Tag: athletic performance

Powerful Nutrition Strategy

Nutrition can have a powerful effect on an athlete’s performance. Not only does it strongly influence body composition, but food can both facilitate and combat inflammation, strengthen or weaken immune systems, and enhance or impair sleep (as a few examples).

Today’s “Thursday Throwback” features a very simple, but incredibly powerful nutrition strategy from my friend Brian St. Pierre. While this was originally posted in 2009, I still believe this is the first change you NEED to make!

Last summer I was fortunate to work alongside Brian St. Pierre. He is a brilliant nutritionist that continues to get phenomenal results with his clients. Brian really knows his stuff when it comes to altering individual diets to help people shed fat, build muscle, recover faster from workouts, and improve their overall health.

In today’s post, Brian shares with us a nutrition tip that will have a large impact on your health and performance.

Brian’s Nutrition Tip:

“Eat Real Food!”

“It may seem trivial or vague, but if you sat back and really took stock of the food in your home, you would probably be shocked to realize just how much of it qualifies as a food product, not actual food. Increasing the amount of real food, defined below, and decreasing the amount of food products you consume is the easiest thing you can do to improve your nutrition and health. It doesn’t require counting calories, worrying about nutrient timing, calculating macronutrient percentages, or any of that, and it will have a far greater impact on your health.”

Real Food Conditions:

If you couldn’t hunt, fish, pluck, grow, or ferment/culture the food, you probably shouldn’t eat it.
If it wasn’t food 100 years ago, it probably isn’t food today.
If it comes in a box or a plastic wrapper, it probably isn’t food, it is a food product.
If it contains lots of industrial vegetable oil (canola, cottonseed, soybean, safflower, sunflower, etc) and/or added sugar/high fructose corn syrup, it probably isn’t food, it is a food product.

If your response to this is “I knew that already”, you should probably ask yourself “Am I doing this?” Most people know what they should be doing; few are actually doing it. If you know anyone else that you feel would benefit from this information, please pass it on to them.

Brian wrote what I still firmly believe is the best nutrition resource for hockey players, parents, and coaches available today. Not only does it cover the “why” of specific nutrition and supplementation strategies, it covers the “how”, which makes every strategy incredibly easy to implement. Check it out here: Ultimate Hockey Nutrition.

To your success,

Kevin Neeld
OptimizingMovement.com
UltimateHockeyTraining.com

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3 Strategies to Maximize Recovery

Today’s “Throwback Thursday” post covers three powerful strategies to maximize recovery. Interestingly, I wrote another post on this exact topic recently that almost identically mirrors my thought process from 2009. In other words, over 4 years after this post was written, what I view as three of the most powerful recovery strategies has not changed at all! You can check out the more recent post here: 3 Powerful Recovery Strategies for Athletes

You may be surprised by how simple these are. It’s not a matter of cracking some magic code; it’s a matter of taking care of the things you already know are important.

1) Drink PLENTY of water. Maintaining proper hydration has positive implications on both mental and physical performance.Bluntly, it means you’ll be smarter and feel better if you drink enough water. Plenty is not 6-8 cups a day. That’s BARELY adequate for completely sedentary people on low caloric diets; you should be drinking AT LEAST double that.If you’re like most people, you’re not even close.It’s never too late to start. Increase your water intake significantly.You’ll likely be making many more trips to the bathroom than you’re used to, but that will cut back within a couple weeks when your body gets used to being fueled properly.

2) Sleep! Everyone’s sleep needs are different, but in general, most people should be getting 7-9 hours of QUALITY sleep.As in wake up in a pool of drool sleep.Wake up with no feeling in your arm because you didn’t move all night sleep.DEEP, QUALITY sleep.If you get 7 and you consistently wake up feeling tired, you need more sleep to recover from the stresses you’re experiencing (through training or other aspects of your life). Remember that this should be consistent from night to night.Your body doesn’t adjust well to 5 days of a lack of rest during the week, and then two days of excessive sleep on the weekend.Make it a priority to get a good night’s sleep every night.

