Importance of Structural Balance for Injury Prevention

What is the Science Behind Structural Balance Assessments?

The concept of structural balance is that a muscle’s ability to develop force is a function of the strength of the opposing muscle group and its stabilizers. Many training and sports-related injuries are often the result of muscular imbalances – strength discrepancies between opposing and synergist muscle groups or even between limbs. These structural imbalances are often caused by a combination of the repetitive motions involved in many sports and/or a lack of exercise variety in training.

A Structural Balance Analogy:

Another way to understand structural balance to imagine you are building a house. In construction, the term “footing” describes the concrete support that the foundation is built upon. The footing also spreads the weight of the structure evenly over a wider area. The walls of the house are then built on the foundation. However, if the footing is poorly developed it compromises the stability of the foundation, which in turn, compromises the structural integrity of the entire house.

Each of the body’s joints are similar to the above analogy in that the joint is the house and the muscles and tendons controlling that joint are the foundation and footing. Viewed as a whole, if the stability of one joint is compromised it will affect the structural integrity of the entire body.

This is the proverbial “only as strong as the weakest link” axiom.

A joint is controlled by two primary sets of opposing muscle groups; one set of muscles flexes the joint and the other extends it. Synergistic muscles help the respective primary muscle perform its action. While one primary muscle group and its synergists are moving the joint, the opposing muscle group and it synergists are stabilizing it from the opposite side.

There is an optimal balance of strength between these muscle groups that control a joint, but if the muscles on one side of the joint are disproportionately stronger than the muscles on the opposing side it creates joint instability, which increases the risk of injury to that joint.

The take away point here is balance is important and vital to injury prevention.

Figure 1: Notice the difference between normal and imbalanced strength and its impact on a joint.

Figure 1: Notice the difference between normal and imbalanced strength and its impact on a joint.

When the central nervous system senses joint instability, it reduces the ability to continue strengthening the muscles that are already too strong. This an effective safety mechanism the body utilizes to protect itself from injury.

However, this safety mechanism can be “overridden” by attempting to force the already too strong muscles to get even stronger — many injuries occur under these conditions. If you place more strain on the weakest link than it can tolerate, the chain breaks.

While unpredictable accidents will still occur, a thorough structural balance assessment can:

  • Identify muscle weaknesses that leave a joint vulnerable to injury and compromise performance;
  • Faulty movement patterns that cause misalignment of the body, which results in distorted movement;
  • Muscle tightness that can result in strained or torn muscles, and;
  • Provide the blueprint from which your initial training program is developed.

A structural balance assessment also provides a starting point for your training. Your initial training program is developed based on the results of your assessment and aimed at correcting your weaknesses, faulty movement patterns, and tight muscles through a progression of corrective and remedial exercises. This approach expedites your results and helps ensure continuous progress.

A thorough structural assessment should be the first step of anyone’s training program whether you are a competitive athlete from any level of competition, an avid CrossFitter, or someone who wants to look better and improve your health.

Excerpt from Athletic Strength Institute

Stuart McGill on Abdominal Training

The science of spine stability: Effective spine stabilization approaches must begin with a solid understanding of what stability is. From a spine perspective it has little to do with the ability to balance on a gym ball. This is simply the ability to maintain the body in balance which is important but does not address the unstable spine. In fact, in many instances the unstable spine is also flexion intolerant and with associated intolerance to compression. Sitting on an exercise ball performing movement exercises increases spine compression to a flexed spine. This retards progress – it is generally a poor choice of back exercise until quite late in a therapeutic progression. True spine stability is achieved with a “balanced” stiffening from the entire musculature including the rectus abdominis and the abdominal wall, quadratus lumborum, latissimus dorsi and the back extensors of longissimus, ilioicostalis and multifidus. Focusing on a single muscle generally does not enhance stability but creates patterns that when quantified result in less stability. It is impossible to train muscles such as transverse abdominis or multifidus in isolation – people cannot activate just these muscles. Do not perform abdominal hollowing techniques as it reduces the potential energy of the column causing it to fail at lower applied loads (McGill, 2009). Interestingly a recent clinical trial (Koumantakis et al, 2005) compared the efficacy of many of the exercises that I quantified and published in Physical Therapy (McGill 1998), with the same exercises combined with specific transverse abdominis isolation (hollowing etc.). Adding the specific transverse abdominis training reduced efficacy! Instead, the abdominal brace (contracting all abdominal muscles) enhances stability. Target contraction levels for bracing and training techniques are described in McGill (2006). Finally, some provocative tests, such as a shear test, will help reveal which classification of patient is best suited for a stabilization approach (Hicks et al, 2005).

Linking Anatomy with Function: Consider the usual and popular approach to train the abdominal wall muscles by performing situps or curl-ups over a gym ball for example. But consider the rectus abdominis where the contractile components are interrupted with transverse tendons giving the “six pack” look. The muscle is not designed for optimal length change but rather to function as a spring. Why have these transverse tendons in rectus abdominis? The reason is that when the abdominals contract, “hoop stresses” are formed by the oblique muscles that would split the rectus apart. In addition to the spring-like architecture of the muscle consider how it is used. People rarely flex the rib cage to the pelvis shortening the rectus in sport or everyday activity. Rather they stiffen the wall and load the hips or shoulders – if this is performed rapidly such as in a throw or movement direction change, the rectus functions as an elastic storage and recovery device. When lifting weights it stiffens to efficiently transmit the power generated at the hips through the torso. Those individuals who do actively flex the torso (think of cricket bowlers and gymnasts) are the ones who suffer with high rates of disc damage and pain. Now revisit the common training approach of curling the torso over a gym ball that replicates the injury mechanics while not creating the athleticism that enhances performance. This is a rather poor choice of exercise for most situations. Yet many clients will expect that a gymball be used. Play a trick on these clients and retain the gymball but change the exercise from a spine breaking curlup to a plank where the elbows are placed on the ball. Now “stir the pot” to enhance the spring and spare the spine – this is a much superior exercise for most people.

