Tennis and Olympic lifts

Power expression is what makes the difference between players in every sport arena. No matter in which way is expressed, as a faster acceleration, more powerful punch or higher jump, to have higher power capacity is a huge advantage on the court! For years the best method “prescribed” to develop power were Olympic lifts and their accessory lifts. In my opinion, they still are one of the best methods, but far from the truth that they are the only ones and that they suites for everyone.

When I’m creating a program for one athlete, first and foremost I’m always trying to analyze the cost and benefits of every exercise for an individual athlete. My first goal is to choose exercises based upon athlete’s need, movement patterns, preventative measures against injury, etc. There are no exercises that everyone must and should do, and the Olympic variations are no different.

In this post, I made a list of 4 biggest reasons why we don’t use Olympic lifts in Piatti Tennis Center, and why I’m against them for tennis player as a tool to develop power.

1) Highly technical

Olympic lifts are highly technical exercises and to learn them properly they need to be practiced almost daily for a long period of time. It takes a considerable amount of time to groove the proper movement pattern on such a complex lifts. Technique is something that can take weeks, months, even years to develop properly. Moreover, tennis is also a highly technical sport, players are spending a lot of time practicing. 3 and more hours daily at the court is considered normal. They need to do so to be able to learn how to execute every shot as perfect as possible, and for that, they need a lot of repetitions. In a perfect world, you should start with Olympic lifts at a young age, using stick to learn proper techniques which you need to repeat daily. But reality is completely different, after spending so many hours at the court there is almost no time left to work on some basic things outside the court. So, in my opinion, there are much more simple exercises solutions which we can introduce under power development.

2) Sagittal plane power

There is a big debate in the physical preparation community if bilateral, sagittal plane dominant exercises (like clean and snatch) are appropriate for rotational sports. Olympic lifts are not plane specific for a rotational athlete’s needs. What’s that mean? Olympic lifts are focusing mainly on triple extension in the sagittal plane of motion, they are missing hip and pelvic rotation, thoracic rotation, contralateral and ipsilateral force absorption and generation. Power for the rotational athlete is coming from the external rotation of the hip and so are we interested in too much sagittal strength and/or power? In my opinion, athletes can benefit more from med ball throws, different jumps and bounds, sprinting, pushing/pulling sleds…some exercises will mimic classic tennis movements from the court, using those means more pattering of force development in appropriate planes – frontal and transverse.

3) Accumulative stress

As mentioned before tennis players already at a young age (12 and younger) are spending a lot of time on the court (rarely less than 2 hours a day). By doing so they accumulate more stress in some areas of the body because of the repetitive nature of the sport. Olympic lifting puts extra stress on the same, already “overload” tissues = wrist-elbow-shoulder and back. There is a higher demand for wrist and shoulder mobility to be able to catch the bar regardless if we are talking about clean or snatch. When we start to load these patterns we start to put more risk in the lumbar region which is already under a ton of extension based stress during overhead movements = serve and smash.

4) Mobility demands

Proper execution of Olympic lifts – clean and snatch, require some specific mobility demands bilaterally. I emphasize this bilaterally, because rarely in my daily practice I can find a tennis player who has equal ankle mobility or hip mobility or shoulder/wrist mobility. Tennis is a unilateral sport, where there is always more stress in some areas like right shoulder girdle for right-handed players. Previous injuries, especially at the ankle or hip area are creating even more “mobility misbalance”, so I need to be very careful with my approach because the last thing I want to accomplish is to feed more into dysfunction! That’s why I put Olympic lift’s out of my toolbox. Why to take unnecessary risk when I have so many other choices.

Examples of Safe Alternatives to Olympic Lifts

1) Landmine Split Step Jerk

As you can see LSSJ does not require a true overhead catch, which automatically will eliminate stress on the shoulder – the lower back. Wrist is staying in a neutral position. Thanks to only one arm under load Jannik can adjust his elbow position to avoid too extreme closing angle. The overhead angle is far from vertical what is sparing compressive forces on GH joint. Exercises is easy to teach and execute, does not require high load when progressing because of unilateral pattern which makes exercises challenging. LSSJ can be regressed to bilateral starting position, or progressed to 1 arm Landmine Pivot Press which includes more rotational force production.

2) Medicine Ball Scoop Toss

This is pure rotational power. First 2 throws Jannik is trying to reinforce the pattern of using hips for more rotational power. Next he is doing lateral step to load back leg and then by using foot-hip-core-shoulders connection create rotational power.

3) Vertical Medicine Ball Squat Catch and Throw

If we want to incorporate some sagittal plane oriented work then this one is exercises we can use with everyone day 1. So easy to teach, only a few tips and med ball trajectory will show the athlete if he is using more hips or arm power. Actually, this one is a small progression because Jannik must react and control eccentric forces first and then explode vertically by using his hips as a primary source of power.

Arthrokinematics and Osteokinematics

In today’s post, I want to talk about 2 terms that are not so common in the world of physical preparation coaches or recreational fitness professionals. Usually, arthro and osteokinematics are more present in the vocabulary of physiotherapist and medical personal. Maybe we as physical coaching staff don’t need to have so deep understanding of these terms but some basic knowledge is so important and in this blog post I will try to explain why!
Let’s start with the meanings of these words:
Osteo = from the Greek osteon = bone
Arthro = from the Greek word arthron = joint
Kinematic/Kinetic = from the Greek word kinesis = movement
So in general Osteokinematics means bone movement and Arthrokinematics joint movement.
Osteokinematics is the gross movement that happens between two bones. This happens because our bone surfaces articulate at the joint where movements are: flexion/extension, abduction/adduction, and internal rotation/external rotation in different planes of motions.


From my perspective is critical to understand these movements for every joint in the human body. Next step is to know appropriate ranges in different planes of motion. In the picture above you can see hip joint, we need to be aware of optimal flexion/extension ranges in sagittal plane for example, how to assess this ranges, what can create limitations and interventions on how to solve problems. The same rules exist for other planes of motion where similar movements between bones exist. Is that mean that every hip of every person should move the same? Of course not, the general rule of thumbs for every joint exists but every human body is structurally slightly different. If we are talking about hip joint here is a list of possible anatomical hip differences:
1) different variations of pelvis structures – round, wide, narrow..
2) variations in the angle of femoral neck
3) acetabulum position
4) acetabulum shape
Why we need to be aware of osteokinematics on daily basis?
Simply because our daily job is to evaluate our athletes or clients, how they move, how they create movement patterns. If one day we spot some changes in movement comparing one hip to another (what yesterday maybe was not the case) we need to react immediately. If one hip for some reason is lost movement of extension, and if this limitation persists for some time, the body will try to find other areas for that missing movement. That is called compensation.
Arthrokinematics represents the small movements happening at the joint surface itself. Movements are rolls, glides/slides, and spins.
A) Roll is a rotary movement, one bone rolling on another.
B) Spin is a rotary movement, one body spinning on another.
C) Slide is a translatory movement, sliding of one joint surface over another.


