Recovery from concussion – a guest blog by Kate Moores

Following our last blog on concussion, I started talking to Kate Moores via twitter (@KLM390) who had some very intersting experiences and ways of managing concussion. So, I am very pleased to introduce Kate as a guest blogger on the topic of Concussion assessment & management – we have decided to split Kates blog into 2 more manageable parts rather than one super-blog (My contribution may have been to add the occassional picture to the blog).

The original blog (here) discussed generalized pitchside assessment of a concussion, irrelevant of age. However Kate has drawn on her knowledge and experience with young rugby players to highlight in particular, the ongoing assessment of young athletes as well as adults and how it differs. Kate raises some very good points throughout but the point that really made me reflect was the consideration over “return to learn.” Looking back at concussions I’ve managed in academy football, I didn’t properly respect the impact that a day at school may have had on symptom severity or neurocognitive recovery. I was mostly interested in “have you been resting from activity?” I think this blog is an excellent resource for medical professionals, but also for teachers, coaches and parents to consider the impact of this hidden injury.

This is part 2 of Kates guest blog (part 1 here).

 

Recovery

Any player regardless of age should never return to play or training on the same day that they sustain a concussion. So when should they return? The general consensus is that players should be symptom free prior to starting their graded return to play and that youth players should have a 2 week rest period and that youth athletes should have returned to their normal cognitive activities symptom free prior to considering a return to play. It is therefore recommended that cognitive rest is adhered to for 24-48 hours post injury. This means no texting, computer games, loud music and cognitive stress. This can be difficult to get players to adhere to however research has shown that a period of cognitive rest helps to reduce the duration of symptoms.

“They said something about no computer games”

The concern with any concussion, but increased concern with children returning to play too quickly is the risk of second impact syndrome, with well publicised cases including the tragic death of Ben Robinson a 14 year old rugby player and more recently Rowan Stringer a Canadian rugby player aged 17. Children are at a higher risk of second impact syndrome (McCory et al 2001) and this risk continues for anything up to 2/3 weeks post initial injury. This is part of the reason why an u19 rugby player can not return to play earlier than 23 days post injury unless they are being managed by a medical doctor who is experienced in managing concussions. Below is the concussion management pathway from the WRU.

Under this protocol adult athletes would be able to return within a minimum of 19 days after a concussion whereas u19s would not return before 23 days. Both groups need to be symptom free and have had a 2 week rest period prior to return. For the younger age group it does state that they must have returned to learning however there is no guidance as to how this should be staged. The graded return to play protocol consists of 6 stages which gradually increase the level of activity. Stage 2 starts with light aerobic exercise, stage 3 includes light sport specific drills, stage 4 includes more complex drills and resistance training, stage 5 is return to contact with stage 6 being return to normal activity. With children there must be 48 hours in-between stages as opposed to 24 hours with adults.

As mentioned, return to learning protocols are less well documented, there has been some proposed protocols from Oregan and Halted et al (2014) who state that a youth athlete should be able to tolerate 30-40 minutes of light cognitive activity prior to a return to school and that players should be gradually return to normal school activities prior to their graded return to play.

At present youth athletes are part managed as students and part managed as athletes, however there is an emerging theme that return to activity is potentially a far more appropriate method of managing a childs recovery from concussion. We need to do more work to align both protocols. A player may well be “fit” to return to school and therefore deemed “fit” to return to light activity and subsequently drills, however very little research has been done to look at the impact of skill acquisition in a physically challenging environment. Learning your french verbs might be fine (in isolation), gentle jogging may well be fine (in isolation) but there is no denying that trying to do the two in consecutive lessons may well be far more challenging, yet that may well be what we are expecting some of our youth athletes to do. We already know that a concussion can impact players non related injury risk for a year following a single concussion, could it is be impacting on the skill level of players we produce?

Howell et al (2014) (here) explain that traditional concussion severity scales are being abandoned in favour of individualized concussion management with multifaceted evaluation of function. For example, the SCAT3 assesses static balance as part of motor control, however Howell’s study found that up to 2 months post concussion, adolescent athletes display increased centre of mass displacement medial-lateral compared to a matched control group. Could it be that we are clearing people for activity based on a static assessment when in fact dynamic balance may take longer to recover? (a potential study for anyone interested).

Whats up doc?