 

gluteal muscle activation retraining based primarily on the original work of Professor Janda has been honed in our own lab (see figure 4). This cannot be accomplished with traditional squat training (McGill, 2007). Chronic back pain tends to cause hip extension using the hamstrings and subsequent back extension using the spine extensors creating unnecessary crushing loads. Gluteal muscle reintegration helps to unload the back. 

Finally consider exercises such as the squat. Interestingly when we measure world class strongmen carrying weight, NFL footballers running planting the foot and cutting – neither of these are trained by the squat. This is because these exercises do not train the quadratus lumborum and abdominal obliques which are so necessary for these tasks. In contrast, spending less time under a bar squatting and redirecting some of this activity with asymmetric carries such as the farmers walk (or bottoms-up kettlebell carry – see figure 7) builds the athleticism needed for higher performance in these activities in a much more “spine friendly” way. The core is never a power generator as measuring the great athletes always shows that the power is generated in the hips and transmitted through the stiffened core. They use the torso muscles as anti-motion controllers, rarely motion generators (of course there are exceptions for throwers etc but the ones who create force pulses with larger deviations in spine posture are the ones who injure first). Many more progressions to enhance athleticism in a spine sparing way are provided in my text “Ultimate back fitness and performance”

A comment on Flat Feet:

When the arches of the feet collapse, a lot of bad things happen. First, consider that the arch of the foot is supposed to flex and absorb shock. If the arch is flat, the foot lacks shock absorbency, and stress is transferred to the knees, hips, and lower back. This is why many of the advertisements for orthotics claim that they can resolve back pain.

With fallen arches, the bones of the ankle are not optimally aligned with the foot, increasing the risk of ankle injuries. According to the National Institute of Arthritis and Musculoskeletal and Skin Diseases, approximately one million people in the US are treated for ankle injuries every year. It’s also estimated that athletes who injure an ankle are five times more likely to injure that ankle again.

Fallen arches also cause the bones of both the upper legs and lower legs to internally rotate. This rotation increases stress on the ACL. The ACL is a ligament that connects the upper and lower leg bones and provides stability to the knee, making the ACL critical for dynamic movements. Approximately 300,000 ACL injuries occur annually in the US, and the risk of injury is greater to athletes and women. Also consider that only 30 percent of ACL injuries are a result of direct contact, which suggests that an important step to preventing ACL injuries is to address the structure and function of the foot.

Another consequence of fallen arches is that the inward rotation of the upper legs increases the arch in the lower back, a condition technically referred to as lumbar hyperlordosis. Lumber hyperlordosis reduces the ability of the spine to absorb shock. The result is an increased risk of back injury and pain.

The most common method of correcting flat feet is orthotics. Orthotics don’t permanently correct fallen arches – they only work while the user is wearing them. Also, the pressure of the orthotic on the arch can also cause the arch to become weaker.

Solutions include corrective exercises to strengthen muscles that support the arch. One such muscle is the extensor hallucis longus, which creates lateral tension on the foot and also strengthens and stretches the two major calf muscles (gastrocnemius and soleus).

Simpleton Guide to Poliquin Training

Part I
Sometimes, when I'm talking to Coach Poliquin about training methodologies, muscle fiber ratios, and all the assorted high-tech, laboratory aspects of weight training, my eyes start to glaze over?not because I'm bored or anything?but because he has lost me; lost me as surely as if he had driven me out to the desert in the back of his four-wheel-drive Jeep of knowledge, kicked me out naked into the midst of scorpions, rattlers, and cacti without so much as a bottle of Evian water, and left me to flounder out under the searing sun where I start to slowly bake and fricassee.

He'll continue expounding on the intricacies of what he knows better than any one alive, and I'll find myself playing little games to make him think we're still sharing the same planet: "Yes Charles, yes, it's so clear?why didn't I see it before?" Meanwhile, I'm staring at his nose, or fantasizing about that blonde I saw on the beach the other day, the one with that metallic thong that split her declivities so deftly in two as she bounded toward the surf, her bottom as brown as a berry and just as juicy... "Yes Charles, yes, don't stop, don't stop!"

Don't get me wrong; I'm not exactly a lightweight when it comes to the science of weight training. I've read more than my share of studies, articles, and books, in addition to having years and years of practical experience. And, I've played Sherman to Charles Poliquin's Peabody for practically longer than anyone else. I'm sort of a Poliquin clone; a juvenile, ill-formed, way-down-on-the-evolutionary-scale clone, but a clone nonetheless. Still, I'll never know everything Charles knows, regardless of how much I tag along with him like some sort of loyal hound dog.

The point of all this is that I can now formulate my own, Poliquin-esque workout routines without too much wailing and gnashing of teeth. What I've done is taken seven of his principles and committed them to memory, so much so that I can't do a single exercise without taking them into consideration. It's kind of like that best-selling business book, Seven Habits of Highly Effective People, but instead, I prefer the less elegant, more humble title, "A Simpleton's Guide to Charles Poliquin's Training Principles".

