Tag: ice hockey training

Rethinking Bilateral Training

Over the last 5 years I’ve written over 650 articles for this site. It’s a little crazy to think about!

Because of the sheer volume of content, I find myself answering a lot of emails these days by searching for old articles I’ve written that answer the person’s question and just firing them back over. The reality is that I may be the only person among us that has read every one. In short, there is probably some good stuff that you guys are missing out on!

It’s for this reason that I’m starting a new “Throwback Thursday” series that will highlight an article from the past that still contains information that is relevant today. This will be a great way to reignite some conversation and discuss what (if any) changes in philosophy/training methods have resulted since these were first written. Today we’ll kick things off with an article that covers what I still feel is a fairly controversial topic (extremists on both ends). Enjoy!

Rethinking Bilateral Training

Bilateral training frequents athletic development programs everywhere. By bilateral I mean both legs or arms working simultaneously to produce force/motion in the same direction. Exercises such as front squats, deadlifts, standing shoulder press, and bent over row are just a few examples. While bilateral training and the associated exercises are deeply rooted in the history of strength training, it may be time to reconsider their use. Heresy you say?

I’m certainly not the first to make this suggestion. Michael Boyle has been making the case for single-leg training for years now. After reading one of his articles on the topic, I began thinking more about the lack of respect single-leg training receives. As the article mentions, people are probably reluctant to use single-leg training because they require less external load. This raises a few more questions. Is external load completely indicative of internal stress to the muscle? If so, is neglecting the movement pattern and maximizing the external load really the goal of training athletes? The article also mentions the “functional” inclusion of the medial and lateral musculature of the hips that is present in single-leg training and not bilateral training, functional being defined as “training the muscles that we’re using in the way that we use them.”

I want to preface the rest of this article by stating that I’m not yet calling for a complete abandonment of bilateral training. Instead I simply want to present some of the research supporting the empirical evidence that Coach Boyle presented in his T-nation article. In light of the available research on the nervous system, a working knowledge of functional anatomy, and injuries associated with heavy spinal loading, I think it is time to reconsider the efficacy of predominantly bilateral training programs.

Neural Hinderance?

A look into the literature on the nervous system’s role in force production revealed an interesting occurrence known as the bilateral deficit. For those of you that aren’t familiar, the bilateral deficit simply describes the fact that the sum of individual extremity force production is greater than bilateral force production (1-5). In other words, if you performed a one-legged knee extension with your left leg only, then your right leg only, and added these two forces together, they would be greater than if you performed a knee extension with both legs together. Bilateral Deficit: Leg A + Leg B > Both Legs
In fact, the bilateral deficit is said to be as large as 20% (6,7) during slow contractions and as high as 45% (7,8) during rapid contractions! Luckily, researchers were quick to monitor the changes in this relationship following a bilateral resistance training program and found that the deficit decreased. In some instances the relationship even reversed so that both legs produced more force than the sum of individual leg efforts (9,10). Phew! Disaster averted.

Neural scientists refer to the bilateral deficit as a phenomenon. I would question whether it is a phenomenal occurrence or a long-term adaptation to repeated movements. As many of you already know, performing a movement repeatedly strengthens the associated neural circuitry resulting in improved force production. In the words of my old neurobiology professor, “Neurons that fire together, wire together.” This is the primary explanation for why novice lifters can experience rapid gains in strength in the first eight weeks of training.

Is it possible that the bilateral deficit is simply a life-long adaptation to producing force on one-leg? I realize that no one grows up performing one-legged squats off their kitchen stools on a daily basis, but think about the movements we perform regularly, notably walking and running. While one leg is producing a triple-extension force, the other is usually producing a triple-flexion force. Let’s come back to the knee-extension example. In consideration of the “neurons that fire together, wire together” statement, it would make sense that as one leg is extending the neural circuitry is telling the other to flex. This pattern predominates in most human movements: walking, skipping, running, and even crawling!

The neural circuitry to explain this pattern is well-established. Some of you may have been introduced to it through the flexor crossed-extensor reflex. In this example, if someone steps on a sharp object or other painful stimulus, they will withdrawal that leg by flexing the hip and knee. At the same time, they will extend the hip and knee on the other leg. This is a stabilization mechanism. If both hips and knees flexed, you’d like end up sitting on the painful stimulus you’re trying to avoid. Basically, as the flexor group on one limb is excited, the contralateral flexor group is inhibited, and the contralateral extensor group is excited.

What does this have to do with athletes?