Muscles are producing force, by doing so bones are moving creating movement at the joints as well. During movement, we need to respect proper alignment of the joints, if not passive stabilizers (ligaments, meniscus) are under more pressure. Let’s take an example of push up, in the bottom position head of the humerus tends to glide forward in the glenoid fossa (translatory movement), this can lead to either increased tensile stress on the tendons or compression of the tendons with excessive stress on anterior capsule!
To explain as simple as possible, in my daily practice I see Osteokinematics as something we need to be aware of even before the main part of the training start, before we start to load the body with high intensity. Does everything move correctly today? Is this person ready to “go hard” from the structural and positional standpoint?


In the picture above we can see excessive pronation of the left foot together with flat midfoot comparing to the right. Also, there is noticeable left hip internal rotation, is this person clear to squat, deadlift or any kind of bilateral stance work? I guess not…
Arthokinematics, on the other hand, are especially important during training, meaning: I need to be aware when they start to lose efficiency with this small unnecessary extra movements at the joint area.


Notice here during the end of row how humeral head is gliding forward putting excessive stress on anterior capsule. We want to avoid this with everyone, especially with overhead athletes. We must be aware during exercise execution what are joints positions!
Respecting osteokinematics as well as arthrokinematics is meaning that we understand the principle of joint centration, which is vital to joint health & overall performance!

Force absorption before force production

Developing power speed, explosiveness must be the ultimate goal for every coach who is training athletes, simply because this is what makes difference on the court, regardless of the sport. If you watch athletes competing, for example basketball or soccer in division II, and you compare them to the players from the top teams, everything seems faster, quicker and more explosive. This is mainly because of the capacity to produce higher power outputs compared to the players of the top teams.

Throughout my career I struggled a lot to find the proper way to make someone more explosive and faster on the court. I found it much easier to make an athlete stronger, but strength alone isn’t the best solution for most of the sports (if so, then power lifters would be known as incredibly strong athletes who also run fast, change direction explosively…). For me, the so called “game changer” was when I learned that to be able to produce force fast, I firstly must learn how to absorb forces. There is a huge advantage if an athlete is able to control efficiently eccentric forces before next jump, cut or when changing direction. We are all training our athletes too often with explosive movements where domination is put on concentric forces. Focusing only or mainly on this to create a faster athlete, we are missing another important part: deceleration and landing mechanics!!! Together with this I “figured out” that power development can be progressed and regressed not only through intensity and volume, but also through learning the patterns! I was already using this kind of approach for fundamental movement and during strength training, so first I did the progression continuum for power training which today looks like this:

One of the most important, but so often overlooked components of plyometric is the proper landing mechanics! Athletes need to learn how to be able to ABSORB high forces when touching the ground; the critical point to understand being that these forces are always higher than athlete’s bodyweight! The ability to absorb force uses advantage of natural mechanisms that exist in our muscles and tendons. THE MORE FORCE AN ATHLETE CAN EFFECTIVELY ABSORB, THE MORE FORCE AFTERWARD HE CAN PRODUCE.     To properly teach landing mechanics, which are highly related to deceleration abilities as well, first we have to understand how body works during these movements from the biomechanical prospective. Deceleration causes a high neural demand that puts a lot of stress on our body because of eccentric muscle action movements. Proper landing or deceleration involves proper coordination movements, such as bending the hips, knees, and ankles while maintaining centre of gravity by having core pre-activated. Teaching athletes how to start and stop moving properly, how to change directions efficiently, how to jump and land correctly, helps not only to improve speed and agility, but can also significantly reduce the chance of injury.

There are many exercises to teach and develop landing mechanics and, honestly, only the trainers’ imagination limits them. The basic ones are the following:

Drop Squat

Drop to Split Stance

Drop to Single Leg Squat

Vertical Jump to Squat Freeze

Lateral jump to freeze (pay attention to how much more difficult is for me to properly land on my left leg)



Isoinertial training has been invented as a solution for the strength training of astronauts. Because, during long travel in space, a problem to maintain strength and power of the astronaut’s muscles exists. In the absence of gravity, regular strength training methods with weights are useless. The term isoinertial comes from the words iso (same) and inertial (resistance). The primary concept of the isoinertial system is the same inertia in both the concentric and the eccentric phases of muscle contraction. The benefit of the isoinertial method and what makes it different from the isotonic muscle contraction is the fact that during isotonic type or conventional exercises (strength machines and free weights), the resistance is constant in both the concentric and eccentric phase. In the isoinertial method the resistance is adapted in every moment. What that means? It means that more force you produce in concentric phase, the same force you will need to control in the eccentric phase, which makes a HUGE difference from conventional type of exercising. So, an athlete needs to be able to absorb the same amount of force, which he/she can produce. However, the speed of action will vary as a function of the effort — just as in sports; there is acceleration and typically deceleration to break and stop and then change direction. This is how the skeletal muscle is designed to operate. If you follow statistics and researches, majority of muscle pulls or strains is happening during inadequate capacity to absorb high eccentric forces.

But what made me show interest about isoinertial training on the first place was the so called eccentric overload. After the end of concentric muscle action and during transition period there is almost zero resistance in the first 10-15° of eccentric phase, but after that you get “hit” with strong eccentric forces. When it comes to joints position and angles, this “eccentric punch” is happening around angles when you are on the court and want to change direction or do another jump! So, if you don’t understand it well, eccentric overload is happening at the most difficult and critical position to execute proper change of direction!

A number of researches have been carried out on the benefits of eccentric overload training in raising neural and muscular performance and in the rehabilitation and prevention of injuries. Some benefits include; higher forces are generated compared with traditional concentric action (LaStoya et al., 2003), unique neuromuscular activation which can be trained specifically (Enoka, 1996), stimulate specific micro-adaptations to regenerate a stronger muscle tissue (Brandenburg and Docherty. 2002), effective in injury rehabilitation (LaStoya et al., 2003; Lorenz and Reiman. 2011), increased hypertrophy adaptations when compared to other forms of training (Brandenburg and Docherty., 2002). 