If you learn these seven principles and apply them to your workout routines, you'll have the next best thing to getting Charles to design your own, individualized programs. What's more, you'll more than likely experience more progress in your training in a short period than you have in the previous five years. Here, in a nutshell, are the seven principles I've adopted (I also gave them my own descriptive names):


The Borg Principle

Anybody who's ever watched the newer versions of "Star Trek" knows about the Borg. They're the bad-ass creatures who can't be beaten using conventional methods. Blast them or their ship with phasers, and they adapt. The only way to keep them off balance is to set your weapons on a constantly shifting frequency so they can't adapt. 

Well, your body is the Borg. It's designed to adapt. When you keep doing the same exercises in the same order, for the same amount of reps, using the same hand grip or foot stance, the body adapts. In effect, the nervous system becomes ""hardwired" to that particular routine and consequently, fewer muscle fibers are recruited, less energy is used, and fewer demands in general are made on the body. You become an expert at that routine, and after a surprisingly short time, you stop making progress.

If, however, you keep shaking things up, "changing the frequency," so to speak, the nervous system does not adapt. Instead, what happens is that the body?the muscles?grow stronger and bigger to survive the onslaught of your attack. Research (by Poliquin and others) shows that, in most cases, the body begins to adapt after having performed a particular routine 6 times. After that, it's time to shake things up again. 

Yes, to the Borg, resistance if futile, but in weight training, resistance to becoming stale is mandatory.


The Principle of Shifting Rep Ranges

Most trainers are hopelessly mired in the old 8-10 rep range scheme. It's as automatic for them as putting two spoonfuls of sugar in their morning coffee; getting a monthly haircut from Rudy, the gay stylist; or watching Dawson's Creek on Tuesdays and wondering what that Joey chick is going to look like when she gets a little bit older. It's largely habit. True, there's a lot of evidence that doing midrange reps is maybe the best compromise between rep ranges designed to build strength (between, say, 3 and 5) and rep ranges designed to build endurance (anything above 12 or so). However, to maximize results, you should work your muscles in all 3 rep ranges.

Muscle fibers are "typed" according to their oxidative capacities and how fast they fatigue. Historically, fast-twitch fibers (the ones best suited for growth) are worked by a combination of lower-rep, lower set routines. Fine. Except that muscles are also made up of slow-twitch fibers. You can't very well ignore them if you want to maximize gains. 

Therefore, you should juggle low-rep training (from 4 to 6 reps), intermediate-rep training (8-10), and high-rep training (12-15, or even 15-18) to make the best progress.


The II-B or Not II-B Principle

We just got done talking about fiber types. Well, true muscle physiology types (the kind that wear lab coats with the sleeves torn off) refer to these fibers using cute little alphanumeric terms, like II-A or II-B. These numbers refer to their oxidative capacity. Now, type II-B fibers are generally known as fast-twitch fibers and are the ones called on to do very heavy lifting. When you experience strength failure, much of it's due to the fact that these type II-B fibers have petered out?they just don't have the endurance of the other muscle fibers. They're like the fat truck driver who lives down the street; huge SOB, real strong, but can't run more than 10 feet without kissing the pavement. 

After these fibers are fatigued, it's hard to engage them fully in subsequent exercises. However, the other fibers, the type II-A guys, will still be fresh, and they're best stimulated with reps of between ten and twelve.

The point here is that you should do your heavy weight, low-rep movements first in the workout. Then, after those fibers are baked, go on to your higher-rep movements.


The Rest Principle

Somewhere along the way, taking short breaks between sets got confused as "intensity". If, after all, you're breathing heavy like a high school kid at a Tracy Lord film festival, you must be working intensely, right? Wrong, Viagra breath. In weight lifting, intensity refers to how close the weight you're using is to your one-rep maximum. If I lift 200 pounds ten times, regardless of how much I huff and puff, I'm not engaging in a high-intensity set. If, however, I push 300 pounds up only 3 times, my intensity level is very high.

With that in mind, let me say that people tend to rush between heavy sets in order to maintain a high heart rate. Heart rate has nothing to do with your goal here. If you want aerobic capacity, run 10-miles a day and turn into one of those pairs of lungs with some sinew attached that you see whipping along the parkway every morning wearing T-shirts that say something like, "Greater Orlando 225K Grapefruit Extravaganza Race".

The more intense the set, the more rest is needed between sets to allow for neural recuperation. If you don't rest long enough between intense sets, it's a safe bet that your lactate levels will still be high and that they'll interfere with your performance on the next set.

Typically, if you're working heavy, you should rest between two and three minutes in-between sets. On less intense sets, you can rest anywhere from 45 seconds to 90 seconds.


The Time-Under-Tension Principle

Muscle growing isn't just about reps and rest periods. It all comes down to something called "time under tension". In some circles, time-under-tension refers to the amount of time you spend tailgating that Ford Pinto that's doing about 45 in the fast lane. It also refers to the time your muscles are actually working and weight, sets, and reps all play a part in the equation. For instance, if you do a set of 10 reps, but you pistoned them up and down like the pelvic thrusts of one of those horny baboons in a National Geographic special, your total time under tension was about two seconds. Muscle is not going to grow when your time under tension is inordinately low (see the next principle for more info on "time under tension").