3) Proper Nutrition. This comes in two parts: General Nutrition, and training-specific nutrition.With regards to general nutrition, it’s important that you eat adequate calories from QUALITY sources.This includes as many servings of vegetables as you can tolerate throughout the day, fats from olive oil, nuts, and cold-water fish (e.g. salmon), and carbohydrates from whole grain/high fiber sources.As a reminder, your carbohydrate intake should be determined by your activity level.The more medium-high intensity activity you do, the more carbohydrates you need.Training-specific nutrition is pretty straight forward.Consuming a liquid source of simple carbohydrates and rapidly digesting protein (e.g. whey protein) immediately after your training helps replenish glycogen (read: carbohydrate) stores within the body and stimulate protein synthesis (read: rebuilding).It shouldn’t be hard to see why this would be advantageous.There’s now research to support consuming these “shakes” immediately before and/or during your training, so the nutrients are readily available as your body begins to break down.Think of it as “on the fly” recovery.Personally, I usually make a half shake and sip it while I train, then make another half shake and drink it immediately after. For the complete nutrition guide, check out John Berardi’s Precision Nutrition program.

Following these three simple (well, at least they’re simple conceptually…maybe not so simple to implement) strategies will help you maximize your rate of recovery, allowing you to get the most out of your training.

Keep training SMART!

To your success,

Kevin Neeld
OptimizingMovement.com
UltimateHockeyTraining.com

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“…a must-have for coaches and strength professionals at all levels of hockey.”

The Truth About Deep Squatting!

This “Thursday Throwback” features an article I wrote over 4 years ago that overviews what may prevent someone from squatting deeply, and an assessment you can use to check your squat depth. Over the last several years, I’ve read a ton of research on hip anatomy and progressive structural changes. In the end, it seems that structural limitations are becoming more of the norm than the exception and it is incredibly important that coaches AND athletes/lifters recognize that what was previously considered a full squat may not apply to everyone/you. Symptoms of squatting past your range can manifest in many ways, but two of the more common ones are low back pain and anterior hip pain. I’ve also seen pretty significant discomfort in the piriformis, adductor complex, and TFL as a result of this pattern.

Check out the post below, as well as the article I link to, and please feel free to post any comments or questions you have below. This is an important topic that affects just about everyone that trains (or moves)!

The Truth About Deep Squatting

About a month ago, my article “Battling Anatomy: Implications for Effective Squatting“, was published at SBCoachesCollege.com, a website I couldn’t say enough good things about.

The other day I received an excellent question from Jason Price, Founder and CEO of Athletes Equation.

“Hello Kevin,
I read you article on SB Coaches College today and really found it informative and enjoyed it very much. I did have a few questions after reading that I was hoping you could provide me with some further information or clarification. What I have noticed with many of the youth athletes that I am training is that their hip mobility is terrible. I too have utilized the “touch and go” method to control how much depth they can attain until they have improved their mobility. I have found this to be a fantastic method for most athletes. But, I was thinking after reading your article about athletes which are dependent of being in the deep squat position in their sport. I train several weightlifters and one of them still suffers from a very similar condition as the individual in your videos. I am wondering what suggestions you would have for me in coaching this individual. In the sport of weightlifting as I am sure you are aware you must get into the deep squat position to effectively clean and snatch significant weight. My athlete does not have the significant discrepancy one side to the other. But, he does have the tuck under at the bottom of the deep squat position. So how can I effectively train him to receive the barbell deep in the squat with this technical flaw without placing him in this potentially hazardous position? Should he not squat deep? Do you know of any methods outside of orthopedic evaluation for anatomical abnormalities?

Again, fantastic article i really enjoyed it and felt you gave many of the readers an alternative viewpoint as to why some of these technical breakdowns happen. I appreciate your time and any response.”

My immediate thought is to first consider that everyone is not built for deep squatting. Despite the increasing usage of pictures of babies in a deep squat position as evidence for this ability, the hip joint and associated ligaments change as a natural/circumstantial part of development, that may result in a range of motion (ROM) limitation in some people. Having said that, it’s always better to assess than guess.