This doesn’t even make sense

Concussion management is further complicated by contradictory advice, youth concussion is not only a sporting issue, but a public health one. If GP’s or A&E do not feel able to confidently manage concussions, how can we expect them to make decisions regarding return to play? I’ve attended numerous times to A&E with players who have been told once you feel better, get back to training. With Scotlands new concussion guides they are starting to address the associated public health concerns around child concussion. It can no longer be deemed as just a sport issue or just a medical issue as the potential long term consequences go beyond these two areas.  With the Scottish guidelines being aimed across sports at a grass roots level it begins to address the disparity between the quality of concussion management across sports and levels. Whether you’re an elite athlete, a weekend warrior or a 15 year old school child you still only have one brain!

 

Prevention

Prevention is better than cure right? Non contact rugby until the age 20? I don’t think so. Considering the reaction to suggesting removing the header from football in youth sport due to concerns around sub concussive events, the suggestion we remove contact from rugby is a no go. However there are lots of benefits to playing a contact sport, from social development, self confidence and the physical benefits from contact so maybe managing the amount of contact sustained in training is one way of combating the risks of concussion and sub concussive events.

How about a helmet, monitors or head guards? Considering the issues within the NFL and concussion with players recently retiring due to concerns around concussion, it would suggest that protective headgear does little for prevention of concussion (think back to blog 1 about mechanisms within the skull). It’s widely accepted that protective headgear has a role to play in prevention of catastrophic head injuries (ie your cycle helmet) however scum caps may well give players a false sense of security which in turn increases the risk of a concussion. RFU guidelines indicate that a scrum cap must be able to compress to a certain thickness and must be made of soft, thin materials – their main purpose is to protect against lacerations and cauliflower ear, they have little to no impact on concussions.

Following a severe head injury (skull fractures), Peter Cech has become synonomous with this head gear. It provides him with the confidence to play – but what does it do?

Every concussion needs attention. Every team has a coach or a parent watching. But not every child has access to a health care professional pitch side.

Cournoyer & Tripp (2014) (here) interviewed 334 American football players 11 high schools and found that 25% of players had no formal education on concussion. 54% were educated by their parents (but who is educating the parents?!). The following percentages represent who knew about symptoms associated with concussion:

Symptoms	Consequences
Headache (97%)	Persistent headache (93%)
Dizzyness (93%)	Catastrophic (haemorrhage, coma, death) (60%)
Confusion (90%)	Early onset dementia (64%)
Loss of Consciousness (80%) – how this is lower than headache is worrying.	Early onset Alzheimers (47%)
Nausea / Vomitting (53%)	Early onset parkinsons (27%)
Personality change (40%)
Trouble falling asleep (36%)
Becoming more emotional (30%)
Increased anxiety (27%)

Table 1: Frequency of concussion symptoms and consequences identified by American Football playing high school students (Cournoyer & Tripp 2014)

Education is key! Players, parents, coaches, friends, family. Everyone! The IRB has some great online learning for general public, coaches and medical professionals (here). Only by symptoms being reported, assessed and managed can we make an impact on concussion.

 

Kate is a band 6 MSK physiotherapist, having graduated in 2011 from Cardiff Univeristy. Beyond her NHS work, Kate has worked for semi-pro Rugby League teams in Wales, the Wales Rugby League age grade teams and is now in her 3rd season as lead physio for the Newport Gwent Dragons u16 squad.

Concussion Assessment – a guest blog by Kate Moores

Following our last blog on concussion, I started talking to Kate Moores via twitter (@KLM390) who had some very intersting experiences and ways of managing concussion. So, I am very pleased to introduce Kate as a guest blogger on the topic of Concussion assessment & management – we have decided to split Kates blog into 2 more manageable parts rather than one super-blog (My contribution may have been to add the occassional picture to the blog).

The previous blog discussed generalized pitchside assessment of a concussion, irrelevant of age. However Kate has drawn on her knowledge and experience with young rugby players to highlight in particular, the ongoing assessment of young athletes as well as adults and how it differs. Kate raises some very good points throughout but the point that really made me reflect was the consideration over “return to learn.” Looking back at concussions I’ve managed in academy football, I didn’t properly respect the impact that a day at school may have had on symptom severity or neurocognitive recovery. I was mostly interested in “have you been resting from activity?” I think this blog is an excellent resource for medical professionals, but also for teachers, coaches and parents to consider the impact of this hidden injury.