Typically, and depending largely on your muscle fiber ratio (some people have more fast-twitch fibers than slow or vice versa), your time under tension should be anywhere from 30 seconds to about 70. Any more or any less is counterproductive over the long run. (Determining your exact muscle fiber make-up is probably a little more complicated than we want to get into here in this article).

As you progress from one set to another and you tire, you have one of two choices: reduce the weight, or reduce the number of reps. Given that choice, you should always reduce the weight and keep the rep range the same or roughly the same. In other words, if you just did 8 reps at 200, you'll need to reduce the weight about 4 or 5% on the next set in order to do 8 reps again.


The Change the Beat Around Principle

In the previous principle, we talked about time under tension and we mentioned the wisdom of keeping the duration of a set somewhere in the 30 to 70 second range. How do you do that without doing 30 to 70 reps? The answer is something called tempo. For instance, if I'm doing sets of dumbbell bench presses for sets of 4 to 6 reps, my time under tension is going to be something like 15 seconds if I do them at "normal" speed. However, if I slow them down, particularly on the eccentric, or lowering part of the movement, I'll increase time under tension.

Whenever you look at a Poliquin workout sheet, you'll see numbers that look like 302, or 501, or something similar. They do not refer to different styles of Levi's jeans. Instead, they refer to tempo, and the first number indicates how many seconds you should take to perform the eccentric portion of that particular lift. For instance, a "5" means you should take a count of five to lower the weight. The next number refers to the pause taken between the eccentric and the concentric portion of the movement, while the last number refers to how long it should take you to raise the weight.

Okay, so what this means is that if you're working in a 4-6 rep range, you have to adjust the tempo in order for that set's time under tension to reach at least 30 seconds. Along the same lines, if you're working in the 8-10 rep range, the tempo should be a little quicker so that you won't exceed the 30 to 70 second time-under-tension frame.


The Yin and Yang Principle

Muscle builders always talk about the endocrine system; the muscular system; or even the cardiovascular system. But, they hardly ever talk about the neurological system and that's a big mistake. Consequently, neural recuperation is ignored.

Ever wonder why 99 out of a 100 trainees do multiple sets of a particular exercise in succession? For instance, they'll do one set of bench press, followed by another set of bench press, followed by another set of bench press. In between, they'll pretend to pull a loose thread on their toe-jammy socks while sneaking a peak at Ms. Hooters while she's doing dumbbell flyes. This supposedly allows the athlete to recuperate in-between sets.

Well, amazingly, research has shown that you'll achieve better recuperation by performing a set for an antagonistic body part in-between sets. For instance, if you do a set of dumbbell bench presses, do a set for your lats in-between and then go back to your next set of dumbbell bench presses. You'll experience less of a drop in strength in between sets. No one is sure why, but you can bet it has to do with the neurological system.


Some of you who are new to Charles' workouts may have noticed that he often labels his exercises as "A1" and "A2" or "B1" and "B2". This refers to the order of exercises. "A1" is usually the first exercise for a particular set for a particular body part, while "A2" refers to the second exercise and that exercise is almost always for a dissimilar body part. After completing A2, the trainee rests for the predetermined amount of time and then goes back to his second set of A1.

Other examples include doing a set of barbell curls, followed by a set of triceps extensions; or a set of squats followed by a set of leg curls.

There are plenty of other Poliquin Principles, but my feeble brain can only digest so much. It's like buying panties for my wife out one of those big Victoria's Secrets clearance bins: they all look so nice, but I can only fit so many in my wheel barrow. 

Anyhow, these are the ones that I use to formulate my workout programs. Next week, I'll show you how I use them to constantly formulate new, incredibly effective workouts without rupturing too many brain cells.

 

 

 

Part II
In Part I of this article, I carefully picked out seven of Charles Poliquin's principles and tried to make them a little easier to understand. Of course, as I mentioned, picking out only seven was a little like trying to pick my top seven favorite Hanson songs?okay, bad analogy. Trying to pick seven was like trying to choose which seven of my family or friends would get to go into the shelter with me when one of those Hollywood-movie asteroids blows up my town. Should I pick my dear, dear, grandmother, or that girl walking by who I've never met but who has a perfectly glorious rack? Anyhow, I made my choices based partly on cold logic and partly on emotion, picking some that worked particularly well for me or that suited my personality.

Hopefully, I made some of them easier to understand, especially if you're new to Charles Poliquin's ideas. Regardless of how well I explained them, though, they're essentially worthless unless they can be incorporated into a workable routine. 

In the beginning, I practically had to book some time on a Craig Supercomputer to help me figure out a Poliquin workout for myself. I mean, geez, with all the other things I had to factor in like speed of contraction and muscle fiber types, etc., etc., I was lucky if I didn't get confused and mistakenly devise an elaborate tap-dance routine: De Camptown Ladies sing this song, oh da-doo-da-dey?.

Anyhow, I eventually got pretty good at it, but I found that I'm a little too goal-oriented and compulsive and I found that a completely pre-planned workout was causing me too much anxiety. I looked at the whole thing as a checklist and I couldn't relax and enjoy myself until I had methodically gone through the whole thing. It felt too much?like work.

So, I adapted. I devised a system using the Poliquin principles listed above and made a workout that had some structure, but was variable enough to suit my personality.