With regards to the lifter in the article video, the side-to-side discrepancy simply indicates that only one of his hips, the right one, lacks full ROM. In his case, I was able to recommend he see a hip specialist because he had multiple signs of CAM impingement. Notably, he lacked internal rotation ROM on the right side compared to the left and flexion/adduction on the right side was extremely painful.

Getting more to your question about the bilateral hip tuck, the first thing you could try is to coach him to push his knees out while he’s going down and to keep his knees out while driving up. This opens up the hips to allow for maximal hip flexion while avoiding bony contact between the trochanters of the femur and the “spines” of the hip bone. Mark Rippetoe wrote a great article called “You Don’t Know Squat without an “Active Hip”” about this topic.

If that doesn’t clear things up, there is a pretty straight forward assessment you can use to see whether this is a soft tissue restriction or a joint anatomy restriction. A few months ago I had the pleasure of talking to Shirley Sahrmann about this issue. She recommended using quadruped rocking to assess their ROM.

Quadruped rocking involves putting the lifter in a quadruped position, with their knees under their hips, top of their feet flat against the floor, and hands under their shoulders. The lifter should set up in a neutral lumbar spine position, then use their arms to push their hips back (pushing into hip flexion) so as to sit on their heels, while MAINTAINING the neutral lumbar position. Note the angle that the hips begin to tuck. Stop them there, have them return to the starting position and try again. Dr. Sahrmann basically said that 8-10 repetitions of this should improve their hip ROM. If it doesn’t, their hip joint anatomy doesn’t allow for it and never will. Any attempt to push beyond this point will lead to lumbar flexion, and invariably some sort of back pain.

I’ve found this assessment to be incredibly useful. In less than 30 seconds I’m able to see what kind of hip flexion ROM someone has. If their hips start to tuck at 90 degrees every time, and it doesn’t improve with more repetitions, I know that’s the extent of their ROM and stop them at that point during all exercises (squats, lunges, etc.). Depending on the severity of the restriction, this may also mean that they can’t perform a deadlift off the floor, in which case I’d move them to a rack pull from a height slightly above their end range.

Ask your athlete where they feel the restriction while quadruped rocking. If they feel like they’re tight on the back side, some mobility work may clear that up, but it’s also likely that quadruped rocking will clear that up. If they feel restricted in the front or any type of grinding in or around their “groin” area, it’s likely a hip joint limitation. I don’t recommend forcing lifters through positions their hip joints don’t allow for. That is, unless they’re looking for low back pain and a hip labral tear. Hope this helps.

To your success,

Kevin Neeld
OptimizingMovement.com
UltimateHockeyTraining.com

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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.

Optimizing Movement Q&A

With the official release of Optimizing Movement, I want to address several questions I’ve gotten both over the last week and over the last few years pertaining to the importance of maximizing movement quality and capacity. If you have a question not covered here, please post it in the comments section below!

Click here for more information and to watch the trailer! >> Optimizing Movement

What does “optimal movement” really mean?

Over the last several years I’ve referenced a growing body of research studies on a wide variety of populations that indicate that both athletic and non-athletic populations alike have an array of structural deviations and sub-clinical pathologies. Some are in pain; some are not. In other words, some may have issues that come to you as a red flag; others may not be aware of it at all (yet). Likewise, the Postural Restoration Institute has done an outstanding job of highlighting some of the structural and functional asymmetries that are present in all humans and how these may predispose different populations to specific injuries. Naturally, people also adapt to the stresses they DO or DON’T place upon themselves. These are small examples, but the big picture is that people are born with different structures and their structures adapt/change differently over time. Optimal movement starts by understanding the individual’s structural capacity. From here, the goal is to discover if the individual has limitations or imbalances WITHIN their maximum capacity, and then further prioritize which order to address these limitations depending on what the demands of the individual’s sport/activity are. Simply, the word “optimal” means allowing an individual to express their full movement capacity based on their structure.

