Tag Archives: Box Squats

The Guessing Game – Box Squats Part IV

 

By Dan Wagman, Ph.D., C.S.C.S.

THE GUESSING GAME – BOX SQUATS

Part IV: Train Smart

The purpose for writing this series of articles was to illustrate why what appears to be very sensible training advice, doesn’t actually deliver. As with all things in life, you should also view training advice critically. The first question to ask about any training recommendation is by what physiological mechanism it’s supposed to work. The box squat’s proposed mechanism seems sensible—on the surface. With but a modicum of understanding about a muscle’s contraction mechanisms, you’d have to raise your eyebrows just enough to want to dig deeper before spending valuable time and effort on an exercise with dubious claims. Those raised eyebrows would then have your finger scrolling through research on your smartphone and you’d quickly learn that based on knowledge dating back to the 1930’s, it’s unlikely that the box squat will increase your squat ability. To summarize, research specific to that movement reveals the following:

  • The way in which your muscles work to perform a squat are enhanced the least by the box squat;
  • Muscle activity in the regular squat is far greater than in the box squat;
  • The forces generated in the box squat are weaker than those generated in the standard squat;
  • Speed of movement in the box squat is inferior to that of the squat;
  • Joint moments of the lower back, hips, and knees are significantly greater in the squat than the box squat;
  • The joint angles of the hip, knee, and ankle are significantly different between the two exercises and finally;
  • The above indicates that the box squat lacks the required specificity to be able to enhance your abilities to squat more weight.

Warmups and a Work Set

Please note that there’s no specific reason for why I chose to investigate the box squat. I could’ve chosen from any number of training recommendations to illustrate why their proposed benefits are fictional. I simply wanted to create a perspective and illustrate an approach that you can use to evaluate whatever training advice you run across. At the end of the day, recognize that you’re a strength athlete who spends tons of time in the gym in an effort to become the strongest person you can be. That’s not easy. You’re also an all-round weightlifter who’s challenged with learning, perfecting, and becoming as strong as possible in different lifts for each meet you enter. That’s not easy. Considering how you’ve self-selected into an area of physical accomplishment that challenges you every time you step into the gym, I would argue that you trying to determine just the minimum—what’s fact and what’s wishful thinking regarding training—is much easier and will take you no longer than what it’ll take to go through your warmups and then your first work set.

There’s no way Paul Anderson could’ve had a quick look at the American Journal of Physiology to see what he could do to increase his already fantastic squat even more. In fact, most athletes back then probably didn’t even know there was research being conducted on human muscle in an effort to understand not only how it works, but how you can get it to become stronger. But today, you literally hold that information in the palm of your hand. The most difficult part for you is to sift through the nonsense and uncover information that’s based on measurable and evidence-based facts instead. To be honest, you have to take responsibility for what training advice you follow. If you find yourself getting injured and not able to make long-term gains anymore, even though you’re healthy, don’t simply write it off as being older than what you used to be, or some other equally silly and unfounded notion. Take responsibility for your training decisions, review them based on exercise science the best you can, and allow yourself to once again experience the thrill of breaking PR’s. Isn’t attaining maximal strength in your red matter worth some effort in your grey matter?

And so, what about the main problem at the core of all of this—increasing your squat overall and more specifically blasting out of the hole? You guessed it, that has been researched and you could experience huge gains if you applied that information. No need for you to stumble through the dark with silly advice put forth by any number of self-proclaimed training gurus. Put that grey matter to work and enjoy the process of learning, putting it to work in the gym, and breaking PR’s.

The Guessing Game – Box Squats Part III

By Dan Wagman, Ph.D., C.S.C.S.

THE GUESSING GAME – BOX SQUATS

Part III: Removing the Guesswork

          Part II (see part II) of this series reviewed what was likely the first study to investigate kinematic differences between a box-squat-like movement and the standard squat. The next study was published by the Neuromuscular Laboratory at Appalachian State University in North Carolina in 2010.(2) They wanted to know what effect removing the stretch-shortening cycle via the box squat might have. They compared the box squat to the standard squat at 60%, 70%, and 80% 1-RM (1-rep maximum, the maximal amount of weight you can lift once). Their subjects were competitive male powerlifters with a minimum of 3 years experience and they looked at peak force and power during the concentric phase (i.e., ascent) along with relevant muscles’ activity. The squat was performed with a quick transition between hitting the hole and blasting back up and the box squat required a one second pause. The primary finding was that both forms of the squat were very similar, indicating that the box squat had “neither a positive nor a negative effect on squat performance.” This surprised the scientists because despite the one-second pause on the box, sufficient amounts of elastic energy remained available to negate significant differences between the two forms of squatting.