Part 1 (of Blog 2)

Conor McGoldricks first day at school

Children are not just little adults… a phrase commonly heard within healthcare. It’s particularly true when it comes to concussion. Children’s brains are structurally immature due to their rapid development of synapses and decreased levels of myelination, which can leave them more susceptible to the long term consequences of concussion in relation to their education and sporting activities. With adults the focus is usually on return to play, with similar protocols being used in managing youth concussions, albeit in a more protracted time frame.

However a child is physically, cognitively and emotionally different to adults, therefore is it appropriate for these return to play protocols to be used with youth athletes? Youth athletes are still children – still students as well as athletes. It is during these years that children develop & learn knowledge & skills (academic and social), in a similar way these youth athletes need to be learning the tactical knowledge and motor skills they will need for their sport. Shouldn’t “return to learning” be as much the focus in youth athletes as a “return to play” protocol?

“Youth Athletes are still children balancing studies with sports”

Assessment

So, the pitchside decision on management has been made (blog 1) and now the assessment continues in the treatment room

The use of the SCAT3 (here) and Child SCAT3 (age 5-12) (here) have been validated as a baseline test, a sideline assessment and to guide return to play decisions. O’Neil et al 2015 compared the then SCAT2 test against neuropsychological testing. They found that SCAT2 standardised assessment of concussion scores were correlated to poorer neuropsychological testing for memory, attention and impulsivity. However symptom severity scores had poor correlation with those same components. Therefore simply being symptom free may not be a good enough indicator that youth athletes are ready to return to learning or sport.

There has been recent research into the King Devick (K-D) test as another option for the assessment on concussion in children with research being done comparing SCAT scores with K-D testing (Tjarks et al 2013)

One of the benefits of using the KD test is that it has stronger links with the neurocognitive processing which may mean that it has a greater role to play with regard to return to learning as well as return to play. Another benefit is that unlike the SCAT3 tests the KD test does not require a health care professional to administer the test.

We educate people about how robust their body is, but should we be more cautious with brain injuries?

At a club with full time staff and consistent exposure to players, the SCAT3 can be useful to compare to pre-injury tests conducted as part of an injury screening protocol. It also helps if you know that person, for some the memory tests are challenging without a concussion so post injury assessment with the SCAT3 may score badly, but is that the person or the injury? It is also important that this assessment is done in their native language. These reasons throw up some complexities if you are working part time for a club, or covering ad hoc fixtures as part of physio-pool system. Its advisable in this instance to get a chaperone in with the athlete to help your assessment – this may be a partner for an adult player or a parent / teacher for a child. A quick conversation with them to say “please just look out for anything odd in what they say or how they say it.”

Beyond the assessment tool, there is evidence now to suggest we should be asking about pre-injury sleep patterns. Sufrinko et al (2015) (here) look prospectively at 348 athletes in middle school, high school and colligate athletes across three different states in America (aged 14-23). At the start of the season the researchers grouped the athletes as those with “sleep difficulties” (trouble falling asleep, sleeping less than normal” and a control group of “no sleeping difficulties”. Following a concussion, assessment was conducted at day 2, day 5-7 and day 10-14 using the Post Concussion Symptom Scale (PCSS) and found that those with pre-injury sleep difficulties had significantly increased symptom severity and decreased neurocognitive function for longer than the control group.

Looking in the other direction, Kostyun et al (2014) (here) assessed the quality of sleep after a concussion and its subsequent impact on recovery. Looking at 545 adolescent athletes, the results indicated that sleeping less than 7 hours post-concussion significantly correlated with increased PCSS scores, where as sleeping over 9 hours post injury significantly correlated with worse visual memory, visual motor speed and reaction times. A word of caution with this study, the authors assumed that “normal” sleep was between 7-9 hours – but anyone who has adolescent children, or hasn’t blocked the memory of being an adolescent themselves, knows that sleep duration does increase when you are growing. Saying that, the impact of both of these studies suggests that we should be:

1) Asking about normal sleep patterns prior to injury to help us gauge recovery times (disrupted sleepers may take longer than we originally predict) and;

2) We need to keep monitoring sleep quality along with regular re-assessment as sleeping more than normal may indicate ongoing recovery from concussion.

 

In Part two (here), Kate continues to discuss ongoing assessment and the recovery process.

Kate is a band 6 MSK physiotherapist, having graduated in 2011 from Cardiff Univeristy. Beyond her NHS work, Kate has worked for semi-pro Rugby League teams in Wales, the Wales Rugby League age grade teams and is now in her 3rd season as lead physio for the Newport Gwent Dragons u16 squad.