Over-specialization with under-development

Early specialization by many sport scientists is today called the sickness of modern sport. In modern sport, young athletes need to spend so much time playing their sport because if they don’t do that, their opponents will! Let’s put it this way… imagine a 12-year old tennis player who is practicing at the court every day for 1.5 hours for 1 month. This means 45 hours/month. His friend is practicing 3 hours daily, which means 90 hours/month. In six-month period, this is 270 hours against 540 hours. If they play against each other on the tournament, it is not too hard to figure out who is going to win. At such a young age where physical characteristics are still not so dominant in sport with high technical demands, the winner is basically always the one who is training more specifically. Moreover, if that one continues to win a large per cent of his/her matches, we deal with the situation where, already at that age, managers, sponsors and possibly higher amounts of money are entering the game… Of course, with that amount of time spent on the court there is less time available to train outside the court and by training in that way we find over-specialized, but under-developed young bodies. What I mean is that these young athletes are already incredibly good at playing their sport but if you ask them to do the basic locomotive tasks such as forward/backward roll or simple bodyweight deep squat they are not able do it! Youth sports participation has evolved from child-driven, recreational free play to highly structured, deliberate practice devoted to sports-specific skill development!
And now, the big question is what can we, as S&C coaches, do with these kids who spend every day 3 or more hours on the court? First of all we need to step out from the classic S&C approach where we only think about jumping higher and running faster because kids are doing that on the court every day!! There are so many categories we need to develop to support the body to be able to jump and run during the actual play. Another important thing to consider is that modern children are not playing outside in the parks, they are not climbing and falling from trees, they are not riding a bike for the whole day and by not doing so they are not developing what I’m calling pre-athleticism!!
Here is a good example from TPI – Titleist Performance Institute training model for young golf players based on biological age. TPI is currently considered the best place for training young golf players and many facilities/academies of other sports are trying to copy their developmental training model.


On the other hand, we have similar situation in professional sport too! With so many competition events during one week or month (look at the NBA, Baseball, top soccer teams in Europe, tennis tournaments almost every week) athletes are, all the time, under specific load (playing sport) and there is little or almost no time (if you calculate traveling and changing time zones) for actual training. And if athletes get into this rhythm for several years, suddenly we have a situation of over-specialized, but under-developed body. Athletes are highly specialized, sometimes on the highest sport levels, but we can find massive anterior pelvic tilt with always-tight hip flexors; they want to stretch their hamstrings and/or calves day and night, and they do not know how to breathe properly. In my opinion, here again we need to step out of the classic S&C coach’s head and start thinking how we can help the athlete to feel better and to move better by not only loading him even more, but by correcting his body posture and allowing him to move with less compensatory movement pattern.
For high-level athletes we need to find a training solution: HOW TO DO MORE WITH LESS. And here I mean less volume, less intensity! Many times we don’t even have 1 day in a week to do proper strength training. What we need is a smart and intelligent approach to the training. Breathing, posture, developing movement patterns during low level and high-level intensities, fatigue resistance training modalities…

Modern Approach to Strength & Conditioning – Part 2

In the second part of this blog series I will share my point of view on developing efficient cardiovascular system via energy system development as well as my principles with regard to strength training. As I have already said in first part, the main purpose is to give you some ideas and information about something new that you might want to start learning about and incorporate it into your regular training routine.



Here we are talking about conditioning, developing efficient aerobic and anaerobic energy system! If we go even deeper, it is all about how our body produces ATP (adenosine triphosphate).
The body can produce ATP in two different ways: with or without oxygen – i.e. aerobically or anaerobically.
Anaerobically in two ways:
1) PCr hydrolysis (phosphocreatine hydrolysis) – energy from phosphate, which is fastest and more powerful, but not long-lasting <10” – ANAEROBIC ALACTIC ENERGY SYSTEM
2) Anaerobic glycolysis – energy from glucose – slower and less powerful but lasting longer than PCr 60-90” – ANAEROBIC LACTIC ENERGY SYSTEM

1) Oxidative phosphorylation – energy from mitochondrial glucose and mitochondrial fat – the slowest and not so powerful production but longest in duration – AEROBIC ENERGY SYSTEM

Regardless of type of sport, the 3 energy systems always work together rather than in isolation and by doing so ATP is produced in bigger or smaller amount aerobically and/or anaerobically. Of course that in marathon there is domination of oxidative phosphorylation as opposed to 100 m sprint, where the energy is dominantly coming from anaerobic resources. Every sport has its own specific energy demands, that is true, and athletes need to train that specific zones to be efficient in their sports. But one thing is really important to understand: athletes need well developed aerobic system! Why?

Athletes who can produce a greater proportion of their energy aerobically versus anaerobically will fatigue slower than athletes who produce a greater proportion of their energy anaerobically!

Efficient aerobic system can:
– help recover faster during the points or between periods of the match, and after the match as well

– strong aerobic system will spare ATP reserves – player will depend less on generating ATP anaerobically if he can use aerobic energy for longer period of time

– athlete will enter easier in parasympathetic mode, lower RHR, which comes as a result of good cardio base and can help decrease sympathetic drive, which helps to relax and recover between games


This is example of energy demands in tennis and as you can see there is high domination of anaerobic alactic energy system. By looking at this graph we can fall into a trap by thinking that there is obvious need to train almost exclusively in a range of 6-10’’ with submaximal to maximal intensity. This is far from the truth!

As you repeat an event over and over again, the proportion of energy produced aerobically as opposed to the anaerobic energy systems increases!

On the other hand, so many coaches are seeing development of aerobic system only through the low intensity steady-continuous cardio work! Aerobic training is not just low-intensity training. There is a need to train whole spectrum of aerobic development, from power to capacity to be able to stay longer in aerobic pathway of producing ATP.

Just remember that as long as you’re under anaerobic threshold and relying on the aerobic energy system to produce energy, you have a chance to live longer. As soon you are above AT to produce energy you are about to die fast on the field!


Getting our athletes stronger should be ultimate goal of every training process!

Strength is underlying capability for power and speed but equally important part of strength training is to prepare athletes’ JOINTS for stress via strengthening muscles & ligaments that hold them together!

Many of us like to watch videos on YouTube where guys lift incredible amount of weight in squats, deadlifts, bench press… Without question, this is really impressive, but the questions that remains in my head when watching these videos: is this kind of strength transferable into specific sport speed and agility? Because this should be our ultimate goal, shouldn’t it?

We are not training our athletes in the gym to become impressively strong dead lifters or squatters; we are using the gym as a helping tool to accelerate them on the court!