We are wired to effectively produce unilateral movements. Athletics involve unilateral movements. Most strength and conditioning programs revolve around bilateral movements. Why? I understand the benefits of including single-leg training is being increasingly recognized and that more unilateral training is being prescribed. However, it still seems that we’re adding some single-leg training to a double-leg program, instead of the other way around. What happens if we abandon double-leg training altogether? Compared to double-leg training, single-leg training:

1. Requires greater force production from more muscles. Picking up one leg immediately requires greater force production from the hip abductors and adductors (among others) to stabilize the pelvis. Some of the affected muscles would include: pectineus, adductor brevis, adductor longus, adductor magnus, gracilis, obturator internus, obturator externus, gluteus maximus, gluteus minimus, gluteus medius, psoas major, iliacus, sartorius, gemelli inferior, gemelli superior, piriformis, and tensor fascia latae.

2. Increases the proprioceptive and sensory demand. Decreasing stability by narrowing the base of support will absolutely necessitate greater proprioceptive and sensory feedback to maintain balance.

3. Decreases spinal loading. I’ve heard a saying a few times that goes something like “Live your life the wrong way, you’ll end up in a cardiologist office. Live your life the right way, you’ll end up in an orthopedic office.” This has come to be accepted as an inevitable truth. Research supports the idea that repetitive heavy spinal loading, as is common in long-term weightlifting, results in a myriad of spinal issues including an increased incidence of spondylosis (11), decrease in intervertebral disc height (12), lumbar spine degeneration (13). But does it need to be this way? If we can maintain or even improve the quality of the stimulus to the muscle and cut the external load in half, could some of these injuries be prevented?

4. Reinforces the neural circuitry common to most athletic movements. The majority of athletic movements occur from one-leg or a staggered stance. Could this more similar training approach help to decrease the incidence of injury? I’m thinking specifically of hamstring strains and ankle sprains. Hamstring strength absolutely plays a role in preventing hamstring strains. But how do we explain the athletes with monstrous hamstrings that suffer an injury? Bad running form? Maybe. Is it possible that these strains are occurring due to a neural mishap associated with hamstring momentarily attempting to contract concentrically bilaterally when one side should be lengthening? The causative factors associated with ankle sprains remain relatively allusive, but there does seem to be some evidence that decreased proprioception and increased peroneal stretch reflex latency may be related to ankle injury. As a global factor, fatigue seems to be related to injury, with more injuries occurring as fatigue increases. Of interest is that muscle fatigue is training-specific, meaning that if double-leg training predominates, the athletes will resist fatigue more efficiently in double-leg movements than single-leg movements.9 Naturally, the opposite is also true. Both of those factors are neural in nature, and may be positively affected by the increased demand on the sensory system provided by single-leg training. Prior history seems to be the greatest predictor of future injury. Therefore, if we can prevent an injury from ever happening, we significantly decrease the risk of future occurrences.

Admittedly, some of the proposed benefits of single-leg training on injury prevention are speculative. There is a clear list of benefits to single-leg training, however, that shouldn’t be overlooked. While I believe that largely moving away from double-leg training is premature (and somewhat scary), I think it is worth considering. Albert Einstein once said, “The significant problems we face cannot be solved at the same level of thinking we were at when we created them.” Weigh the pros and cons associated with eliminating double-leg training. Is it time for a change?

This article was originally published on StrengthCoach.com, an athletic development website where some of the world’s experts in strength and conditioning print their articles and discuss current issues.

