“The power of locomotion is that which contracts and relaxes the muscles whereby the
members and joints are moved, extended, or flexed.” This is how the Persian physician
Avicenna described the crucial role of muscle contraction in human movement, reported
in his masterpiece The Canon of Medicine (eleventh century). The ability of moving
from place to place is indeed fundamental for survival: it represents a distinctive
manifestation of life and evolution (Hoppeler and Herzog, 2014). Skeletal muscle allows
movement through contraction and force generation: the muscle shortens in order to
exert force, which is then transmitted to tendons and successively onto bones, resulting
in joint movement. However, locomotion, as many other movement patterns, is a combination
of distinct muscle actions: while during shortening (concentric, CON) contractions
the muscle indeed shortens, lengthening (eccentric, ECC) actions allow the dissipation
of mechanical energy during body deceleration (Konow and Roberts, 2015).
Thus, lengthening and shortening muscle actions coexist in many of our daily movements.
Resistance training (RT) represents a widely accepted strategy of muscle conditioning
that normally involves both CON and ECC. As these two types of contraction completely
differ from one another in terms of mechanisms of force generation, maximum force
produced and energy cost, some authors have suggested that ECC and CON would provide
different stimuli for distinct muscular and functional adaptations (Roig et al., 2009).
ECC actions can generate greater forces than isometric and concentric ones for any
given contraction velocity (Katz, 1939). Interestingly, the metabolic cost required
for ECC contractions is approximately a quarter of the one required for a CON one
of the similar magnitude (Lindstedt et al., 2001). Thus, ECC RT may be particularly
suitable for training individuals with medical conditions associated to muscle wasting
and reduction in muscle strength, mobility, and aerobic capacity, since it provides
a strong mechanical stress at a lower metabolic cost (Lastayo et al., 1999).
Despite the mentioned advantages, the use of ECC in clinical scenarios and aging has
often been object of contrasting opinions, mainly because associated with exercise
induced muscle damage (McHugh, 2003). However, moderate/low ECC loading has been suggested
as a strategy to overcome this problem, as when monitored and progressively ramped,
it effectively promotes muscle mass and strength gains without inducing muscle soreness
and damage, both in lower and upper limbs (LaStayo et al., 2014; Elmer et al., 2017).
Up to date, research has mainly focused on the acute and chronic effects of high-load
ECC only (resistance-exercised based) while the potential of moderate/low load regimes
seems to have been virtually neglected.
Through a mix of reviews, opinions and original research articles, the aim of the
presen Research Topic was, on one hand, to better clarify the main physiological,
functional, morphological and molecular features of ECC contractions as well as the
responses of human skeletal muscle (and tendons) to ECC RT. On the other hand, we
wanted to explore the feasibility of using ECC loading modalities in specific populations.
Hoppeler's review lays the groundwork of the Research Topic, discussing the main physiological
features and usefulness of eccentric cycling in cardiac rehabilitation, sarcopenia,
metabolic, and neurological conditions. Hoppeler makes a clear case for the application
of moderate load ECC RT in cardiovascular and orthopedic rehabilitation, as well in
injury prevention.
Yao et al. move the attention of the topic to the brain level, providing novel insights
via fMRI analyses on the functional connectivity between the primary motor cortex
and other areas during voluntary eccentric and concentric contraction.
While Nagamori et al. discuss the implications for rehabilitation purposes of bilateral
alterations in leg dexterity after ECC contractions, a review article (Hessel et al.)
from Professor Nishikawa's lab takes us back to fundamental muscle physiology, delineating
the current understanding of muscle mechanics in ECC, focusing on titin and its proposed
role in force generation.
Rindom and Vissing's mini review illustrates the beauty and complexity of molecular
pathways linked to the transduction of mechanical stimuli into muscle protein accretion,
discussing the implications of such cellular signaling with distinct muscle contractions.
The hypothesis and theory by Harris-Love et al. leads the way to the more “clinical”
part of the topic, proposing a novel periodization model for prescription of ECC RT
in outpatient rehabilitation setting. Tesch et al. illustrate the feasibility of Iso-inertial
eccentric overload RT in order to counteract muscle disuse and aging, as well as deconditioning
due to spaceflight, due to its applicability in rehabilitation settings. Instead,
Maganaris et al. focus on human tendons and on their regional adaptations/mal-adaptations
to chronic mechanical loading and tendinopathy, discussing the effectiveness of loading/rehabilitation
protocols on such “topography” of responses.
The works by MacMillan et al. and Chen et al. focus, respectively, on the mitochondrial
adaptations to ECC RT compared to CON RT on COPD patients and the superior effect
of ECC RT (i.e., vs. CON RT) on insulin sensitivity and lipid profiles. In addition,
Professor Fluck and colleagues present the cardiovascular and muscle-functional responses
to work matched ECC vs. CON RT performed on a novel soft robot device which allow
to prescribe rehabilitation programs tailored to the patient's functional and pathological
characteristics.
Mitchell et al. wrapping up this series of articles on clinical applications of ECC
RT, advocate the potential use of ECC in critical illnesses where the maintenance
of muscle mass acquire major importance. In conclusion of the topic, while Hicks et
al. nicely correlate muscle-tendon unit properties to the insurgence of exercise-induced
muscle damage, the extensive review by Franchi et al. tries to illustrate the morphological
and molecular remodeling of skeletal muscle in response to ECC and CON loading paradigms.
In conclusion, the 14 articles which constitute this research topic extensively present
how ECC contractions distinguish themselves from concentric, and how could be particularly
suitable for clinical scenarios. We hope that the different sides touched by the topic,
from fundamental muscle and tendon physiology to motor control and brain activity,
have provided a clearer idea of what we know about ECC so far, hopefully helping to
move this research field forward.
Author contributions
MF conceived the manuscript. MF, KM, HH, and MN contributed to the final editing of
the manuscript.
Conflict of interest statement
The authors declare that the research was conducted in the absence of any commercial
or financial relationships that could be construed as a potential conflict of interest.