These are the principles that are building blocks in my approach to strength training:

Myofibrillar/functional hypertrophy more important than sarcoplasmic/structural hypertrophy*
Here we are talking about type of strength training causing growth of muscle contractile parts versus growth of plasma, organelles, and non-contractile proteins. Type of strength training that develop functional strength and power is more beneficial for general athlete than hypertrophy oriented strength training

- Proximal stability leads to distal mobility and athleticism
Importance of core control and strength as priority to every other aspect of strength development, but also every strength exercises where core is not involved is complete waste of time

Fundamental relative strength (FRS) before every other type of strength
Athletes need to have complete control over their bodies by having capacity of doing wide range of bodyweight movements with absolute control such as 1 leg squat, front plank, 1 leg reverse plank/bridge…

Unilateral strength more important than bilateral strength
Almost every sport is played on 1 leg, and if you are not familiar with the term BILATERAL DEFICIT you should absolutely learn it

- Low system training load – higher internal demands with less external stress on the body
example 1: split squat with barbell on the back = spine compression, more difficult to control proper posture, more difficult set up with high load
example 2: split squat /kettlebell in each hand = less load on spine, easier to control positioning of thoracolumbar canister, because of irradiation principle athlete can generate more tension by being “innervated” better by the surrounding muscles’ contractions = forearms>shoulder>lats>gluteus

Isoinertial type of strength training is the same (or maybe more) beneficial than isometric, isokinetic or isotonic
This is because:
a) Injury “PRE-rehabilitation”
Many of non-contact sport injuries typically occur when muscles are in lengthened position under high tension. Isoinertial training is oriented towards preparing muscles for that kind of stress because of high forces in this, almost overstretched, position
b) Eccentric muscle contraction overload = deceleration advantages
Eccentric overload is coming from the so-called ‘’delayed eccentric action’’. During isoinertial training 1/3 of eccentric motion is almost with no resistance and by doing this we are overloading the remaining 2/3 of the range of motion because muscles need to absorb the same amount of energy that is produced over the whole concentric phase but in a shorter period of time
c) Lower external stress on the body
Resistance is placed around waist so there is no compression of the spine during heavy lifting
d) Greater neural adaptations and neuromuscular efficiency with increased recruitment of high threshold motor units

CAT – compensatory acceleration training**
Lifting heavy weight with the intent to move it as quickly as possible during concentric part of the movement provides explosive strength benefits

*Mel Siff: Supertraining , Vladimir Zatsiorsky: Science and Practice of Strength Training
**Dr.Fred Hatfield

Modern Approach to Strength & Conditioning – Part 1

Modern Approach to Strength & Conditioning – Part 1

In this blog series I decided to share my view of how modern approach to strength and conditioning should look like. Everything here is based on my current knowledge and on more than 20 years of experience. The main purpose is to provide you with new ideas and information about something new that you might want to start learning and incorporate into your regular training routine.

The next slide shows what is essential for me with regard to the methodological, well-organized and long-term athletic development:


Before I start to talk about every segment of this pyramid, one thing I want to make clear. If, for example, SAQ-speed/agility/quickness is on the top of the pyramid that automatically doesn’t mean that is the least important and/or that it should be trained in the end, when all other parts of this pyramid are developed good enough. As every house should have strong foundations, my pyramid also has its own base qualities that are ideal to build one after another. So, if I have, for example, an athlete with poor movement quality that automatically doesn’t mean that I’m not going to train strength or power or speed, yes I will, but I must find adequate approach not to eventually hurt this athlete or over train him because of his movement limitations. In this part 1 I will talk about lower part of my pyramid, what I’m considering being the foundations and movement quality.


Five words, SLEEP-HYDRATION-NUTRITION-SUPPLEMENTATION-BODY COMPOSITION. It sound so simple, but so many athletes fail in one or more of these. We can be serious professionals and train hard every day, but if we don’t have adequate sleep regularly everything will fall apart. Moreover, we can train hard and sleep long enough, but if we are not paying attention to our micro and macro nutrients intake, the recovery process will suffer, immune system will not be able to efficiently protect our body, hormonal status will not be optimal… Hydration status is very critical before, during and after the training or competition. Water regulates your body temperature and lubricates your joints. It also helps transport nutrients to give you energy and keep you healthy. If you’re not properly hydrated, your body can’t perform at its highest level.

In the end, what is the sense of training if you can’t recover from it!


This graph is showing classic supercompensation cycle. Every well-organized training plan must have periods of loading and periods of recovering before the next training stimuli. Without putting attention to all the foundations, it is much more difficult to re-enter in the SUPERCOMPENSATOIN PHASE.

What can we use to monitor these 5 so essential categories if we want our training program to succeed? Bioforce HRV ( is on top of my list because it gives you information on day-to-day basis about the recovery process and athletes readiness for training. Measuring pH level is simple and effective way to control acidity/alkalinity of our saliva and/or urine. If you have metabolic or respiratory acidosis this can be a warning signal that something is wrong with your diet. Elevated levels of lactic acid in the system are an indicator of lactic pH imbalance, whilst dehydration can cause the acidic state of the body, and poor sleeping habits can influence your pH status. Whatever is the level of athletic intensity, a healthy pH balance can be the difference between good and great athletic achievements!

Simple questionnaire on a daily basis can give you so much information about the recovery and readiness for next training stimuli. Here is an example:



Our first task should be the INJURY REDUCTION and (then) the performance enhancement!

That is why, if an athlete can’t squat, there is no sense to load that pattern with extra weight because he will compensate that with muscles and joints that are not designed to execute that specific task. If someone can’t do proper shoulder flexion 120°, there is higher risk of injury whilst doing the overhead pressing. If an athlete can’t show proper hip flexion >90°, any kind of sprinting is inefficient and can lead to the injury. I could go on forever with examples, but today so many people in our field talk about this fundamental movement importance although few of them are having good approach at least from what I can notice. Every coach must be aware of the fact that with, for example, unstable core/pelvis, poor hip function, one or both ankles stiff, the athlete is competing with an injury about to happen.

An injured athlete cannot train and therefore can’t improve his athletic performances, only a healthy athlete can do that!

Movement quality essentially means: every joint and muscle must have adequate range of motion        (MOBILITY), capacity to sustain stress (STABILITY/STRENGTH), and on top of that an adequate coordination between these joint systems (MOTOR CONTROL) should stand.

If an athlete can’t demonstrate movement quality, then he is not ready to proceed with the movement quantity training – loading with weight or speed, or even just volume!

Movement matters and if you don’t believe in that I highly recommend you to learn methodologies like FMS (Functional Movement System), DNS (Dynamic Neuromuscular Stabilization), PRI (Postural Restoration Institute), FRC (Functional Range Conditioning) and then decide whether the movement quality is or isn’t important!


