A number of personal trainers, strength coaches and gym rats advocate the leg press over the squat for perfectly healthy athletes because of the risk-to-benefit ratio and increased performance.  After analyzing this, is the leg press really safer than the squat? Which has more transference to athletics, the leg press or the squat? We will find out what common sense, science and anecdotal evidence have to say.

The leg press, regardless of design, has a preset motor pattern determined by the manufacturer. This motor pattern may not be ideal for your individual body type. It is built for the average person, and there is no real adjustment for body structure. Very few people would fall into what the manufacturer considers an average person. Consequently, you may condition postural and movement dysfunctions.  This in turn will affect overall movement quality (9).  It can negatively impact your everyday gait and posture for normal daily activities, not just during exercise (9).  In the long run, it can lead to misalignment of joints and spinal problems. Eventually this will lead to a cumulative injury cycle (9).

The leg press has been shown to make athletes more prone to lower back problems, because at the bottom position, they are very deep into flexion.  The knees get close to the chest, and many times the back is raised off the pad (13).  This is actually quite common, and leaves the spine very susceptible to large compressive forces (13).  Because the leg press is built to optimize leverage and there is no stabilization involved, much more weight is used than with a squat, making the compressive forces in this unnatural position with heavier weights potentially much more dangerous.

World renowned personal trainer Brian Dobson, owner of Metroflex gym, says, “My daughter can leg press 800 pounds, yet she struggles to squat 115.”  How is this possible?  The answer is simple.  The leg press requires no balance, as the lower back and hips are not stabilized by the core of the body (11).  Because the stability factor has been eliminated, the legs are able to lift poundages much greater than when trunk stability is a factor.  Ergo, the forces transmitted on leg muscles and joints are much greater than the body could naturally transmit during the squat (11).  This potentially puts the hips, lower back and knees at much greater chance of injury because of the artificially heavy loads the kinetic chain is forced to handle.  The core does not have to stabilize the weight.  Numerous studies have shown that not only are squats safe, but are in fact a significant deterrent to knee injuries.  Squats increase stability in the knee by increasing strength in the muscles around the joint, along with strengthening tendons and ligaments.

A squat requires the athlete to extend the knees and hips, while the leg press requires an athlete to extend the knees, but the hips are perpetually in flexion through the entire movement.  The leg press is considered a compound movement, as is the squat.  The leg press is closer to a single joint movement than the squat.  However, much more weight is lifted in the leg press.  Traditionally, compound lifts are the heaviest core movements, while isolation single joint movements are not.  Athletes in many cases are able to leg press more than five times what they can squat. Stabilization is important in sport and life.  Increasing stability decreases the chance of injury in all activities.  The squat increases stability, but the leg press does not.

An athlete is required to balance on his or her own two feet while performing the squat (11).  Transference of ground force through the body is exactly what is required of an athlete on the court or on the field of play (11).  The leg press completely eliminates the balance aspect of the equation, an aspect that will never be eliminated from sport. The leg press has nowhere near the same level of muscle recruitment as the squat (13), and lacks the degree of inter- and intra-muscular coordination of the squat (13).

Efficiency of movement is displayed by synergistically contracting the muscles so the correct muscles are being fired at the right time; therefore, maximum power can be generated (13).  Let us look at a vertical jump.  Vertical jump enhancement is a common goal at all levels of sport.  Muscle coordination is greatly enhanced through full body movements in the weight room, like the squat.  When squatting, the weight is opposed directly to your effort when attempting to lift the load (1).  Gravity is pulling the weight down (1).  When performing a vertical jump, you are trying to directly oppose gravity and the direction of its pull, by jumping up (1).  To defeat gravity, one must fight the effect it has on the body.  Leg presses are fundamentally the equivalent of pushing a loaded weight up a ramp while lying on your back, requiring no core strength. While squatting, you directly oppose gravity (1).

Due to the seated position of the leg press, hip extension is eliminated.  When a squat is completed, the hips reach full extension. By examining the leg press at the top of the movement, one can see the hips are still flexed at 100-120 degrees.  A large part of where speed and power is produced is during the last 60-80 degrees (11).  Because hip extension is eliminated, an athlete does not get to forcefully contract his/her hips like a vertical jump or most other powerful movements in sport (13).  Most sports require some sort of hip extension.  The squat trains hip extension, which the leg press neglects.