First, I arranged a seemingly logical split:

Day 1: Chest and Back
Day 2: Biceps and Triceps
Day 3: Off
Day 4: Quads, hams, calves
Day 5: Off*

*I don't work shoulders directly?I know that sounds nuts, but I think that anyone who habitually works chest and back is already getting plenty of shoulder work. My aim is to keep my shoulders healthy so that when I'm eighty, I can still throw lumps of stale bread at the pigeons that congregate around my park bench.

As I mentioned, I don't do well with set-in-stone structure. I need a little leeway to do what I want to do occasionally, or to have another choice or two in case the machine or weight I want is being used by some yutz who's telling his entire life story to his personal trainer in-between sets. 

Therefore, I combine structure and spontaneity. Before I go into the gym, I've mapped out the first exercise (using the appropriate Poliquin Principles) for each body part I'm going to work that day and only the first exercise. As an example, the "written-down" portion of my chest and back workout will look like this:


A1)  Incline Barbell Bench Press Weight Used Sets(4)  Reps(4-6) Tempo(402)  Rest(120secs)
1) 
2) 
3) 
4) 

A2) Wide-Grip Chin-Ups Weight Used** Sets(4) Reps(4-6) Tempo(402) Rest(120secs)
1)
2) 
3) 
4) 
                         

**With chins, I'd strap some additional weight onto my waist.


Again, these are the only two exercises that are set in stone for this particular workout. More on that later, but let's take a look at the parts of this exercise prescription and see which principles they employ:

The exercises themselves: Note the "A1" and "A2" designation? For you Poliquin neophytes, that simply means I'll do one set of the A1 exercise (the incline presses), rest two minutes, and then go on to the A2 exercise (the chins). I'll rest for another two minutes and then go on to the second set of the A2 exercise. This incorporates the "Yin and Yang" principle explained in Part I of this article which, in a nutshell, says that you experience better recuperation when you do another set for the antagonistic body part in-between sets. So, you might consider pairing chest and back; biceps and triceps; and quads and hams.

Reps: Sets of relatively low reps target the type IIB muscle fibers, and these are the fibers that have the least endurance. Therefore, I do these low-rep sets early in the workout while these particular muscle fiber types are still fresh (the "IIB or not IIB" principle). 

Tempo: Note the 402 tempo indicated in my example workout. This tells me that I should take 4 seconds to lower the weight, no pause, followed by a 2-second concentric or lifting phase. By doing these slow, controlled reps, I'll ensure that my time under tension will be close to 30 seconds, which again suits these muscle fibers best (the "time under tension" principle, and the "change the beat around" principle).

Rest: Again, different muscle fiber types respond better to different rest periods, and type IIB fibers?which are being targeted here in my first group of exercises?respond better to longer rest periods. It may be difficult for traditional muscle builders to wait this long between sets, but it's the absolute correct thing to do if you're after additional strength and size.

Now, I'll record my weights and reps achieved for this workout, and I'll continue to do so for the next five workouts. Remember the "Borg Principle," the one that says your body becomes "hard-wired" to a particular routine? Well, it's true, and you really shouldn't do the same exercise or group of exercises more than 6 times in a row. After that sixth workout, I'll pick two new movements for chest and back. For instance, my "A1" movement might even be dips, doing 4 sets of one rep each, with a tempo of 15015 (that's right, 15 seconds on the way up and 15 seconds on the way down). Likewise, my "A2" movement might be close-grip chins for a 15015 tempo. 

You're probably wondering why I record these first two exercises and no others. Well, as mentioned, the completely structured, completely-planned-beforehand workout doesn't work with me, mentally. I find myself thinking about the next set while I'm still doing the current one. But, by keeping careful records of the first movement for each body part, I can determine if my workouts continue to be effective. For instance, if I fail to either increase the weight or the reps on each subsequent workout, I know I'm not hitting it hard enough on the subsequent movements. 

You, however, may prefer a lot of structure. If that's the case, simply write out your entire program beforehand using Chuck's principles. Just make sure you change your program after every 6th workout or so (that's every 6 workouts for that particular body part or parts).

Let me reiterate that the above exercise combo isn't my entire chest and back workout. Hardly. But after this, I free-wheel it, doing a combination of exercises that employ the Poliquin Principles but change constantly from workout to workout. This keeps me amazingly fresh (mentally) and allows me to keep making far more progress than I might have had I stuck to a completely pre-determined workout. 

For instance, after I've done these first two low-rep exercises, I'll want to do some mid-range rep training (approximately 8-10). Consequently, I'll often do two exercises that:

A) Work the muscle slightly differently, i.e., flat-bench dumbbell presses instead of incline barbell presses, and bent-over rows instead of chin-ups.

B) Incorporate a slightly faster tempo. Since I'm doing 8 to 10 reps, I don't want to do incredibly slow reps because that will bring my total time-under-tension beyond the 30-70 second range I've established for myself. Consequently, my tempo will probably be about 202 or somewhere in that range.

C) Require less rest. Since, by doing higher reps, I'm working the fiber types that have greater recuperative abilities, I'll rest only about 60 seconds in-between sets.

Okay, so we've done a few sets in the low-rep range and the middle-rep range. That means that a good portion of your total number of muscle fibers have been recruited and put to work. That leaves your slow-twitch fibers. They've barely broken a sweat and they're laughing at all the low-endurance fibers that are gasping, wheezing, and massaging their bruised sarcomeres. Time to put these high-resistance fibers to work with some high-range rep training.