Self-myofascial release – pros and cons

Foam rolling and other techniques under the so-called self-myofascial release (SMR) continue to gain popularity in the fitness world today. These days, we can find foam rollers everywhere: in gyms, physical therapist have them, in living rooms, athletes travel with them… Like many other things invented in the last 20 years, in our fitness industry this training or treatment approach is, for some fitness professionals, also extremely important and beneficial, whilst for others is a complete waste of time. However, the truth lies somewhere in between. But, as we work with the real people and if we consider ourselves professionals, we owe our clients or athletes the best of what they need. When we want to apply some training methods, we need to have all the available knowledge not only about how to apply it, but also all the necessary knowledge about the science supporting it.

So let’s start talking about what the SMR can really do to our body:

  1. Autogenic inhibition and tissue desensitization

We all know what Golgi tendon organ (GTO) and muscle spindles are and without peeking too much into the science, they are two important neuroreceptors that are working together reflexively to regulate muscle/tendon stiffness. Like muscles, fascia also has receptors and they are called Pacini receptors and Ruffini corpuscles (there are more neuroreceptors both in muscles and in fascia, but these are the most common and therefore I will mention only them). They are all specialized to provide information with regard to touch, pressure, vibration and tension to the central nervous system. When, for example, the tension rapidly increases, the GTO inhibits muscle spindle activity within the working muscle (agonist) to prevent possible injury of the muscle or tendon. This reflex relaxation is called autogenic inhibition. Basically, it is a self-induced, inhibitory, lengthening reaction that protects against the muscle tear.  With the proper application of SMR, we can simulate these and other neuroreceptors by compression of the tissue, which will result in less tension in the muscle. This tissue desensitization is possible by compressing and stimulating neuroreceptors of the fascia too and by using the SMR techniques we can decrease the fascial tone.

  1. Increased blood flow and recovery

In the research published in Journal of Strength and Conditioning, foam rolling can lower the risk of developing coronary artery disease, blood clots, and other atherosclerotic diseases. (1)

Normal, healthy arteries relax and contract in order to increase and decrease blood flow, but they get stiffer and more rigid as we grow older or become inactive. The researchers found that foam rolling not only advances the blood flow and circulation to the muscles, but also loosens the arteries to maximize vascular performance. The deep compression of the muscles allows the normal blood flow to return and restores the healthy muscle tissue. More flash blood in the muscles-tendon and surrounding fascia means that we can speed up the recovery process to some extent. Moreover, healthy tissue acts as a sponge; through the movement and stretching there should be a sponge-like compression and expansion of the tissue with associated water in/out-take through the tissues.  The tissue that does not adequately act like a sponge will cause pain after some time and will become “bonded”, without normal sliding between tissues.           

  1. Relaxing trigger points

Trigger points can be found in both muscles and fascia and are made of thick and knotted tissue. We are actually talking about the tissue misalignment caused by trauma or injury, poor motor control patterns and emotional distress. Sometimes, trigger points can be accompanied by the inflammation and, if they remain long enough, what was once healthy fascia is replaced by inelastic scar tissue. Trigger points can be caused by poor posture and, if dysfunctional movement patterns remain long enough, the brain consequentely turns off the stabilizing muscles so that the prime movers start to work like stabilizers and become overtoned and tight. Below you have the example of process how scar tissue is formed in muscles that are always “on”.


This is one of the main reasons why we have so sensitive areas like upper trapezius, SCM, pectoralis minor, tensor fasciae latae…

SMR can be beneficial for relaxation, desensitizing these trigger points and adhesions formed between the muscle layers and fascia. What is important to emphasize is that it is impossible to completely break down trigger points or tissue adhesions or scar tissue by using the SMR techniques. For that, you will need a manual treatment practitioners as well as changing your posture or dysfunctions that are causing them!


These are three main things we can accomplish with SMR, and now I will try to explain two completely incorrect explanations of SMR benefits: 

  1. Improving flexibility

Foam rolling or any other technique used in SMR can’t improve flexibility!


When we are talking about improving flexibility, we are actually trying to make a muscle longer by increasing sarcomeres in series. If we try to do it (and there is no exact scientific evidence that this is possible), we need to put the muscle in its maximal length position and hold it there for a minimum of 30 minutes according to the Shirley Sahrmann’s theory.

Simply as it can be, when applying foam rolling, we don’t move the muscle through large excursions, which means we are not stretching the sarcomere in a new position!

But, after foam rolling, lots of people will say they feel much more flexible than before. This sensation is real because through the stimulation of neuroreceptors, you regulate your neural tone and with less neural tone in muscle and fascia, you can move more easily with fewer restrictions. But what is really important to understand is that these changes are not permanent, after 5-10 minutes everything returns back in what is considered the normal state for every individual.

  1. Improving the joint ROM

Available joint ROM is depending on many things that are linked together. How one joint will move depends on the surrounding muscles, tendon and fascia, on their flexibility, good coordination during action, if tissues are gliding one over the other smoothly. In addition, the stability and mobility of surrounding musculature crossing one joint have a big impact on how this joint will move. Then there are intrinsic factors, which include joint capsule with ligaments and other collagenous tissues and finally the joint structure itself (not everyone have the same joints with regard to the angular positioning of the different bones that are creating one joint). All of these factors have tremendous influence on joint ROM.

Now why is the SMR ineffective with regard to the joint ROM.

We can’t influence the anatomic composition of the joint with SMR. For example, limited ROM can occur because of the joint capsule tightness and can be treated only manually. There is no way you can treat such delicate areas with any technique from the self-myofascial release arsenal. If we want to improve joint ROM, we simply need to enter in these limited joint positions and “play” there with different techniques. Furthermore, whilst applying SMR we don’t work on the stability/mobility of surrounding muscles. Muscles on which we apply the SMR are mostly in passive position and there is no way to have the impact on the stability/mobility issues if they are the limiting factor in joint ROM. We can only influence the soft tissue extensibility and tone, where again changes we make are only temporary. These are the most obvious reasons why SMR cannot be considered as a technique to improve joint range of motion.

Here is a video clip from dr. Andreo Spina, where he is going even further trying to explain why foam rolling and other techniques can not actually be included at all under the name of myofascial release:



From strength and conditioning trainer’s perspective, the SMR is definitely worth it, but my impression is that this supplemental training approach is taking too much credit for things it can’t accomplish.

If you work with an athlete or a client who doesn’t have the possibility of regularly working with manual treatment practitioners (and by that I mean minimally 2-3 times a week), then SMR should be an integral part of each workout. In this situation we, as trainers, can use the SMR not only for warming up or recovery purposes, but also for “scanning” the body to find the tissue that is repeatedly too sensible during the SMR.  This can give us information about what is wrong and can help us modify your training plan.

In the situation when you have the help of a manual practitioner who works on the soft tissue, there is no need to incorporate SMR techniques into every workout. Rather then spending time on a foam roller, do some real mobility work by putting your joints in restricted positions where, by using breath, isometric contractions, irradiation, you can make more difference and help someone to move better.