A 2004 study by the British Journal of Sport’s Medicine concluded that maximum effort strength in the squat determines sprint performance and jump height in elite soccer players (12).  In 2009, researchers at Appalachia State University in North Carolina found significant correlations between squat 1RM and sprint times in the five, ten, and forty yard dash; the shorter the distance, the stronger the correlation in division 1-AA football players (7).  Track coaches are quickly learning the importance of strength to body weight ratio concerning the squat.  This is a great determiner of the athlete’s ability to produce ground contact forces.  These studies clearly demonstrate the functionality of the squat.

If an athlete chooses to use a leg press instead of the squat, likely he/she will have weakened hip extensors and weak hip extension in a chosen athletic endeavor.  Another problem may be decreased functional strength for free weight movements.  Any experienced weightlifter will tell you the correlation between a squat and a leg press is virtually non-existent.  Other potential downfalls of choosing the leg press over the squat may be decreased overall power output, decreased neural efficiency, shortened muscles, and decreased flexibility (9).  The leg press in place of the squat could potentially teach the body to become dysfunctional by a lack of neuromuscular control, stability and potential retardation in motor patterns in sport.

Numerous studies show that weight training in general increases growth hormone and testosterone levels during exercise and post-exercise (6).  It now appears this acute response is more important in hypertrophy and tissue remodeling than chronic changes in hormone levels at rest (6).  To maximize these benefits, training programs that are moderate in intensity with short rest intervals and high volume elicit the greatest acute hormonal elevations (6).  Compound movements increase testosterone and growth hormone, and squats do the most of any resistance exercise, including the leg press (3).  The body’s natural release of testosterone and growth hormone is a catalyst for muscle growth (3).  What does this mean?  If you have no preexisting injuries and want to maximize the release of anabolic hormones without using illegal performance enhancing drugs, SQUAT!  If you want your muscles to grow, SQUAT!

Bodybuilding is one of the few sports where maximum muscle hypertrophy is the primary goal.  Bodybuilding supplements, contests and magazines are a mega-industry.  What do the experts who work in the trenches with these amazing athletes have to say?  What do the most muscular men in the world feel anecdotally is superior, the squat or the leg press?

Brian Dobson is the trainer of eight-time Mr. Olympia Ronnie Coleman, the largest champion competitive bodybuilder to ever take the stage.  He also trains current Mr. Olympia runner-up Branch Warren, who unquestionably has the largest and most muscular legs in bodybuilding today.  Brian also trains professional bodybuilders via the internet and trains many local and regional amateur champions.  To top it off, Brian is the former training partner of Tom Platz, who many consider to have the greatest legs of all time.

When asked about Platz’s implementation of the leg press into his training protocol, Dobson remarked, “I remember seeing Tom Platz do 425x28 deep reps in the squat.  Tom Platz was all about the squat.  That was his deal, he never did leg presses.”  Brian went onto explain, “I have Branch and Ronnie squat every leg workout.”  While both Ronnie Coleman and Branch Warren do leg presses as a supplementary lift, their legwork revolves around the squat.  Brian clarified, “The squat works the total body and is much safer than the leg press.  I know plenty of people that cannot squat 300 lbs yet can easily leg press over 1000 lbs.  My simplest answer is look at Tom Platz.   He never did a leg press, but he’d squat until the cows came home.”  In the past, Brian and I have been training partners.  In our bodybuilding phases, every leg workout begins with the squat.  Over the past four years, I have watched Branch Warren and Ronnie Coleman begin their workouts with the squat.

Many will still claim the leg press is superior when it comes to building quad mass.  Current Mr. Olympia Jay Cutler, had this to say on the subject: “Nothing builds quad mass like heavy free weight squats.  I recommend all bodybuilders squat. “(8). Let us see if science agrees with Jay Cutler and other champion bodybuilders.

A study by the University of North Dakota compared muscle recruitment during a leg press and a free weight barbell squat lift (5).  The study used two groups of subjects. Group 1 was made up of ten untrained, healthy men, and Group 2 was made up of sixteen trained, healthy male athletes (5).  The analysis method used was electromyographic (EMG) activity (5).  EMG activity was recorded from the erector spinae (ES), gluteus maximus (GM), vastus lateralis (VL), and biceps femoris (BF) muscles (5).  The exercises performed were the leg press and the barbell squat lift (5).

Every subject in Group 1 lifted three repetitions of both exercises using a weight equivalent to their own body weight, which ranged from 155 to 165 lbs.  In Group 2, each subject performed three repetitions of both exercises using a weight equivalent to 80% of their 1 RM in both lifts, which ranged from 225 to 600lbs. (5).  The results indicated that in Group 2, the trained group, the squat exercise elicited significantly more EMG activity than did the leg press in the ES, GM and BF (5).  A significant difference in the VL activity was not observed between the two exercises, but the activity in the VL was still slightly greater (5).  In the untrained group, Group 1, the results were almost a reflection of the trained group (5).  The leg press utterly failed to recruit the ES, GM or BF to the degree the barbell squat did (5).  The quadriceps were slightly more stimulated in the squat than in the leg press.