There are a few limitations that deserve mention. First, only a 1-second pause was investigated in the box squat. The usual recommendation includes times twice to five times as long. Perhaps the amortization phase requires more than one second to significantly lose its benefits. Second, the scientists did not define their box squat technique. It’s possible that the subjects held the position on the box firmly in an isometric contraction for one second as opposed to sitting back and resting on the box as is usually recommended. In doing so, the subjects would not have broken the coupling phase of contractions, which could explain why elastic energy remained to benefit the ascent.

A year later the same scientists provided additional information.(3) This time they also calculated peak velocity and made it clear that they removed the coupling phase. What the calculations revealed was that, generally, muscle activity was significantly higher in the standard squat compared to the box squat. This left the research team to conclude that, “It does not appear that the box squat, which removes the coupling phase, increases muscle activity in either the eccentric or concentric phase.” Based on their analyses they deduced that, “The box squat does not appear to be a viable alternative to squatting…which would not optimize training adaptations.”

 

A Final Look

The most recent study was published in 2012.(4) This research is very complex in terms of the kinetic variables investigated and results analyses and interpretations. I’m limiting my review to those aspects most related to the comparison of the box squat to powerlifting squat.

The research team used 12 well-trained powerlifters with an average training experience of 9.2 years. The testing protocol I shall present is the one with the heaviest weight, i.e., 70% 1-RM. Though 30% and 50% 1-RM were also investigated, I’m omitting those findings because, 1) although of great scientific value, those intensities don’t reflect the training most strength athletes engage in; 2) by including findings at lesser intensities, the math is skewed away from the higher training intensity; 3) since research shows that the degree of muscle involvement can change as lifting intensity rises (1), I thought it prudent to only look at the heaviest weight lifted (see Part 1).

The scientists looked at the traditional squat (weightlifter’s style), powerlifting squat, and box squat. The box squat employed the powerlifting squat style along with sitting/rocking backward on the box as is mostly advised in the gym setting. Each subject paused on the box for the same duration used in training, which ranged from 1.3 to 2.3 seconds. All conditions required the powerlifters to squat as explosively out of the hole as possible.

One of the most interesting findings was that the forces generated in the box squat were the weakest. The same was found for peak power values; the box squat came in last. In terms of speed of movement, the traditional squat was superior to the powerlifting squat and the box squat came in last. Although mathematically insignificant, I thought I’d share it with you because perhaps you might still consider that meaningful. In regard to the rate of force development, however, the box squat showed values three to four times greater than the other squat techniques. Another important finding was that the greatest hip moments were observed in the powerlifting squat and the least in the box squat. The same comparisons were found for the lower back and knees.

Another important consideration is that during the weightlifting and powerlifting squat, large increases in force were measured during the transition in and out of the hole. During the box squat, however, these forces decreased tremendously, though they would “then rapidly increase during the concentric phase.” This is expected, and nice to have scientific confirmation for, since you’re starting a squat out of the hole from nothing. Of course this also highlights how ineffective the box squat would be for improving standard squat abilities because a critical performance component of the latter is removed from the movement.

Finally, in looking at joint angles of the hip, knee, ankle, and shank, significant differences were noted between the box squat and powerlifting squat. This, too, is an important consideration when it comes to training specificity, one of the key variables required to maximize training gains. With a significant difference between joint angles in these two squat movements, even though the subjects were instructed to copy their powerlifting squat style to the box squat, it’s not clear how the box squat would be able to increase performance in the powerlifting squat.

This group of scientists noted that one of the key findings of previous research is that if you can maximize the production of all of the variables this group looked at, you would provide your body with the best stimulus necessary for long-term strength gains. Rather clearly, the box squat would not be able to deliver.

The next step is to tie the research together and derive at a conclusion. Part IV will attempt to do so.