(1)  T Okomoto et al. “Acute effects of self-myofascial release using a foam roller on arterial function.” Journal of Strength and Conditioning Research (2014): 69-73. PubMed. Web. 2 September 2015. <>




5 basic bodyweight strength test/exercises for every athlete

We can measure the strength in many different ways. First of all there are many different types of strength: maximal strength, explosive strength, strength endurance, strength speed, speed strength, relative strength. Along with so many different types of strength, we have even more exercise modalities for testing and developing each of different strength qualities.

However, here I want to talk about something completely basic, something that not only every professional athlete must be capable of doing, but also young athletes who are involved in regular sport activities. In my opinion, the most important type of all strength types is called fundamental relative strength (FRS) or how effectively can you control your own bodyweight. What I mean is that every athlete, regardless of age and gender, should be capable of doing this kind of exercises properly and with 100% control.

To avoid confusing you, here I’m not talking about classic relative strength. Example of relative strength is when you can deadlift 200kg with 90kg of your body weight, your friend can also deadlift 200kg but with 85kg of his body weight so his relative strength is higher because he can produce more force per kilogram of body weight. Here I’m talking about pure bodyweight type of strength where we are not using the external weight. I know what you are thinking now: calisthenics! Calisthenics indeed use only body weight for resistance, but when practicing calisthenics, exercises are done in more dynamic way most of the time using momentum when exercises or part of the exercises are too difficult to perform. Here we don’t want a momentum! These tests are done with a maximum control during movement, always with short pauses between eccentric and concentric part of the movement. These pauses are done to emphasize movement control and kinaesthetic awareness and to avoid the stretch-shortening cycle. Many times we neglect the ability to slow down the movements. In my opinion, we have to earn our right to be fast.

So let’s talk about FRS tests:

1. Test – Front Plank for 2′
When we are talking about athletic performance, we are actually talking about how efficient is the central part of the body in order to be able to transfer energy down and up through the kinetic chain! Period!!! We need to have well-organized core so that extremities could move freely and efficiently and this is the reason why modern training approach is moving more and more proximally. But what does that mean? It means that every exercise properly done must use the “core” to CONTROL rather than initiate the movement! From an injury prevention perspective, getting the athlete closer to the neutral position (front plank is one of basic exercises for that goal) takes the stress off the low back, hips, and knees. I know that if I can improve athletes’ posture, alignment, and stability in the sagittal plane first, this will have positive influence on frontal and transverse stability too! There is no better way to test how we control our core in sagittal plane than the old, simple front plank.

Why for 2’?
Dr. Stuart McGill (PhD), who is considered a leading authority in spine biomechanics and core development, says that in order to protect the spine, two minutes is a good goal to aim for a standard abdominal plank on your elbows. Holding the plank exercise for that long indicates that you have a reasonably strong core. It can also reveal if an athlete can control this perfect posture even when under fatigue. Another good point of view is Dr. Kelly Starrett’s. He is teaching about 20% constant tension concept or enough abdominal tone to keep braced neutral core position while playing, walking, standing or sitting. If an athlete can’t keep a good front plank for 2′, I doubt that he/she will have this 20% tension during playing or practicing when he/she is actually not thinking about the position of his/her core.

To perform the standard front plank, start by putting your elbows directly beneath your shoulders, forearms parallel, wrists and palms on the floor. Create double neck and pull your head back, push your elbows to the ground to open your mid scapula region, press your sternum down together with slightly posterior pelvis rotation in order to create neutral spine position. Legs are spread shoulder-width apart with knees locked and ankles dorsiflexed. In this position you should have the straight line along the ankles-hips-shoulders-ears. If someone would put a stick on your back, there should be 3 points of contact, sacrum-thoracic spine-head, with little or no space between lumbar spine and the stick. Try to breathe normally. Stay like this for 2′ please.

2. Test – Side Plank for 1′
If the front plank is telling us how good is the core control we have in sagittal plane, a side plank can tell us how good we are in frontal plane. Side plank can also reveal where the major problem exists in lateral component of stability. If it is more the core problem or maybe it is also the hip problem. In fact, during the side plank, a big role is played by three gluteal muscles too, minimus, medius and maximus. The frontal plane instability in the hips will lead to the excessive knee caving in during running, jumping or during regular lower body training in the gym (squats, lunges, step ups…). Furthermore, in my opinion, when we are talking about the side plank we are not talking only about the frontal plane stability, but about the component of transverse stability as well. Everyone who has tried the side plank had noticed smaller or bigger loss of balance whilst holding the position. To prevent falling down to the front or backside automatically include the anti-rotation stabilization movements – transverse plane!

Why for 1’?
Simply because in the front plank position we have 4 points of contact to create stiffness and stability, in side plank 2 points or 50% less…
To perform the left side plank, put your left elbow directly beneath your left shoulder, elbow at 90° with wrist and palm on the floor. Push your left elbow and forearm into the ground with your right arm resting on the right side of your body. Again create a double neck position pulling your sternum down together with slightly posterior pelvis rotation to create neutral spine position. Left foot is on the ground with right above it and the position of the both ankles at 90°. Knees are locked. Your body must be in a straight line with your chin-navel-2 medial malleolus. If someone would put a stick on your back, there should be 3 points of contact, sacrum-thoracic spine-head, with little or no space between the lumbar spine and the stick. Try to breathe normally. Try to stay like this for 1′. Then repeat on the right side. Here we also want to check if there is some asymmetry between the sides. Not only by checking if someone can keep the position for the same period of time on both sides, but also if the technic/alignment is the same for both sides.

3. Pistol Squat – 5 reps w/1” down position hold
I remember couple of years ago in my old gym when I was asking some strong guys who were squatting more than 150 kg to show me whether they can do a pistol squat. None of them was ever able to do even 1 solid rep. What is that telling us: you can be strong like a bull bilaterally and it means nothing unilaterally! And I honestly hope that everyone is already familiar with the fact that almost every sport is played on a single leg! Conclusion: athletes need single leg strength much more! Let’s educate their bodies to be able to have control, balance and strength to perform a single leg squat. Pistol squat is not only about the strength, but is more about building perfect interaction between mobility-stability-motor control in our lower extremities. Pistol teaches us how to properly load the hip and this is one of the most important athletic manoeuvres.

Perfect pistol is done standing on the flat floor and this is not very demanding for the working leg, but it’s also a good checking point for hip flexor on the non-working leg.

