7%, g = 0.73);
PWR70 (113.6, 12.4%, g = 0.52);
PWR60 (91.5, 10.0%, g = 0.41);
PWR50 (167.5, 21.5%, g = 0.99);

CMJ (3.5, 9.8%, g = 0.61);
SJ (3.3, 9.9%, g = 0.54)

Sabido et al. (2017) 7 7 2–4 × 8 Flywheel
Flywheel disc with
inertia moment of

0.05 kg·m2
“Max Effort”

CMJ (2.4, 6.0%, g = 0.47);
TJ_R (0.19, 2.9%, g = 0.29);
TJ_L (0.40, 6.2%, g = 0.74)

Sanchez-Sanchez et al. (2019) 5 10 2–3 × 6 Flywheel
Iso-inertial pulley
(0.27 kg/ m2) and

flywheel (0.05 kg/m2)
“Max Effort” CMJ (2.6, 7.4%, g = 0.46)

Suarez-Arrones et al. (2018) 27 54 1–2 × 5–10
Inertial +

Bodyweight
Inertia 0.05 kg·m2

Highest power
output between

two loads during
familiarization

HalfSquat30 (g = 0.42);
HalfSquat40 (g = 0.47);

RLHS30 (g = 0.48);
LLHS30 (g = 0.85);
RLHS40 (g = 1.03);
LLHS40 (g = 1.63)

Notes. Results are reported as (change in mean, % difference, Hedges’ g). Abbreviations. CMJPP (Counter-movement Jump Peak Power), CMJ (Counter-movement Jump height), HalfSquat30
(Half Squat power at 30 kg), HalfSquat40 (Half Squat power at 40 kg), PWR90 to PWR 50 (Power at 90% to 50% 1RM Leg Press (W)), RLHS30 (Right Leg Half Squat power at 30 kg),
LLHS30 (Left Leg Half Squat power at 30 kg), RLHS40 (Right Leg Half Squat power at 40 kg), LLHS40 (Left Leg Half Squat power at 40 kg),TJ_R (Triple Jump Right Leg), and TJ_L (Triple
Jump Left Leg).



J. Funct. Morphol. Kinesiol. 2019, 4, 67 11 of 18

Table 6. Eccentric training intervention characteristics for change of direction outcomes.

Study (year) Weeks Sessions Sets × Reps Equipment ECC Load/Intensity
Prescription

Method
Results

de Hoyo et al. (2016) 10 18 3–6 × 6 Flywheel
Concentric = optimal power

output (per inertia = 0.11 kg/m2)
“Max Effort”

BT_crossover (0.01, 16.7%, g = 0.60);
BT_sidestep (0.01, 16.7%, g = 0.95);
CT_crossover (0.01, 7.1%, g = 0.48);
CT_sidestep (0.03, 20.0%, g = 1.43);

rB_IMP_crossover (0.16, 21.6%, g = 0.92);
rB_IMP_sidestep (0.13, 13.5%, g = 0.53);

rPB_crossover (7.4, 29.1%, g = 0.72);
rPB_sidestep (9.0, 29.7%, g = 0.84)

Maroto-Izquierdo et al. (2017) 6 15 4 × 7 Flywheel
Two 6.5 kg flywheels with

moment inertia of 0.145 kg·m2
“Max Effort” T-test (0.6, 6.5%, g = 1.46)

Sanchez-Sanchez et al. (2019) 5 10 2–3 × 6 Flywheel
Iso-inertial pulley (0.27 kg/ m2)

and flywheel (0.05 kg/m2)
“Max Effort” Illinois (1.0, 5.6%, g = 0.93)

Notes. Results are reported as (change in mean, % difference, Hedges’ g). Abbreviations. BT_crossover (Braking Time in crossover cutting), BT_sidestep (Braking Time in sidestep cutting),
CT_crossover (Contact Time in crossover cutting), CT_sidestep (Contact Time in sidestep cutting), rB_IMP_crossover (Relative Braking Impulse in crossover cutting), rB_IMP_sidestep
(Relative Braking Impulse in sidestep cutting), rPB_crossover (Relative Peak Braking Force in crossover cutting), and rPB_sidestep (Relative Peak Braking Force in sidestep cutting).