 

 

 

 

 

 

Rehabbing teenagers can be awkward! – sensorimotor function during adolescence

There is a bit of a buzz phrase in rehab about “individualising programs” and while it is something we wholeheartedly agree with, it is a phrase that is very easy to say and yet very difficult to implement. Especially when you work with a population where said individual changes rapidly through time, like a teenager! It is a common sight on a training pitch to see a star player in their age group suddenly tripping over cones or developing a heavy touch where there was previously effortless control. Side effects of the adolescent growth spurt, where the brain is now controlling a much longer lever. It’s like giving a champion gardener a new set of garden sheers when for the past year they have used little hand-held scissors and asking to them maintain their award-winning standards. (My garden embarrassingly needs some attention and it’s affecting my analogies).

The control and precision between these two instruments is influenced by the lever length of the handles…

…Similar to a rapidly growing femur and tibia which is still being operated by muscles that have length and strength suitable for shorter levers.

 

 

 

 

 

 

 

 

Alongside the performance related issues, there is suggestion that this period of growth may coincide with increased risk of injury (Caine et al 2008). We believe that bone grows quicker than soft tissue, so we are asking a neuromuscular system to control a new, longer lever using prior proprioceptive wiring. Imagine our gardener again, for a long time he has been able to keep his pair of scissors close and controlled, now with his extra long shears the load is further away from his body, his back and shoulders are starting to ache. Not sure what I mean? With one hand hold a pencil to the tip of your nose. Now, with one hand hold a broom handle to your nose. The longer lever is harder to control. **I promise it gets a bit more sciencey than gardening and broom handles. **

Managing these growth spurts is something we have talked about before and recently contributed to a BJSM podcast on the topic (Part 1 & Part 2) and a complimentary BJSM blog about “biobanding” during periods of growth and development (here). This particular blog was inspired by a recent (2015) systematic review looking into exactly which sensorimotor mechanisms are mature or immature at the time of adolescence by Catherine Quatman-Yates and colleagues over in Cincinnati (here). The following is a combination of their summary and our examples of how these findings can influence our rehab programs.

Tailoring the program:

We have so many options for exercise programs, that’s what makes the task of designing them so fun. It challenges our creativity. When working with a teenager with sensorimotor function deficits, let’s call them “Motor Morons” for short, we don’t have to totally re-think our exercise list, just perhaps the way we deliver them. We previously spoke about motor control and motor learning (here) and how our instructions can progress just as our exercises do, but the following relates to children and adolescents in particular.

Consider the stimuli.

Children aged between 14-16 have well-developed visual perception of static objects however their perception of moving objects and visual cues for postural control continue to mature through adolescence. When very young children learn new skills such as standing and walking, they become heavily reliant on visual cues. Quatman-Yates et al suggest that puberty and growth spurts (think gardener with new shears) brings new postural challenges that causes adolescents to regress proprioceptive feedback and increase reliance on visual cues again. From a rehab perspective, we need to consider this as part of our balance and proprioception program. How many of us default to a single leg stand and throwing a tennis ball back & forth from therapist to athlete? For our Motor Moron, this may not be an optimal form of treatment in early stages, where it is commonly used, however it may incredibly beneficial to that athlete in the later stages or as part of ongoing rehab as we try to develop that dynamic perception.

Consider the amount of stimuli involved in an exercise versus what your goal of that exercise is

We should also consider the amount of stimuli we add to an exercise. Postural stability in children is believed to be affected by multiple sensory cues. If we consider that children are more dependent on visual cues than adults are, perhaps our delivery of external stimuli should be tailored also. With a multi directional running drill for example, there is sometimes an element where the athlete is given a decision making task (a red cone in one direction and a yellow cone in another) and they have to react quickly to instructions from the therapist or coach. Rather than shouting instructions like “red cone”, “yellow cone” etc, hold up the coloured cone for the corresponding drill. This way we are utilising this developed visual perception, minimising the number of stimuli and also encouraging the athlete to get their head up and look around rather than looking at their feet.

When to include unilateral exercises:

Within adult populations, it is often considered gold standard to make exercises unilateral as soon as tolerable. If they can deep squat pain free and fully weight bear through the affected side, progress them to pistol squats ASAP, or single leg knee drives. However, young children (pre-pubescent) may struggle with this for a couple of reasons.