This 1” pause in the bottom position is only because we want to avoid rebound; on the other hand, the goal is to have control in the most difficult position. Pistol squat is an excellent indicator for proper acceleration, deceleration and change of direction movement capacity!
To perform a single leg pistol, stand with weight on your heel and your other leg slightly out in front of you. Push your hips back and bend your knee to slowly lower yourself; ideally you will be able to touch your heel with your butt; the knee should be over your mid-foot and the other leg extended in the air. Stay in this position for 1” and then stand up, do 5 reps and then try it on other leg. Here again we want to check for any kind of asymmetry between legs: heel off the ground, knee caving in, hip flexion on other leg, amount of spinal flexion.

4. Push Up – 10 reps w/1” down position hold
This test represents a simple way of checking whether an athlete has enough:
– basic strength and endurance in upper body musculature responsible for pushing
– core control during dynamic movement in sagittal plane
– interaction between scapula and GH joint
Why 1” down position hold? Simply because I want to avoid momentum, and you will be surprised how many of your athletes will struggle with this test. This one-second floor touch with the sternum (neck needs to be retracted) will completely avoid the stretch-shortening cycle and put much more stronger stress on core and scapula stabilizers to control the movement. You also want to check the scapula movement because the push up is a closed chain exercise and scapula needs to move freely on the rib cage. For example, many times you can find both or only one scapula in retracted position all of the time, which puts a lot more stress on GH joint. Secondly, this position of the scapula puts you in extended posture where the core will be inhibited.
To perform standard push up test lie on the floor, put your feet shoulder width apart, hands are set up so that middle fingers point straight up, forearms are perpendicular to the floor, elbows at 45°. Before starting, outstretch your legs by contracting your quads, rotate your pelvis underneath you, pull your head back and create the so called “double neck” by tucking in the chin. In this position the only thing that touches the ground is the lower part of the rib cage and upper abdominal wall; push up from this position.
Again 1” pause with the lower part of the rib cage touching the ground is only because we want to complete the control during the movement with no use of momentum at any time. We can also put a stick on athletes’ back to have better view on what is going on with his/her core during the execution of the test. Do 10 repetitions. As soon as the athlete loses its initial position, the test is over. For example, the head touches the ground first, hips are dropping down, changing position of the arms or legs.

5. Inverted row – 10 reps w/1” up position hold
For me, inverted row is nothing else than the reverse push up! So if someone is capable of doing 10 push ups, then in order to have optimal upper body strength and symmetry he/she should also be able to do 10 inverted rows, but unfortunately this is a very rare case. In my experience, 9 out of 10 athletes will fail to do this! But why is that important?
Many sports require from athletes to use their upper body to perform a throwing motion (baseball, softball, handball, basketball, swimming) or use a racquet (tennis, squash, badminton) in order to propel an object. Sports like football, soccer, wrestling, martial arts involve pressing and pulling with the upper limbs against an opponent. Imbalances in strength between agonist and antagonist must be analysed due to their association with injury and performance.
“Muscle imbalances have been defined as faulty relationships between the antagonist and the agonist muscles that will result with an effect upon the joint they cross.”- (Sahrmann S. (2002) Diagnosis and treatment of movement impairment syndromes. Mosby, St. Louis).
So in this case we are talking about the shoulder joint. In order to protect the shoulder, we need to have symmetry between pushing and pulling musculature. I choose inverted row and not pull up for example, because during the pull up you need to lift the whole weight of your body, in the standard push up you lift between 65-70% of your bodyweight, the same happens for inverted row when your body is parallel to the floor.
To perform parallel inverted row you ideally need the Smith machine or you can do it on the squat rack just be sure to block the barbell so it can’t move. As your complete body must be parallel to the floor (like in down push up position) you need the box at least 10-15cm high where you can put your both heels. Grasp the bar with overhand grip at the same width like during the push up test, raise your body from the ground and if you have the barbell on the correct height, your position should be parallel to the floor. Retract your neck, pull the ribcage down, contract your abs and gluts, your legs must be straight. Pull yourself up until your sternum (the same as during the push up test) touches the bar, stop for one second. Do 10 reps. As soon as the athlete loses its initial position, the test is over, for example forward head posture, hip sagging (the body doesn’t stay in a straight line), changing positions of arms or legs.

Fundamental relative strength test chart:

Fundamental Relative Strength Tests Score Notes
Front Plank 2′
Side Plank – Right 1′
Side Plank – Left 1′
Pistol Squat – Right 5 / 1” pause
Pistol Squat – Left 5 / 1” pause
Push Ups 10 / 1” pause
Inverted Rows 10 / 1” pause

After inserting results in the above table, you have an easy insight and know how to program your future strength training. If the score of an individual is low on some test, spend some extra time on that movement. Of course, if you have worked with athletes who are involved with sports or positions where strength is a dominant capacity, you will need to test squat, deadlift, bench press etc., but if you find that these athletes fail in one or more of the above mentioned FRS tests, involve that during the strength training too. You will find that these big lifts will improve working on fundamental relative strength. The same is true for power lifts like cleans, snatches or swings.
Someone can argue about these tests being too static and every sport is dynamic. At the end of a day this is true, but like I sad at the beginning, these are the basic tests that can show us elementary limitations in mobility/stability, inadequate motor control, asymmetries left/right and front/back or lack of strength. We all easily forget that everything must have a foundation. According to my training philosophy, if someone is not capable of holding static front plank for at least 60”, it will be very hard for him/her to control his/her core during a set of push ups, which is nothing else than a dynamic front plank. Moreover, so many coaches force athletes to do squats or lunges with a lot of weights on their backs to make them stronger and more athletic although none of these athletes has the capacity to perform a single leg squat. These guys don’t understand that pistol squat is a true indicator of athleticism! Develop the capacity to perform a single leg squat and then, if you need, load that pattern or every other with regard to the leg training and your athletes will explode!
Hopefully I have succeeded with the intention to ask yourselves at least a few questions about how to approach to the strength training in the future. Because at the end of the day, asking yourselves the tough questions and bringing your principles into dilemma, is the only way we can improve and become better coaches for our athletes!

Athletic stance – 4 important rules to have optimal position

There is one postural position/stance that is common to all multidirectional sports and it’s called athletic stance. Regardless to the surface (ice, grass, clay, hardwood) or type of sport (individual or team sport), athletic stance is position that can be repeated many times during one point or action, or during the entire match. This position can be the starting position before acceleration, or stopping position after deceleration. It can also be intermediate position during transition between two different moves and, finally, it can be “active waiting” position from which a player must react to another player or ball.