J. Funct. Morphol. Kinesiol. 2019, 4, 67 12 of 18

4. Discussion

The goal of this systematic review was to identify and evaluate the existing literature surrounding
EO training interventions and their effects on performance measures in trained team sport athletes.
The current evidence is in support of the inclusion of eccentric training in training programs to improve
performance measures of strength, speed, power and change of direction. However, inconsistencies
exist within the literature with regard to methodologies and variables of interest that need careful
consideration before the results can be extrapolated to other athletes or populations.

The quantification and prescription of EO intensity in well-trained athletes was only reported
in four studies focused on performance outcomes [24,25,30,31]. The loading parameters (i.e., load
magnitude, repetitions, tempo) were unspecified in several training interventions [19,22,26,29], making
it difficult to assess the connection between stimulus and adaptation [34]. Interestingly, Cook et al. [30]
were the only authors to prescribe supramaximal training loads (>100% 1RM), even though this method
does not require specialised equipment beyond typical barbells and weight plates. The remaining two
studies either estimated joint angular velocities [24] or used submaximal loads [31]. Other prescription
methods relied on instructing participants to perform one or more phases of the exercise with “maximal
effort” [19,22,29,32], but provided no further evidence for EO. Tous-Fajardo et al. [35] demonstrated
that the magnitude of eccentric peak force with a flywheel device is largely dictated by the trainee,
and that differences in EO exist between those with and without flywheel training experience. Thus,
the quantification of neuromuscular and mechanical output data in EO exercises may be necessary to
determine the extent of training load and subsequent adaptation.

4.1. Strength

Maximum strength, as measured by a single maximal voluntary contraction, is influenced by
both neurological and morphological factors that can be influenced through EO [1]. Studies involving
trained [36–39] or untrained participants [40,41] have demonstrated an increase in maximal strength
after EO interventions, which may be due to greater neurological contributions and/or type-II muscle
fibre hypertrophy. These adaptations are thought to be a result of the high levels of tension developed
in the muscle fibres [34], with relatively lower metabolic cost and levels of activation when compared
to concentric contractions [42]. These activation patterns may be a result of the distinct molecular
and neural characteristics of eccentric contractions [12], and could necessitate specific strategies in
order to accurately assess and prescribe eccentric training [43]. A recent review by Douglas et al. [1]
highlighted that motor unit recruitment and discharge rates are contributing factors to improvements
in eccentric strength following eccentric or heavy resistance training.

The velocity of EO training appears to play an important role in determining subsequent strength
adaptation following the intervention. For example, Roig et al. [16] reviewed eccentric and concentric
training studies and found that eccentric stimuli produced superior improvements in total strength.
However, the effects were greater when the testing and training velocities were matched. The authors
concluded that performance outcomes were mode- and velocity-specific. In contrast to these findings,
other investigations [41,44] have found that high-velocity EO training (180◦·s−1) had a greater degree of
transfer than slow velocity EO training (30◦·s−1) during isokinetic testing. Furthermore, one review [45]
challenged whether EO provided any additional benefit over traditional training, suggesting that
specific populations such as athletes and the untrained may respond differently to EO as a training
stimulus depending on baseline strength capabilities.

Studies in the current review reported effect sizes from −0.17 [29] to 1.67 [28] when EO training
methodologies were applied to athletes. Training interventions and assessments that were matched on
mode of contraction reported effect sizes from 0.19 [25] to 1.67 [28]. Brughelli et al. [29] conducted
concentric isokinetic testing following a training intervention that emphasized eccentric contractions.
The authors did not speculate whether mode specificity might have played a role in their findings.
The only three studies [27,28,30] to report on dynamic (eccentric and concentric) strength tests (1RM
leg press, back squat, half squat) demonstrated moderate (0.69) to large (1.67) effects. Although some



J. Funct. Morphol. Kinesiol. 2019, 4, 67 13 of 18

transfer effect has been noted between contraction modes [6], this phenomenon is inconsistent within
the literature [16].