I've got several options here for doing high-rep sets, but generally, I'll throw out the Yin and Yang principle when I do them. In other words, I'll do the same exercise for three consecutive sets without bouncing back and forth between two exercises for two antagonistic muscle groups. Sure, the Yin and Yang principle is designed to allow for greater recuperation of a muscle groups, but given that you're doing work specifically for muscle fiber types that have great endurance, we can temporarily ignore the Yin and Yang principle during high-rep sets.

For instance, I might do three sets of dumbbell flyes for 12 to 15 (or even 15 to 18) reps each, with only 45 to 60 seconds of rest in-between sets. Then, after I've completed all three sets of flyes, I might do three sets of one-arm dumbbell rows, again doing 12-15 reps (per arm) and taking only 45-60 seconds of rest in-between sets.

There are other options, too. I might, on occasion, do three sets of vertical bench presses (machine), doing a 6,6,6, rep-scheme where I do 6 reps to failure, wait 10 seconds, reduce the weight, do 6 more reps, wait ten seconds again, and reduce the weight and do a final 6 reps. After resting for 45 seconds to 60 seconds, I'd do the next set. In this just-mentioned scenario, I'm using heavier weights than I might for a straight-out set of 15-18, but I'm still fatiguing the high-threshold slow-twitch muscle fibers.

Obviously, there are as many exercise possibilities as there are walrus bones in the dumpster of an Eskimo diner, but the key is, at least for me, to employ as many of the Poliquin principles as I can in each workout. Rules, of course, are occasionally meant to be broken, and I don't always hold fast to every principle 100% of the time. The key to being successful in this and any endeavor is to be creative. Experiment, but keep the basics in mind. Deciding to use hedge clippers to remove an ingrown toenail certainly falls under the category of creative, but it just isn't going to work that well, is it?

Charles Poliquin on the Five Percent Solution

You may or may not be a mystery reader. Regardless, you've probably heard of the greatest sleuth of all time, Sherlock Holmes. Unfortunately, Holmes had a little habit that, today, would likely have qualified him as a Jeopardy answer in the category, "Guys Who Have Bunked With Dan Duchaine in Prison." You see, Holmes was an opium addict, and he was partial to a very precise mixture which he called the seven percent solution.

Well, I too have my own version of the seven percent solution, only it has nothing to do with illegal opiates. Instead, it has to do with rep schemes. I call it my Five Percent Solution. Let me elaborate.

There are a lot of effective rep schemes, but the fact is, they're only as good as the time it takes you to adapt to them. For beginners, a particular workout, coupled with a particular rep scheme, might guarantee progress for 4 to 6 weeks. After that, they'd be performing the exercise equivalent of getting stuck in a revolving door. Advanced athletes, on the other hand, might have to change their programs every week. Some even have to change their program every single workout!

Although some experts promise a lifetime of continuous results from doing the same routine day after day, ad nauseum, it's a cruel lie. Not only will your body adapt, but you'll probably quit because you'd be bored silly. For instance, one infamous trainer exhibits a fanatical obsession with one training method — his — to the exclusion of all others. His system requires only a fraction of the time required by most other programs, but it's difficult to do it for more than a few weeks because it requires that the trainee be either mentally disturbed or addicted to amphetamines in order to keep up the degree of effort required.

I recommend variety, of course, but there are some set-rep schemes that I tend to favor over others. I like them because they're mentally stimulating and physically challenging. Moreover, I like them because they're effective. One in particular is the aforementioned Five Percent Solution. It's effective regardless of where you are in the bodybuilding hierarchy. You can be a rank beginner, or master of the universe. In short, it gets your heart rate going and your muscles growing.


A Closer Look...
The Five Percent Solution involves a set pattern of progression. In a nutshell, you'll increase the amount of resistance by 4 to 5% each workout, while simultaneously reducing the number of reps by one each time. After you recover from the sixth workout, you'll have increased your strength in each lift by approximately 10%! 

People in the know in the field of strength training realize that the number of reps is the loading parameter to which an individual adapts the fastest, and the Five Percent Solution takes advantage of this fact. I'm sure people like Tony Little have no idea what I'm talking about, but no matter. The Five Percent Solution is based on the principle, "success breeds success".  Whenever people achieve goals, whether it's in business or athletics, testosterone levels rise. When T levels rise, your recovery ability improves. And, because you recover more quickly, you make more gains. Because you have more gains, you have more success and you make more testosterone, and so on and so on. 

Before I give examples of the workout, let's talk about the loading parameters of the Five Percent Solution.

The Intensity Zone

Select a 3-rep bracket to start the cycle. The number of reps should fall between 3 and 8. For instance, choose to do sets of 3-5 reps, 4-6 reps, 5-7 reps, or 6-8 reps. The decision is somewhat arbitrary; just make sure you write down the rep bracket you selected and stick with if for the duration of the program.


Tempo

The tempo (the time it takes you to complete one rep) should be the same throughout the 6 workouts of the phase. Depending on your goal, the total time under tension per set determines the chosen tempo. For example, if mass is your goal, the set should last at least 40 seconds. If relative strength is the desired goal, the total length of the set shouldn't exceed 20 seconds. 

Let's say the rep bracket you selected is 4 to 6 reps and your goal is to build mass. That means that it should take at least 40 seconds to do your 4 to 6 reps. Therefore, a suitable tempo for a set of six might be 412, where 4 is the number of seconds it takes to lower the weight; 1 is the number of seconds you pause; and 2 is the number of seconds it takes to raise the weight. Therefore, each rep would take about 7 seconds and since you'd be doing 6 reps, 6x7 equals 42. That means your total time under tension would be 42 seconds for that particular set.