 

References

  1. Król, H. and A. Golaś. Effect of barbell weight on the structure of the flat bench press. Journal of Strength and Conditioning Research. 31(5):1321–1337, 2017.
  2. McBride, J., et al. Comparison of kinetic variables and muscle activity during a squat vs. a box squat. Journal of Strength and Conditioning Research. 24(12):3195-3199, 2010.
  3. Skinner, J., et al. Comparison of performance variables and muscle activity during the squat and box squat. Journal of Strength and Conditioning Research. 25(Supplement 1):S21, 2011.
  4. Swinton, P., et al. A biomechanical comparison of the traditional squat, powerlifting squat, and box squat. Journal of Strength and Conditioning Research. 26(7):1805–1816, 2012.

The Guessing Game – Box Squats Part II

By Dan Wagman, Ph.D., C.S.C.S.

THE GUESSING GAME – BOX SQUATS

Part II: Less Guesswork

“The progressive evolution of athletic performance and specific conditioning techniques is dependent on a thorough understanding of those mechanisms underlying dynamic muscular function.”(2)

 

In Part I, I presented someone’s guess that has huge intuitive appeal—that the box squat will enhance your squat strength and power for driving out of the hole. I made a guess, too, and to derive at it I asked what is perhaps the most important question anybody can ask about any training concept: by what physiological mechanism would that idea work? I could find none. The question is, might there be something going on that’s less well understood about muscle contraction mechanisms that might render the box squat a useful tool after all?

Our knowledge of how important the coupling and amortization phases (see Part I) are to you being able to produce maximal strength goes back to research published in 1931.(1) Back then, however, those phase-terms were not used. Since then research has built upon itself and advanced our knowledge of what we now term the stretch-shortening cycle. What all this scientific study would suggest is that the promise that performing box squats will enhance your regular squat is nonsense. But I wanted to verify or refute my “guess” based specifically on research that looked at the squat and box squat.

 

A First Look

I believe the best starting point to be research published in 1998.(2) The researchers recruited 40 athletes of various sports. They all had a minimum of 1 year squatting experience and could squat a minimum of 1.5 times their body weight. The entirety of testing methods are too complex to mention here, but to briefly illustrate included a modified Smith machine that measured and controlled speed of movement, among other things; a force plate to gather much data on force, power, work, etc.; electromyography to measure muscle contractions; and more.

The subjects were tested in three conditions: 1. They had to squat from the bottom position up, similar to a box squat. What was dissimilar to a box squat was that they had to first hold an isometric contraction for no more than 1.5 seconds before exploding upward; 2. The “stretch-shortening squat” was tested, which you may view as a normal competition squat with an intact coupling and optimized amortization phase; 3. The subjects had to perform a maximal isometric contraction against an immovable bar for 100 to 200 milliseconds before it automatically released and allowed the athletes to explode out of the hole.

Among many data points analyzed, the most important consideration for the strength athlete is that the greatest effect on the squat was achieved in the stretch-shortening condition, i.e., a regular squat. That was followed by the squat preceded by a maximal isometric contraction and lastly by squatting from the bottom up as in a box squat, which resulted in the weakest readings. In fact, the readings generated from the standard squat were more than twice that compared to the box squat style. The research team concluded that the quicker you transition from lowering the bar to exploding upward, the more strength you’ll be able to demonstrate. This finding is entirely in line with what you would expect considering the basics of muscle contraction mechanisms/physiology. Bottom line, you must have an intact coupling phase along with the briefest amortization phase possible. Only then can you expect to demonstrate maximal strength and power.

Still, because this was initial work done on the squat and how different methods of commencing the ascent might influence strength and power, there were a lot of methodological controls put in place. Researchers place a great deal of control into their studies in an effort to eliminate extraneous variables that might influence the outcome. In doing so, they obtain very specific and accurate information. From there, future research builds and looks at additional variables that might have an impact. And so it could be argued that since in this initial work the squat was performed with an empty bar and the speed of ascent could not exceed the 0.4 meters per second set by the modified Smith machine, no matter how hard each athlete tried, the squatting was not as specific to a regular competition squat as necessary for an accurate comparison. Of course the research team acknowledged this while outlining in painstaking detail the reasons for their approach. Moreover, it could be argued that when the subjects commenced the squat from a dead stop without pre-stretch or isometric contraction first, that movement pattern was not exactly the same as what’s generally advised in doing a box squat.

So far things don’t look good for the box squat, but the above concerns may or may not be valid, which means I had to dig deeper into the research advancements. Part III will look at comparisons between the actual box squat and standard squat.