Three studies investigating NORD and strength outcomes found small to moderate improvements
in trained athletes [19,22,25]. The isokinetic assessments used by these authors matched the mode
of contraction used in the training interventions. Ditroilo et al. [46] found that the NORD is capable
of producing EMG levels greater than those reported in maximal eccentric isokinetic testing, which
supports the NORD as an effective EO exercise.

The effect and time course of training duration and number of sessions on strength outcomes
following EO training is unclear, as both shorter (3 weeks) and longer (10 weeks) interventions and
smaller (7) [28] and larger (16) [24] numbers of sessions resulted in improvements. More research is
needed to understand the dose–response relationship between EO and strength in trained athletes.
With the exception of Brughelli et al. [29], studies investigating strength-based outcomes in athletes
appear to be in agreement with the literature that supports EO as a potent stimulus for neuromuscular
strength adaptation [1].

4.2. Speed

The effect of EO training on measures of linear sprint ability are thought to involve numerous
components [47]. Briefly, sprint performance consists of several phases, including acceleration and
maximal speed, which have distinct kinetic and kinematic features [48]. Acceleration is characterised by
extensor action in the hip, knee and ankle, maximal rate of force development over minimal time (RFD),
maximal relative strength and higher ground contact time. Maximum-velocity sprinting involves the
hip and ankle extensors, RFD and relatively short ground contact time. These features are related to
physical qualities such as mechanical stiffness and stretch-shortening cycle (SSC) performance [3,49–52]).
Studies investigating the contribution of mechanical [53] and neuromuscular [36,38,54–56] factors have
demonstrated improvements as a result of eccentric training.

Several articles identified throughout the literature search were in agreement with the apparent
positive effect of EO on sprint performance. Each of the nine studies included in the review reported
trivial to moderate improvements in speed measures. Investigations involving short sprints (<10 m)
showed trivial to moderate effect sizes. Krommes et al. [26] reported moderate improvements in 5 m
(0.81) and 10 m (0.64) sprint times, but moderately slower times in 30 m sprints (−0.60). Cook et al. [30]
reported that eccentric training alone did not improve 40 m sprint speed. Mendiguchia et al. [31]
described trivial results in 5 m velocity (0.20) and 50 m top speed (−0.07). Additionally, bilateral
and unilateral EO training have been reported to increase power and change of direction ability
without improving 10 m sprint times [38]. A recent review favoured the use of EO with a flywheel
device over traditional resistance training for improving running speed [15]. However, as mentioned
previously, controversy exists as to whether certain inertial devices are capable of producing EO [35,57],
as force production is in part determined by the experience of the trainee. As previously mentioned,
acceleration and maximum-velocity sprinting are distinct physical abilities and may depend on
separate performance qualities. Thus, identification and examination of the factors associated with the
prescription of EO to enhance specific aspects of sprint performance are necessary.

Contraction velocity appears to be a contributing factor to subsequent adaptations in EO
research [1,6,16], with high velocities resulting in greater magnitudes of neuromuscular adaptation. A
review by Guilhem et al. [7] stated that isokinetic angular velocity in the literature ranges from 30◦·s−1

to 210◦·s−1. Askling et al. [24] were the only authors in the current review to report the joint angular
velocity (60◦·s−1) used in training interventions for speed outcomes, which resulted in a moderate
effect (0.73) in trained athletes. Based on previous research investigating high- and low-velocity
training [44,58], 60◦·s−1 may represent a relatively low training velocity. Limited availability of EO
literature examining trained populations makes it difficult to draw generalisations; however, it is
speculated that distinct sprint qualities may be differentially affected by EO training parameters such
as velocity.