How does optimal movement affect sports performance?

This is a bit of a loaded question and one that could be the subject of a book series. In short, there are three major buckets in which movement capacity can influence sports performance:

Economy
Skill Performance
Injury Risk

When a joint doesn’t possess sufficient range of motion or isn’t positioned optimally at any given time, another joint (frequently an adjacent one) will need to pick up the slack in terms of both providing the necessary motion to allow a certain movement, and in helping to produce or reduce/absorb the force that the other joint could not. As you can imagine, while this system allows the execution of some version of the intended movement, it certainly isn’t a very efficient system. Movement efficiency can influence both local (at a specific muscle or structure) and global (the entire system) conditioning/endurance, and may therefore impact how an athlete performs both at the end of a competition, AND at the end of the season.

Movement capacity can heavily influence skill performance. As a simple example, when a hockey player takes a slapshot, the movement necessitates internal rotation on the front hip, in this case the left. If the player doesn’t have sufficient left hip internal rotation (EXTREMELY COMMON!), they won’t have as large of an arc to produce force, they’ll lose some of their ability to use their glute to decelerate the movement, and they’ll need to compensate by both moving excessively at a neighboring joint (in this case probably more of a lateral bend and rotation of the spine/rib cage), and by excessively loading additional musculature to decelerate the movement. Tying this in to the third point, this environment can lead to breakdowns in a number of fairly predictable places: lumbar disc or spinal fractures, oblique strains and lower abdominal tears (e.g. sports hernias), anterior superior hip labral tears (the lack of IR on the lead leg will cause compensatory movement within the joint). This is a hockey example, but this can be paralleled to any high velocity rotational sport, such as baseball and golf, among others.

I just assume this went bar down?

While I presented these as three distinct issues, I don’t feel they can really be separated. I can’t imagine a situation where an athlete has a mobility limitation that impairs their skill expression and increases their injury risk, but improves their economy/conditioning. To me, it always comes back to the Athletic Performance Pyramid idea; the larger the foundation, the higher the peak.

Optimizing Movement is all about building a larger foundation, so the athlete can fulfill his/her TRUE athletic potential.

What if I don’t have time for assessments?

If you don’t have time, I’d suggest making time. Always think “how”, and not “if”. That said, I understand that some folks are in really tough situations and don’t have the flexibility to even determine where their time is spent with a team or client. In this case, I’d suggest looking for a new job! But in all seriousness, I get it. If you are an astute observer of movement, you can pick up on a lot just by watching your athletes/clients move. As I discuss in the DVD, a corrective approach isn’t just about corrective exercise. When you learn what to look for and have a system set up to address limitations when you see them, you can take a huge step in the right direction without including formal assessments. This is a major topic of Optimizing Movement and one that I think will resonate with just about everyone in the training and rehabilitation professions.

Is Optimizing Movement an ACTUAL DVD or just streamed online?

Optimizing Movement is a 2-DVD set. After you order, the DVDs will be shipped directly to the address you specify. In addition to the U.S. and Canada, the DVDs can be shipped to Australia, Asia, Europe, the United Kingdom, and Ireland. If you’re in an area where shipping isn’t currently available and would like to buy the DVDs, just drop me a note below and we’ll work it out. If you’re in a sunny area, I may even deliver them myself.

What if I don’t like it?

I can’t imagine that will happen. I sent an advance copy to a D1 Hockey S&C Coach, and he emailed me back with “Just finished the first DVD. Hands down the best DVD I’ve ever watched.” The information has been very well received and I know you’ll love it too! That said, I understand there may be a person or two out there that are offended I’m wearing a Flyers hat the whole DVD and will want to return it. The DVDs are backed by a 60-day 100% no risk, no questions asked money back guarantee. Simply return the DVDs and you’ll be issued a full refund.

Click here for more information >> Optimizing Movement

That’s a wrap! As I mentioned above, if you have a question that wasn’t addressed above, please post it in the comments section below!

To your success,

Kevin Neeld
OptimizingMovement.com
UltimateHockeyTraining.com

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