Squats cause the desired natural anabolic hormonal response favorable to muscle hypertrophy.  Electromygraphic activity was much greater in the lower body with the squat than the leg press.  Champion bodybuilders and their trainers seem to agree on the superiority of the squat to the leg press for the purpose of hypertrophy.  Science, along with the philosophies and anecdotal observations of those who are in the trenches on a daily basis seem to agree.  The squat is superior to the leg press for lower body hypertrophy and overall muscle growth.

People with larger amounts of muscle mass have higher metabolic rates.  The more muscle one has, the more calories one burns, even at rest.  Award winning ISSA certified personal trainer George Baselice added this on the subject of fat loss as it relates to squat:  “The squat challenges your cardiovascular system to an extent unequaled by any other weight training exercise.  The reason being the hypoxia effect, in which oxygen intake or use is temporarily inadequate.  This breathless state is a tremendous metabolic stimulator.  Squats will build an armor-clad heart and lungs, like a high-performance engine.”(2)  This is very thought provoking.

The leg press is not totally evil.  It offers certain advantages, like a simpler learning curve than the squat, although the squat is easy to learn with a good, qualified coach.  The leg press may offer other advantages in rehabilitative clinical settings, for people with certain disabilities and other limiting factors, or as an accessory movement.  It is tough to take any exercise seriously when televangelist Pat Robertson claims he can leg press 2000 pounds, and 73 year old Madelyn Albright stated in the New York Times she can do over 400 pounds!  Strength and conditioning coach, legend and author Mark Rippetoe, sums it up best:  “There is simply no other exercise, and certainly no machine, that produces the level of central nervous system activity, improved balance and coordination, skeletal loading and bone density enhancement, muscular stimulation and growth, connective tissue stress and strength, psychological demand and toughness, and overall systemic conditioning than the correctly performed full squat. “ (10)  Amen, Coach Rippetoe!

For more information about Josh, visit his log here.

References

  1. Increase Vertical. Increase Vertical. Retrieved May 2, 2010, from http://www.soprege.org/
  2. Baselice, G. (2009, Sep. - Oct.). Long 'Lift' The King. Planet Muscle, N/A, 94-106.
  3. Bodybuilding Forum - Blog - Store. (n.d.). Bodybuilding Forum - Blog - Store. Retrieved April 23, 2010, from http://bodybuildingweb.net
  4. Exercise Prescription Kinesiology/Squats. (n.d.). Exercise Prescription. Retrieved April 21, 2010, from www.exrx.net/
  5. James, M., Ivesdal, H., Mohr, T., & Frappier, J. (n.d.). An EMG Comparison Study of a Leg Press and a Squat Lift. School of Medicine & Health Sciences | University of North Dakota. Retrieved May 1, 2010, from http://www.med.und.edu/depts/pt/PT%20Website/research/Plyo3/LegPressvsSquat.htm
  6. Kraemer, W., & Ratamess, N. (2005). Hormonal Responses and Adaptations to Resistance Exercise and Training.. Sports Medicine, 35(4), 339-361.
  7. McBride, J., Blow, D., Kirby, T., Haines, T., Dayne, A., & Triplett, N. (2009). Relationship between maximal squat strength and five, ten, and forty yard sprint times.. Strength & Conditioning Journal, 6, 1633-1636.
  8. Merritt, G. (2004, March). Cutler's quad quiz: Jay Cutler answers 10 questions about thigh building. Flex, N/A, 96-101.
  9. Sifferman, J (June 2009)Physical Living. (n.d.). Physical Living. Retrieved April 18, 2010, from http://physicalliving.com
  10. Rippetoe, M. (n.d.). Starting Strength. Starting Strength. Retrieved April 2, 2010, from http://startingstrength.com
  11. Rogers, L., & Sherman, T. (2001). Leg Press Versus Squat. Strength & Conditioning Journal, 23(4), 65-69.
  12. Wisloff, U., Castagna, C., Helgerud, J., Jones, R., & Hoff, J. (2004). Strong correlation of maximal squat strength with sprint performance and vertical jump height in elite soccer players. British Journal of Sports Medicine, 38(3), 285-288.
  13. Woodrup, J. (n.d.). The Biggest Vertical Jump Training Site Online!. The Biggest Vertical Jump Training Site Online!. Retrieved May 2, 2010, from http://verticaljumping.com