J. Funct. Morphol. Kinesiol. 2019, 4, 67 14 of 18

4.3. Power

The storage and reutilisation of elastic potential energy during the eccentric phase of the SSC is
thought to contribute to jump performance [3,59–63]. In the current review, changes in lower-body
power performance were measured primarily with jumping variations. These investigations [20,26–28,
33] revealed small to moderate (0.27 to 0.61) improvements in CMJ performance, while the inclusion of
overspeed training protocols resulted in large (1.22) improvements [30]. One reason for the efficacy of
EO training in improving power performance may be that relatively fewer motor units are recruited,
resulting in more muscle tension, especially at higher velocities [7,41]. The high levels of tension
developed in the MTU may lead to adaptive responses in the elastic components of the muscle [34,64].

However, investigations using EO have also reported no change in squat jump, counter-movement
jump or rate of force development [65]. Additionally, eccentric duration and execution of the correct
technique [55,66] may actually decrease measures of velocity in a jump squat. Discrepancy in the
effects of EO on power may be a result of individual differences (e.g., technique, anthropometric
qualities, contractile and elastic capabilities), which have been shown to influence drop jump and CMJ
performance [67]. EO has also been shown to suppress performance qualities for extended periods
of time, which could potentially interfere with results dependent on the timing of the post-testing
regime [68,69]. Thus, although there seems to be a favourable effect on the expression of power
following EO, it is unclear whether the effect sizes related to power production in the literature review
are affected by individual recovery profiles or individual differences.

4.4. Change of Direction

Despite recent evidence [9,70,71] on the relationship between eccentric strength and change of
direction performance, only three studies in the present review examined any measure of agility.
Kinetic data for a novel crossover and sidestep cutting task displayed moderate to large (0.48 to 1.43)
changes in the eccentric phase of muscle action following an EO training intervention. Similar effect
sizes (0.93 to 1.46) were reported for the Illinois and T-test times in trained athletes [27,33]. Interestingly,
neither study reported performing agility-specific training as part of the intervention. This lack of
task-specific activities suggests that lower-body flywheel training may transfer to complex skills such
as change of direction ability.

These findings are in agreement with existing literature that has reported improvements in change
of direction ability following EO training interventions. Gonzalo-Skok et al. [57] reported substantial
improvements in measures of change of direction ability for two EO training programs. The authors
reported that although bilateral and unilateral groups improved, differences existed between groups in
power outputs and force-vector applications. These results support existing evidence [38,72] for the
positive but differential effects of EO on change of direction performance.

5. Conclusions

EO appears to be an effective training strategy for athletes and sports practitioners looking to
improve measures of strength, speed, power and change of direction. The review highlights evidence
suggesting EO can improve performance qualities even in experienced athletes. The exact neurological
and morphological mechanisms underlying these changes have been the focus of a growing body of
research. Due to a large degree of variation in the existing research, a dose-response relationship for a
specific method and its intended adaptation has yet to be determined in trained team sport athletes.
Future research should explore the quantification of eccentric ability, the prescription of eccentric
training variables and the relationship between EO-induced adaptation and performance qualities.

Author Contributions: Conceptualization, N.G., D.T.M., C.M.B., C.M.; data curation C.M.; formal analysis, C.M.;
investigation, C.M.; supervision, N.G., D.T.M., C.M.B.; writing—original draft, C.M.; writing—review and editing,
N.G., D.T.M., C.M.B.

Funding: This research received no external funding.



J. Funct. Morphol. Kinesiol. 2019, 4, 67 15 of 18

Conflicts of Interest: The authors declare no conflict of interest.

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	Introduction 
	Materials and Methods 
	Search Strategy 
	Eligibility Criteria 
	Study Selection 
	Analysis of Results 

	Results 
	Participant Characteristics 
	Intervention Characteristics 
	Outcome Measures 
	Strength 
	Speed 
	Power 
	Change of Direction 


	Discussion 
	Strength 
	Speed 
	Power 
	Change of Direction 

	Conclusions 
	References