To your success,

Kevin Neeld
OptimizingMovement.com
UltimateHockeyTraining.com

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References

1.    Obtsuki, T. (1983). Decrease in human voluntary isometric arm strength induced by simultaneous bilateral exertion. Behavioural Brain Research, 7, 165-178.
2.    Schantz, P., Moritani, T., Karlson, E., Johansson, E., & Lundh, A. (1989). Maximal voluntary force of bilateral and unilateral leg extension. Acta Physiologica Scandinavica, 136, 185-192.
3.    Secher, N., Rorsgaard, S., & Secher, O. (1978). Contralateral influence on recruitment of curarized muscle fibres during maximal voluntary extension of the legs. Acta Physiologica Scandinavica, 103, 456-462.
4.    Secher, N., Rube, N., & Ellers, J. (1988). Strength of two- and one-leg extension in man. Acta Physiologica Scandinavica, 134, 333-339.
5.    Taniguchi, Y. (1998). Relationship between the modifications of bilateral deficit in upper and lower limbs by resistance training in humans. European Journal of Applied Physiology and Occupational Physiology, 78, 226-230.
6.    Howard, J., & Enoka, R. (1991). Maximum bilateral contractions are modified by neurally mediated interlimb effects. Journal of Applied Physiology, 70, 306-316.
7.    Koh, T., Grabiner, M., & Clough, C. (1993). Bilateral deficit is larger for step than for ram isometric contractions. Journal of Applied Physiology, 74, 1200-1205.
8.    Vandervoort, A., Sale, D., & Moroz, J. (1984). Comparison of motor unit activation during unilateral and bilateral leg extension. Journal of Applied Physiology, 56, 46-51.
9.    Rube, N., & Secher, N. (1990). Effect of training on central factors in fatigue following two- and one-leg static exercise in man. Acta Physiologica Scandinavica, 141, 87-95.
10.    Enoka, R. (1997). Neural adaptations with chronic physical activity. Journal of Biomechanics, 30, 447-455.
11.    Aggrawal, N., Kaur, R., Kumar, S., & Mathur, D. (1979). A study of changes in the spine in weight lifters and other athletes. British Journal of Sports Medicine, 13, 58-61.
12.    Granhed, H., & Morelli, B. (1988). Low back pain among retired wrestlers and heavyweight lifters. American Journal of Sports Medicine, 16, 530-533.
13.    Videman, T., Sarna, S., Battie, M., Koskinen, S., Gill, K., Paananen, H., & Gibbons, L. (1995). The long-term effects of physical loading and exercise lifestyles on back-related symptoms, disability, and spinal pathology among men. Spine, 20, 699-709.

NHL Combine Training Program

Over the Summer I had an opportunity to train a junior player for the NHL combine. While I recognize that combine prep can be big business, I’ve steered clear of doing stuff like this in the past because I think training to prepare specifically for a testing battery can often be conflicting with training to prepare for the season. In this case, the player was one that was friends with many of the kids we trained already and had a very narrow window between finishing his junior program and attending the NHL Combine, after which he reported immediately to college to train for the remainder of the off-season. I wish I had the player for the full Summer, but it was fun preparing him for the combine before he left for college.

As with all of our athletes, we started this player off with an assessment and an overall “needs analysis”. We used our mobility screening to implement an individualized corrective program (as I discuss in detail in Optimizing Movement). From a performance standpoint, there were a few things to consider. The combine is an opportunity for programs to get an understanding of your physiological makeup, as well as your psychological makeup. To address the latter point, it was important for the player to recognize that part of what coaches are looking for is how you respond when things start to suck. There are a few tests in the combine (notably the VO2Max test and the Wingate) that aren’t very pleasant to go through; it’s important for players to dig deep and grind through these tests to leave a positive impression regarding their work ethic and resolve. We talked about this quite a bit, while he was training with us.

In terms of physiological profiles, what is viewed as advantageous (or disadvantageous) may depend a bit on the position of the player. In this case, the player was a goalie, so explosive power is an extremely important quality. I don’t always think it’s appropriate to judge players based on off-ice tests, but if I see a goalie with less than ~24″ vertical jump, I think they’re under powered and they better be EXCEPTIONAL in terms of their positioning and anticipation if they want to compete at higher levels. There are certainly some goalies that fit this criteria, but I’d much rather have an overpowered goalie than an underpowered one. Bottom line is the position requires a significant amount of explosive movement, and it’s important that goalies possess this quality.

In this case, the player came in and jumped 25.5″ with a counter movement, a number that isn’t remarkable in a positive or negative way. Being that the goal of him training with us was to help him stand out in this process in relevant areas, one of our major short-term targets was to improve this number as much as possible. Another major goal was to improve the athlete’s familiarity with the tests. This comes back to the idea I alluded to earlier, that test preparation and season preparation aren’t always the same thing. With our time frame, the more the athlete practiced the tests, the better prepared he’d be for combine.

Another major consideration when designing any training program is how much time the player has to train. In this case, we only had 3 weeks. This is extremely important, because it drives what can be emphasized with a realistic expectation of adaptation. If a player doesn’t possess a lot of strength, and you only have three weeks to make a difference, training methods involving higher rep sets with short rest periods designed to increase muscular size are unlikely to create a significant adaptation within that time window. In contrast, low rep, high intensity sets will have a much more profound influence given that the adaptations are primarily neural. In other words, from a speed/power/strength perspective, the training process in this time frame is much more about maximizing the individual’s current capacity than it is about creating a larger foundation from which to develop higher peak levels of these qualities.