Rest Interval

In order to allow the phosphagens to replenish and give the central nervous system enough time to recover and be able to activate the high-threshold fibers again, you need to rest 3 to 4 minutes between sets. 

It may be difficult for many of you to take that much rest, but believe me, your discipline will pay big dividends in the long run. In fact, failure to take adequate rest between sets will negate the positive effects of this program. I recommend using a stopwatch that beeps after the rest interval is over. As a note, strength athletes generally rest between 4 and 5 minutes after sets of the Power Clean or other Olympic lifts. The technical element of these lifts is much greater than that of conventional lifts; thus the demands on the nervous system are much greater.


Number of Exercises

I don't recommend doing more than 1 to 2 exercises per body part because you'll be doing a high number of total sets. Of course, the odd genetic freak or the steroid assisted athlete might be able to handle 3 exercises.


Exercise Selection

I recommend that you select compound exercises that recruit a lot of muscle mass. Therefore, exercises like rows, squats, deadlifts, or presses are the best choices for this method. Hopefully, you can use at least 100 pounds in a given exercise because it makes the math easier. It also makes it easier to change the weight since 1 1/4 pound plates are a rarity. Of course if your strength levels are low, you can always use PlateMates or Record Disks to meet the 4 to 5% weight increase.


Frequency

Work every body part once every 4 to 5 days. Here's one possible split:

Day 1: Chest and Back
Day 2: Legs and Abs
Day 3: Off
Day 4: Shoulders and Arms
Day 5: Off


Duration

This program is designed to be used for 6 workouts per body part.

Overload Mechanism

Do your initial workouts with the chosen number of reps and the predetermined weight. You'll then increase the load by 4 to 5% every workout for two workouts in a row. Concurrently, you'll also reduce the target reps by one rep for every weight increase. Then, after the third workout, you'll reduce the weight 4 to 5% but bring the number of reps back to the original starting point. If you've done this correctly, you'll have increased your strength by 5%.

If you're confused, I don't blame you, so let me offer an example:

The Five Percent Solution

Let's say you have a weak brachialis muscle and you want to improve your reverse curl strength. And, for the sake of this example, we'll say your best performance for the reverse curl is 100 pounds for 7 reps. This is what your rep/set cycle would look like:

Workout 1:
4-5 sets x 7 reps at 100 pounds

Workout 2:
Increase the weight from the last workout by 4-5 percent and do 1 rep less per set: 4-5 sets x 6 reps at 105 pounds

Workout 3:
Increase the weight from the last workout by 4-5 percent and do 1 rep less per set: 4-5 sets x 5 reps at 110 pounds

Workout 4:
Use the load you used in workout #2 for the workout #1 rep target. In this case, you're shooting for: 4-5 sets x 7 reps at 105 pounds

NOTE: If you achieve your goal, it means you're already 5% stronger!

Workout 5:
Use the load used in workout #3 for the workout #2 rep target: 4-5 sets x 6 reps at 110 pounds

Workout 6:
Increase the weight from the last workout by 4-5 percent and do 1 rep less per set: 4-5 sets x 5 reps at 115 pounds

By logical extension, if you did workout 7, you'd now be able to do 7 RM (repetitions maximum) with 110 pounds! That's a 10% percent increase in strength over 6 workouts, and that's excellent! (I don't actually map out the seventh workout because it would just be an exercise in vanity-the nervous system typically adapts to any workout program in 6 workouts and after that, it's time to move on to another type of program.)

Obviously, because of neuromuscular fatigue, you won't be able to achieve your rep target every set, but as long as you hit your goal on the first set of every workout, you're doing fine.

The Five Percent Solution Applied to Squats

Biomechanists have determined that when you do a squat, you're in fact squatting 75% of your bodyweight, plus the load on the barbell (Although it seems like you're squatting all of your bodyweight, you're not. After all, the legs are lifting the upper body; they're not lifting themselves off the ground). Keep that in mind when you adjust your squat poundages up by 5%. For instance, let's say you weigh 200 pounds and you're squatting 350 pounds for 5 reps. When increasing the weight five percent from workout to workout, the load increases would look like this:

Weight increase: 5% (load of barbell + (75% x bodyweight))
Weight increase: 5% (350 pounds + (75% x 200 pounds))
Weight increase: 5% (350 pounds + 150 pounds)
Weight increase: 25 pounds

So, in this particular case, a 5% increase would bring our hypothetical 200-pound bodybuilder's load to 375 pounds for his sets of 4 in his next workout.

Tips for the Five Percent Solution

In order to perform this program properly, I strongly urge you to keep a detailed journal of the exact number of sets and reps performed, load used, and rest interval taken. Furthermore, only count the reps done in strict form. Go ahead and do forced reps for the last rep of every third workout, but don't count them as complete reps.

Wrap Up

I hope that the Five Percent Solution isn't too confusing. I think that you'll find it well-worth all the head scratches and furrowed brows it took to figure it out, though. If enough of you find that you like it, let me know and I'll fill you in on the Advanced Five Percent Solution.

In any event, if there's such a thing as one singly unifying theory of training as Mike Mentzer claims, it's that the best system is the one that constantly changes. As your body adapts, its recovery ability increases and higher levels of volume and intensity of training are needed to ensure further growth.