There is no universal definition of AS as it can vary between different sports (tennis or soccer), positions in the team or players’ position (defender or attacker). Generally speaking, athletic stance is a standing position that allows you to maximize your strength, power or speed in any direction. Changes in the angles of the ankles, knees and torso depend on the direction where we want to produce strength, power or speed. For example, there are differences in stance with regard to the pure vertical power vs. lateral speed. Because all of that, when we train athletes, AS is something we should address during the training process and develop properly in order to enhance other qualities that are categorized under power, speed and agility skills. Like with every other skill, first we have to learn some basics of proper positioning.

When I’m coaching athletes for proper AS positioning there are 4 most important rules:

  • Position of feet should be wider than shoulders with firm tripod contact


You need to have a wide stance because in this way you will be able to start moving in any direction you want – left, right, forward or backward. If you stay in narrow position, it is impossible to have rapid start in any of these directions because you don’t have the proper angle to push off. How wide is ideal? There is no perfect answer. If you are guard and play defense in basketball, you will want to have wider position than, for example, if you are returning serve in tennis. But if you like numbers, many researches are talking about 50° angle between your belly button and your heels.

Serve return position in tennis

Serve return position in tennis

 Feet can be parallel or up to 15° out of the toes. This mostly depends on how much dorsiflexion we have in the ankles. Good tripod contact with the surface (first, fifth metatarsal and calcaneus bone) is essential for efficient pushing of the ground in the direction we want to go and for executing proper triple extension of the ankle, the knee and the hip.

  • The position of knees should be inside the feet


In this way we can create a better push off angle in order to push our body in direction we want to move. For example, if we want to move to the right we need to push with our left leg. Start of the movement will be more efficient if we have left hip internally rotated with the knee positioned inside our left foot. If our knees are in line with the feet or even outside it will be much harder to start the movement and we will lose precious milliseconds to react.



  • Chest should be positioned over feet, back neutral not hyperextended


When chest is positioned in front of the feet we have weight on the front two-thirds of the foot. Why? Simply because if the weight is distributed mainly on the heels, the reaction time drops quickly. Try to execute any movement whilst “sitting” on your heels and you will feel like it takes forever to accelerate in any direction.



  • Back neutral not hyperextended position


Lower back should be as flat as close to the neutral position in order to create stiffness through the midsection. Everyone should know that proximal stability leads to distal mobility, so that with the proper positioning of the core, an athlete can create adequate stiffness to move his distal segments in more efficient way.


The myth of functional training

I was inspired to write this post about functional training since this term has been misunderstood by many personal trainers, strength and conditioning coaches as well as by physiotherapists. Almost everyday I witness, even on high-level sport training, what coaches and trainers do when it comes to “the functional training”!

What is the origin of the functional training idea? Who was the first to bring up this training modality to everyday life? Functional training has its origins in rehabilitation. Good physical therapists often use this approach to retrain patients with movement disorders. The whole idea is to work with patients after, for example, knee operation not only to regain full ROM at the knee joint but also to regain full movement pattern such as squat or lunge. After terminating with their physical therapy, patients-athletes are often released from medical institution just because they do not feel pain anymore. Without regaining the movement pattern they are doomed to a new injury sooner or later. FT can help people-athletes with no medical history to restore some basic movement patterns, which have been lost due to the lifestyle and/or wrong training approach. Movement patterns are often lost not because of the negative structural changes in muscles or joints, but because the nervous system is continually sending alarm messages to certain muscles and inhibitory messages to others. Therefore, functional training is actually every training approach used to address certain muscle imbalances.

Functional or?

And this is where the problem for me begins? Well, some trainers and physical therapists (who want to become trainers) are thinking too much and often come with great conclusions.
Example number 1:
If staying on Bosu ball can improve stability of the foot and overall balance than I can load that position and do 1 leg RDL (or whatever the name is for that exercises but you know what I mean) with barbell with as much weight as possible!! Oh boy, this is completely wrong! Why? If we follow the basic principles of human movement and strength training, we know that we should respect joint centration and how important is to do exercises to improve strength. Now try to do 1 leg RDL with barbell in your hands staying on the Bosu ball and try not to a) round your spine, b) have ankle-knee-hip aligned, c) put load on your hip properly keeping tibia relatively vertical! Impossible!!!
Example number 2:
I analyzed every tennis movement in detail and now I’m going to load those specific movements to improve power output. We are going to do forehand in open stance on cable apparatus with 10 kg with fast and explosive movement, like those that happen during the match or practice… Very stupid! Why? Because with this much weight (racket weights some 300 grams) the athlete will most certainly change its technique (tennis coach is not going to be happy about that), the speed will change as well – he will not be able to move 10 kg at the same speed as with the racket and from the specific power standpoint this is waste of time. Last but not least, the body will start to compensate – in order to move 10 kg quickly, some “wrong” muscles will start to do the job.
I could continue listing this kind of examples forever…heavy squats standing on fit ball, push ups with feet and hands in the TRX, split squat standing on 2 Bosu balls etc.

Real FT approach or whatever the name of that approach is

Generally we use unstable surfaces as type of training when we want to increase strength/reaction time of muscles responsible for proper stabilization. What Gray Cook was teaching us for so many years is that muscles that stabilize don’t need so much strength training, but good timing and reaction. Rotator cuff muscles could be showing high EMG during external rotation with elastic band, but during the pull up they are working even harder to keep humeral head into glenoid fossa and that is their primary task!
The basic idea of FT is to get to work our local and global muscle system in coordination. The LMS (local muscle system) is a group of small muscles located close or around the joint and responsible for adequate centration and stabilization, whilst the GMS (global muscle system) is a group of big and strong muscles, the so-called prime movers, because they are mainly responsible for producing powerful movement. These 2 systems can work efficiently only if a perfect joint centration during movement is present. If one of your femur bones has the so-called “anterior glide syndrome”, you have limited access to strength and power in that hip. In order to explain better how these two systems should work imagine a car where LMS is transmission and GMS is the powerful engine. If the transmission doesn’t work efficiently with proper timing to change the gear all that force that engine has cannot be expressed efficiently.
For example, if we have a client and we want him to do lunges or split squats but one knee is caving in during these movements, we need to introduce some functional training approach with some RNT techniques, using some unstable surface to engage more properly core firing and glutei activation. After we regain this fundamental pattern, the next step is to load that pattern and not to progress with unstable surface. We want to do as soon as possible the real “heavy duty” training and not certain circus training.
If someone shows me a perfect “eagle” squat with 2×24 kettlebells, I’m not going to put him on the balance board so he could show me if he can do it there. Instead, I’m going to give him 2×26…
And finally, for every client/athlete functional training should bring result in the everyday life/sport with regard to the improving ROM, stability, motor control of basic movement patterns – squat, hinge, push, pull and locomotion. If one exercise can improve some of these movements, I will call it functional.