In the end, the program consisted of:

Individualized corrective work
Contrast training to improve maximum strength and maximum power
Integrating each physical test into the program on a weekly basis (sometimes more)
High intensity work at a low volume to minimize fatigue accumulation and keep the quality and frequency of training high.
So-called “assistance work” to help keep the program balanced

The player trained 5 days per week for 3 weeks. The day of the combine, I got a text message that he tied for the combine lead in vertical jump at 28.5″, 3″ up from where we initially tested him 3 weeks prior. We actually tested him at 29.5″ at our facility the last day before he left (a discrepancy that could be explained by a number of factors, including a different warm-up process, nerves, etc.). All of his other numbers improved similarly, and in the end the player was rewarded for all of his hard work with a 3rd round selection (I was told this was ~2 rounds earlier than hew as projected).

Aside from being really proud of the work he put in, and happy that it paid off for him, I think this process helps shed light on the program design process in general. Every training program should be designed in consideration to the answers of these questions:

What is the athlete preparing for?
Who is the athlete (what is their training background and injury history, how do they move and what limits more optimal movement, and what are their current strengths and weaknesses)?
How much time do they have to train, both in terms of the total duration of their program, and how much time they can dedicate each week, day, etc.?

For Ultimate Hockey Training Insiders, I added the NHL Combine Prep program last week so you can see exactly what we did. If you’re not currently an Insider and are interested in joining, check out this link for more information: Ultimate Hockey Training

Ultimate Hockey Training-Membership Card Insider Small

To your success,

Kevin Neeld
OptimizingMovement.com
UltimateHockeyTraining.com

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Ultimate Hockey Transformation

Ultimate Hockey Transformation is the follow-up training program series to Ultimate Hockey Training, and features year-round hockey-specific off-ice training programs for players at the U-14 age level and above. The Ultimate Hockey Transformation system includes:

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228 high quality videos demonstrating how to perform every exercise in the program with perfect technique
A 65-page manual outlining everything you need to know to successfully use the Ultimate Hockey Transformation system!
Specific warm-ups, corrective exercise, and cooldowns to help you maximize your training preparedness and recovery
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The UHT Recovery Monitoring Log so you can prevent overtraining before it occurs!

Simply, following the RIGHT training program can completely alter the course of your career. Propel your game to the next level by following training programs proven to deliver game-changing results!

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The Truth About Concussion-Like Symptoms: Part 2

If you missed Part 1, you can check out the first half of the presentation here: The Truth About Concussion-Like Symptoms

The second half of the presentation was divided into two videos, which are available below.

As a disclaimer, I’m a strength and conditioning coach. I’m not a physician, nor am I an expert on brain injuries. The information in these videos is NOT meant to be taken as medical advice, nor does it suggest that concussions are being mishandled in any way by medical professionals in hockey. My interest in concussions stems solely from wanting to ensure that I can help the players I work with find the best care via the most appropriate referrals to medical professionals, to help make sure they aren’t missing unnecessary time.

The Truth About Concussion-Like Symptoms: Part 3

The Truth About Concussion-Like Symptoms: Part 4

*This information is by no means a replacement for medical advice or diagnosis, nor does it suggest that any of the players whose names or images were presented in the videos had cases that were mishandled in any way. It’s simply meant to provide additional potential causes of symptoms so players are aware of what other injuries they may need to get checked out by a medical professional.

To your success,

Kevin Neeld

P.S. It has often been said that injury prevention is just good training. Now you can get access to a comprehensive hockey training system that can be altered to help improve the performance of U-10 players all the way up through the pros: Ultimate Hockey Training.

Please enter your first name and email below to sign up for my FREE Athletic Development and Hockey Training Newsletter!

The Truth About Concussion-Like Symptoms

Over the last year, concussions have plagued all levels of hockey more than any other injury. While much attention is now being paid to the prevention of concussions and following more appropriate return to play protocols, the fact is that these injuries, and the other causes of related symptoms, are relatively poorly understood.

Last week I filmed a 30-minute presentation titled “The Truth About Concussion-Like Symptoms”. The presentation starts by discussing the basics regarding symptoms and the return to play process, which is incredibly important information to minimize the risk of repeat occurrences, and exponentially more profound long-term consequences. However, the real value of this presentation lies in identifying the most commonly overlooked predisposing factors and causes of concussion-like symptoms. As you’ll quickly see, we may have many players sitting out with concussion-like symptoms that don’t or no longer have a true concussion.

I strongly believe this is the most powerful collection of practical concussion information for hockey players that has ever been compiled. To make the information more manageable, I’ve divided the presentation into four parts. The first two are presented below. Please share this with everyone you know in the game of hockey. Information is power.

The Truth About Concussion-Like Symptoms: Part 1

The Truth About Concussion-Like Symptoms: Part 2

To your success,

Kevin Neeld

Please enter your first name and email below to sign up for my FREE Athletic Development and Hockey Training Newsletter!