 

References

  1. Fenn, W.O., et al. The tension developed by human muscles at different velocities of shortening. American Journal of Physiology. 97:1–14, 1931.
  2. Walsche, A., et al. Stretch-shorten cycle compared with isometric preload: contributions to enhanced muscular performance. Journal of Applied Physiology. 84(1):97–106, 1998.

The Guessing Game – Box Squats Part I

By Dan Wagman, Ph.D., C.S.C.S.

THE GUESSING GAME – BOX SQUATS

Part I: Two Guesses

Like most guys and gals that got bit by the iron bug, I used to read all sorts of stuff about training. Once I came across something that seemed promising, I couldn’t wait to put it to practice in the gym, not to mention the torture I went through trying to manage the anticipation of huge gains. Of course those huge gains never happened, not until I learned about an area of scientific investigation called exercise physiology and started to apply what I learned. You see, that stuff isn’t based on guesses and conjecture. What I would like to share with you is a perfect example of why what might seem like really good training advice, when looked at from the perspective of human physiology, it couldn’t deliver as promised. My hope is that you’ll then be able to make more educated decisions about from whom to take training advice and what sort of questions to ask in your assessment of that advice.

 

The First Guess

It seems beyond obvious; for you to squat a ton of weight you have to be able to descend to below parallel in a controlled manner and once you hit depth you need to explode out of the hole in an effort to complete the movement. Nearly every lifter will tell you that the hardest part of the squat is blasting out of the hole. Naturally, this begs the question: might there be a method of training that’ll enhance your strength and power for getting out of the hole? Decades ago one very passionate powerlifter and coach came up with box squats for that very purpose.

The guess he made is that if you could squat down to a box that’s just the right height to break parallel, and you literally sat on it while rocking back, pausing on the box for one to five seconds or so, then blasted off it with all your might, you’d be able to increase the power you need to get out of the hole in a regular squat. This sounds really good. And so decades after the box squat idea was conceived tons of lifters still use it to increase their overall squat strength (though other purported benefits are said to exist). My guess, however, is that what seems to be such a good idea is far less than that when viewed through the lens of exercise physiology.

 

The Second Guess

The origin of my guess is based on the physiology of muscle contractions. Therefore, it’s really not a guess, but just humor me and let’s stay with the guessing theme.

When you squat down to depth your quad and glute muscles elongate, this is called an eccentric contraction (note that other muscles are involved, too, but addressing the entirety of functional anatomy and biomechanics is beyond the point of this article). When you reverse direction out of a deep squat, those same muscles shorten in what is termed a concentric contraction. For a very brief moment, as your muscles switch from eccentric to concentric, they contract isometrically. The linking of these contractions is referred to by some scientists as the coupling phase. Now, a fascinating thing occurs in your muscles during the eccentric phase of the squat—your muscles store elastic energy. As you reverse direction that stored elastic energy is released resulting in a powerful completion of the lift. The singular moment of switching directions is called the amortization phase and the entirety of what occurs here is often referred to as the stretch-shortening cycle. And here’s where another fascinating thing occurs; the longer the amortization phase, the more elastic energy is lost for the subsequent concentric contraction. Simply put, the longer the time you spend sitting on a box, the weaker you’d be during the ascent.

The above represents perhaps the most important amortization phase mechanism—reutilization of stored energy. Other proposed mechanisms include a stretch reflex, muscle-tendon interactions allowing muscles to remain at optimal lengths and to shorten at the best velocities, optimized muscle activation patterns, and increasing pre-force before the concentric contraction. Regardless of the mechanism(s) involved, it seems clear to me that the basics of muscle physiology deeply contradict the stated benefit of the box squat; as you sit on the box you’re increasing the amortization phase and ostensibly breaking the coupling phase, thus squandering valuable elastic energy. How could that possibly result in increased squatting abilities?

With that in mind, it’s well and good enough to reject the box squat. But is it possible that there is some component within the neuromuscular system that scientists have as of yet not discovered that would indeed warrant employing the box squat in your training? Could the original guess have accidentally hit on something? The way to get answers is to test the box squat hypothesis via controlled research. That’s what I’ll discuss in Part II.

 

Reference

Stone, M.H., M. Stone, and W. Sands. Principles and Practice of Resistance Training. Human Kinetics, 2007.