Difference Between Lactic Acid & Lactate

By Andrea Cespedes

You'll hear "lactic acid" and "lactate" used interchangeably by trainers, coaches and other sports experts. Colloquially, people assume you mean the same thing when you use either term, but they are technically different. Lactate is produced by your body in response to aerobic exercise and serves as a fuel for the muscles, delays fatigue and prevents injury. Lactic acid contains one additional proton and is not produced by the body at all during exercise.

One Proton

The technical difference between lactate and lactic acid is chemical. Lactate is lactic acid, missing one proton. To be an acid, a substance must be able to donate a hydrogen ion; when lactic acid donates its proton, it becomes its conjugate base, or lactate. When you're talking about body's lactate production and lactate or lactic acid threshold, the difference is largely a matter of semantics. But, the body produces and uses lactate -- not lactic acid.

What Is Lactate?

During hard exercise, from running a race to surfing the waves, your breathing rate increases to deliver more oxygen to the working muscles. Some exercises are so intense -- such as lifting a heavy dumbbell or swimming away from a shark -- that your body cannot use oxygen fast enough as a source to create fuel. For these quick, intense bursts of activity, your body needs to move into anaerobic mode -- during which the stored energy in your body is broken down into a compound called pyruvate.

When you don’t have enough oxygen to perform activity, your body turns pyruvate into lactate to fuel the muscles. Fit folk can utilize this form of energy production for one to three minutes.

High Levels of Lactate

As the muscles work at intense levels, they become more acidic, which interferes with firing. Lactate isn't the cause of this acidity; it's actually an antidote to this muscle failing. As your muscles lose power and energy, lactate swoops in to help counteract the depolarization of the cells. This is the familiar burn in the muscles you feel when you just can’t do another rep. Lactate production is a protective mechanism that prevents the body from hurting itself. When lactate production can't continue to the levels needed to prevent the complete failure of the muscles, you reach your threshold.

High levels of lactate -- or, as it is sometimes called, lactic acid -- were once blamed for delayed-onset muscle soreness. Lactic acid or lactate are not responsible for the soreness. Rather, researchers believe it is due to micro tears in the muscles that occur during strenuous exercise.

A Measure of Athletic Success

Lactate is essential to the exercising process. It helps bolster the mitochondria, energy powerhouses inside each of your muscle cells. Increase the number of mitochondria in your cells, and you'll improve your stamina and strength. High-intensity interval training in which you do short bouts of very strenuous exercise at or near your lactate threshold followed by recovery is especially effective in developing your lactate threshold. The better able you are to process lactate, the greater your ability to push high levels of performance.

About 75 percent of the lactate you produce during exercise is used as this moderating energy source; the other 25 percent leaks into the blood, which is how scientists test lactate levels during exercise. At one time, it was thought that high-level athletes produced less lactate; it's more likely that these athletes are better able to utilize the lactate they produce and leak less into the bloodstream, so their tests show lower amounts.

Resistance Training’s Effect on Endurance Performance

Research shows that the appropriate integration of resistance training into the endurance athlete’s training can result in significantly better performance when compared to classic endurance training plans that focus only on aerobic endurance.

Research shows that the appropriate integration of resistance training into the endurance athlete’s training can result in significantly better performance when compared to classic endurance training plans that focus only on aerobic endurance.

The following is an exclusive excerpt from the book Developing Speedpart of the NSCA’s Science of Strength and Conditioning Series with Human Kinetics.

Endurance athletes who are stronger can generally perform at a much higher level.

This suggests that training modalities that stimulate increases in muscular strength without compromising endurance capacity may be beneficial for the endurance athlete. Support for this contention can be found in the scientific literature; research shows that the appropriate integration of resistance training into the endurance athlete’s training plan can result in significantly better performance when compared to classic endurance training plans that focus only on aerobic endurance training.

When looking closely at endurance performance, several key factors—including the athlete’s maximal aerobic power (V˙ O2max), lactate threshold, and movement efficiency—contribute to performance (see figure 7.1). The training modality selected influences these factors by inducing changes to the athlete’s aerobic power and capacity, anaerobic capabilities, and neuromuscular function.

Aerobic training exerts a strong influence on both aerobic power and capacity, but it does not exert a great impact on the athlete’s anaerobic or neuromuscular abilities.

Conversely, resistance training exerts a strong influence on the athlete’s neuromuscular function and a moderate influence on anaerobic power and capacity, while offering only a minimal influence on aerobic power and capacity. By influencing the athlete’s anaerobic abilities as well as neuromuscular function, resistance training can elevate the athlete’s lactate threshold, movement efficiency, and ability to engage in high-intensity activities.

The ability of resistance training to improve endurance performance is likely related to several key factors, including the specific physiological and mechanical adaptations that are stimulated by the resistance training regimen. The integration of resistance training into the overall training plan appears to be central to creating these specific performance-enhancing adaptations.

Traditionally, endurance athletes and coaches have believed that resistance training either does not affect or negatively affects endurance performance. However, this view may be partially explained by a design flaw in many of the training programs that include both resistance and endurance training. The flaw is that resistance training is simply added to the endurance training plan. Athletes who undertake this approach often experience excessively high levels of fatigue that can negatively affect overall performance.

If athletes reduce their endurance training load to account for the addition of resistance training, then resistance training has a positive effect on the athletes’ endurance performance. The athlete who performs both resistance and endurance training in an integrated and appropriately planned fashion will perform at a higher level than the athlete who performs only classic endurance training.