Justin
Gibson, BS, CSCS
Introduction
Shoulder
performance and injury is a major topic of interest for professional athletes,
recreational fitness enthusiasts, and the general population alike. Whether
discussing one’s ability to throw a baseball at a consistently high velocity or
their ability to hoist a gallon of milk onto a countertop, the strength and
health of the glenohumeral joint should and has been the subject of a large
body of scientific literature. However, when seeking funding for a research
proposal, it is perhaps easier to justify studying a shoulder when it is
attached to a body on a $3.1 million dollar 2-year contract than it would be if
it were attached to someone lifting weights as a hobby. And so, a large
proportion of our scientific literature regarding the shoulder tends to focus
on athletes, specifically overhead athletes, when attempting to identify
potential risk factors for injury.
One such risk factor explored in these studies has been the
balance between external rotation strength of the shoulder and internal
rotation strength. For overhead athletes in particular, it is believed that the
eccentric strength of the external rotators should be as strong as the
concentric strength of the internal rotators to maintain glenohumeral stability
and optimal shoulder function (Wang & Cochrane, 2001) . In this paper, I
will discuss the scientific evidence linking internal/external rotator
imbalance as a predictor of injury in overhead athletes, the similarities
between these athletes and recreational weightlifters, and possible data that
may build a bridge between them.
External/Internal
Rotation Strength Ratios as a Predictor for Injury in Overhead Athletes
Several studies have noted a link between shoulder muscle
imbalance and injury. Two such studies looked at several factors that may
contribute to shoulder injury: range of motion, external rotation weakness,
scapular asymmetry, and ER/IR strength ratios. Clarsen,
Bahr, Anderson, Munk, & Myklebust (2014) measured all of these factors when
following the teams in the Norwegian elite handball series for men for three
months of the 2011-2012 season. They found significant associations between ER
weakness, obvious scapular dyskinesis, and shoulder range of motion, and inury,
and “noteworthy” associations between injury and ER/IR strength ratios. To
directly quote the study, “non-significant trends in the data suggest that
lower ER to IR ratios and abduction strength may also be noteworthy risk
factors.”
In contrast,
Wang & Cochrane (2001), in their study on elite male volleyball players,
concluded that shoulder rotator muscle strength imbalance (eccentric
external/concentric internal <1) played in statistically significant role in
the shoulder injuries of their athletes over the course of their season, whereas
shoulder mobility, scapular asymmetry, and muscle strength were not
significantly associated with injury. These
two studies each have their merits and limitations: The Clarsen study follows a
larger group of athletes, while the Wang study measures a longer timeframe.
Both studies, however, at least make note of the ER/IR ratios as a risk factor,
and both studies extensively reference other studies done on overhead athletes
when discussing possible causes of injury.
Perhaps stronger evidence for the link between ER/IR
imbalance and injury is seen in Bryam, et al. (2010).
While the researchers’ hypothesis mainly concerned the weakness of shoulder
external rotators (which they found to be very strongly associated with injury),
they also found significant links between low ER/IR strength and overall
throwing injuries and an even stronger association with shoulder injuries specifically.
This study was conducted over a 5 year period at looked at 144 Major and Minor
League Baseball pitchers, a much larger scope than the previous two studies
(and with, as noted earlier, more expensive subjects).
All three of these studies discuss, independent of their
findings, why a proper ER/IR strength ratio may be important in predicting
injury. Handball, volleyball, and baseball all involve motions that require
significant internal rotation torque to perform at a high level, and as a
result, these athletes tend to develop very strong internal rotators without a
concurrent strengthening of their external rotators (Codine, L., Pocholle, Benaim, & Brun, 1997) . In a high-velocity
activity such as throwing, this imbalance may lead to soft tissue injuries as
the weak external rotators are unable to provide enough stability to the
glenohumeral joint to counteract the immense forces produced by the internal
rotators. With this in mind, are these findings relevant to the average weight
lifter, or do they only apply to the specific motions of overhead athletes?
The
Role of the Rotator Cuff in Glenohumeral Stability and Movement
Thus far this paper has not attributed internal or external
rotation to any specific muscle or muscle group, but of course these motions
are achieved by the contraction of specific muscles. Most anatomy textbooks
attribute internal rotation to the subscapularis of the rotator cuff, with the
larger pectoralis major, anterior deltoid, and latissimus dorsi muscles
contributing significantly. The posterior muscles of the rotator cuff, the
infraspinatus and the teres minor, are the external rotators, with only the
posterior deltoid providing significant additional force, although some studies
also suggest the supraspinatus could play a significant role (Dark, Ginn, & Halaki, 2007) . This difference in
cross-sectional area of muscles that provide internal rotation vs. external
rotation could explain why even in non-athletes, internal rotation strength is
significantly higher (Noffal, 2003) .
Rotation, however, is not the only function of the rotator
cuff. It could be argued that their isometric role in stabilizing the humeral
head in the glenoid fossa is as or more important than their isotonic role in
providing rotation. Centering the axis of rotation in the glenohumeral joint
could be an important factor in preventing shoulder impingement, and it is a
role for which the rotator cuff muscles, particularly the inferior and
posterior components, are well suited (Sharkey & Marder, 1995) . Indeed, instability
of the shoulder joint has been shown to be a major predictor of injury in
overhead athletes and weightlifters (Gross, Brenner, Esformes, & Sonzogni, 1993) .
Applying
ER/IR Strength Ratios to the Weight Training Population
Now that we have established some evidence that a lack of
external rotation strength compared to internal rotation strength has been
observed to predict injury in overhead athletes, and that specific muscles are
responsible for these actions, we can begin attempting to link this information
to the recreationally trained weight lifting population. Some common ground has
been found between the ER/IR strength ratios of throwers and recreational
weight lifters. When comparing throwers to non-throwers, Codine, L. et al (1997) and Noffal (2003) found that
throwers had a lower concentric ER/IR strength ratio (about 0.57 and 0.65 at
300 degrees/second, respectively) than non-throwers (about 0.75 at 300
degrees/second in both studies) in their dominant throwing arms, and that this
was due to the throwers’ higher IR strength without a significant increase of
ER strength over non-throwers.
A similar study which looked at muscluar strength differences
between the recreational weight training population and a control group found
that these same ER/IR strength discrepencies also exist in the recreational
weight training population (about 0.61), and that this imbalance is also due to
a strengthening of the internal rotators without concurrent strengthening of
the external rotators (Kolber, Beekhuizen,
Cheng, & Hellman, 2009) . In EMG studies, the pectoralis major,
commonly targeted in traditional weight training programs, has been shown to
contribute significantly to internal rotation (achieving similar activation
rates as the subscapularis), whereas no such large muscle is activated nearly
to the same extent as the infraspinatus during external activation (Dark et al,
2007).
Shoulder instability, particularly anterior shoulder
instability, has been observed in weight lifters with shoulder pain. Gross, et
al (1993) observed that every patient in their study (all of whom had recurrent
instability in one or both shoulders and reported weight lifting as their
primary recreational activity) experienced pain in abducted and externally
rotated positions when the humeral head is translated anteriorly in the glenoid
fossa, and that most of them could not recall any particular event that caused
the pain. In common weight training
exercises such as the bench press and row, the rotator cuff functions in a reciprocal
fashion to oppose translation of the humeral head by the larger external
muscles acting on the shoulder; the infraspinatus is highly active during the
bench press to oppose the pectoralis major’s anterior pull, and the
subscapularis is highly active during the row to oppose the latissimus dorsi’s
posterior pull (Wattanaprakornkul, Halaki, Cathers, &
Ginn, 2011) .
However, as noted in the Kolber study, there is little evidence to suggest that
the infraspinatus is significantly strengthened alongside the larger pectoralis
major in most common resistance training programs. This may provide a possible
explanation as to why some recreational weight lifters experience progressive
shoulder pain: large muscles such as the pectoralis major are strengthened at
much faster rates and have a much larger total strength capacity than the
muscles of the posterior rotator cuff, and eventually these smaller intrinsic
muscles cannot adequately stabilize the glenohumeral joint during exercises
like the bench press.
Shoulder
Injury Prevention in Weight Training Populations and the Case for More Research
Although not common in traditional weight training
programs, the infraspinatus and other rotator cuff muscles can be specifically
targeted and relatively isolated from other muscles with the right exercises (Escamilla, Yamashiro, Paulos, & Andrews, 2009) . Properly designed
strength training programs that include exercises to specifically target
external rotators can limit or eliminate the ER/IR strength discrepancy found
to be common in weight lifters (Niederbracht, Shim, Sloniger, Paternostro-Bayles, & Short, 2008) .
It is important, however, to note that the comparison
between throwing athletes, recreational weight lifters, and the methods used to
measure their respective muscle imbalances, has several caveats and outright
flaws that need to be addressed. Testing methods for ER/IR rotation varied
across the studies I’ve presented in this paper; Bryam (2010), Clarsen (2014),
and Kolber (2009) all used isometric testing protocols to measure ER/IR
strength, whereas Wang (2001), Codine (1997), Noffal (2003) used isokinetic
testing. This is important to note because the sports played by the athletes in
the study involve dynamic, rather than isometric, motions of the shoulder,
often under immense load and stress. Baker,
Wilson, & Carlyon (1994) found that while isometric and dynamic
measurements of strength are significantly related, they were not so closely
related to imply generality of muscle strength across all contraction types and
speeds. It would not be advisable to assume that isometric strength is always
going to predict high-velocity eccentric strength, or that changes in isometric
strength over the course of a strength training program always reflect dynamic
changes in strength.
Isometric testing, however, may be appropriate for testing
the strength of the infraspinatus in recreational weight lifters. As previously
stated by Wattanaprakornkul (2011), the infraspinatus plays a major isometric
role in glenohumeral joint centration during the bench press as it opposes
anterior translation, which contributes to anterior instability. I would make
the case that measuring the isometric ER/IR strength ratios of recreational
weight lifters might be an effective estimate their posterior rotator cuff’s
ability to maintain glenohumeral stability against the pull of the pectoralis
major during popular exercises like the bench press. Studies referred to in
this paper have only looked at these ER/IR strength imbalances as they relate
to overhead athletes, and further study would be recommended to see if such a
correlation exists in the recreational weight training population.
Conclusion
The
connection between low external-to-internal rotation strength of the shoulder
and risk of injury has been well documented in throwing and overhead athletes,
and the need to maintain proper balance between the two has been the objective
of many strength and conditioning programs for athletes of all levels. Low
ER/IR strength ratios similar to that of overhead athletes have also been
observed in recreational weight lifters. Considering the dual role of the
rotator cuff as shoulder rotators and shoulder stabilizers, and that
traditional strength training tends to neglect the external rotators, more
research needs to be done to determine whether this same ER/IR strength
discrepancy when present in weight lifters carries the same risk of injury.
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