Difficult enough even for an adult to perform, but uncoupling the actions of the each leg & fine muscle movements to maintain balance are extra challenging for children

Firstly, we need to consider postural adjustments. Where as adults and young adults can adjust their balance with smooth control and multiple, small oscillations, children rely on larger ballistic adjustments. There is also reduced anterior-posterior control in younger athletes which suggests reduced intrinsic ankle control. Put this alongside immature structures and (if working a physio, most probably) an injury then single leg exercise become a progression that may be further down the line than an adult counterpart with the same injury. Instead, consider semi-stable exercises. Support the contralateral leg with a football or a bosu ball – something that is difficult to fixate through but provides enough stability to support the standing leg.

Secondly, we understand that coupled movements are mastered earlier in adolescence, around 12-15 years old but uncoupled movement patterns take longer to develop, 15-18 years old (Largo et al). A good example is watching a young child reach for a full cup of water at the dinner table. It is much easier and more natural for them to reach with both hands than it is with one, as coupled movements are unintended. Rarely do you see a child taking a drink with one hand filling their fork with the other – yet this is something commonly seen with adults as they are able to uncouple and segmentalise. Another example is watching a child dynamically turn, watch how the head, trunk and limbs all turn as a “block”, it is not until further down the line where dynamic movements become more fluid. The argument here is that surely running is an uncoupled movement? Or kicking a football, swinging a tennis racket, pirouetting in ballet – they are all uncoupled, segmental movement patterns that we expect kids to do, and in all they cope with. Correct, but it is usually in rehab programs for kids that we begin to introduce unfamiliar tasks and exercises that they may not have encountered before. Also, we should respect the impact of the injury on proprioception and control. So these are all considerations for starting points in exercise & if a regression is ever required.

For this reason, it is important that exercises are monitored and reviewed regularly. There is no need to hold an athlete back because of their age and making assumptions on motor function because of their age. If they can cope, then progress them. But be mindful of “over-control” where speed and variability of movement are sacrificed in place of accuracy and control (Quatman-Yates et al 2015).

Become a Motor Moron hunter

It is worth spending some time watching training, watching warm ups, watching gym sessions and talking with coaches and S&C’s trying to identify a Motor Moron as soon as possible. It’s important to minimise the chances of an immature sensorimotor mechanism ever meeting a growth spurt. It is when these two things combine that we see kids doing immaculate Mr Bean impressions and therefore increase their risk of injury.

Regularly re-assess your exercise programs. If things arent quite progressing as quickly as they should, it may not be failed healing of an injury, but it may be that we are providing the sensorimotor mechanism with too much information!

 

Yours in sport,

Sam

 

“The Young Athlete” conference 9-10th Oct, Brighton. Here

The Osgood, the bad and the ugly

One of my best sources for recent literature is via a good friend of mine, Mr Jonny King (@Jonny_King_PT). Before he shot off to Doha to have his moment in the sun, he left a multitude of articles on my desk for me to read, one of which was a study looking at that persistent pest in my clinic, Osgoods Schlatters Disease (OSD).

OSD falls under the apophysitis or enthesopathy umbrella along with severs disease and Sinding Larsen Johansen disease amongst others. In our injury audit for the last season, these injuries alone accounted for 20% of our total injuries (u9-18s).

However, with a little bit of education to players, parents and coaches we feel confident that we can manage these numbers even better.

We are very lucky to be part of an in depth, ongoing study with the brilliant and very knowledgable Jenny Strickland at the University of Greenwich. With her guidance and protocol, we are bringing the days spent on the treatment table down considerably, but ideally we want to learn about these conditions to help prevent them in the first place.

What do we think we know?

OSD is a growth related condition, we think it can be attributed to high levels of activity during periods of growth. Unlike an adult presentation of a tendinosis, the condition affects the soft cartilaginous junction between the patella tendon and the immature anterior tibial tuberosity (ATT). (See my previous blog for the BJSM about differences between adult and Paeds injury management here).

Figure 1
Demonstrating the close relationship between the enthesis, the patella tendon, the infra patella fat pad and the physis of the tibia.

Historically OSD has been labelled as “growing pains” (a genuine medical entity, but no clinical similarities to OSD) and sufferers of the condition may well have been told to “just get on with it” or that “you’ll grow out of it”. Unfortunately this attitude still exists amongst some parents and, regrettably, GP’s – we see first hand evidence of this in our academy. When I first started in my role, I was guilty of just sitting a lad on the plinth with some ice, telling him to rest for a few weeks and we’ll see how we go.

OSD can almost certainly be attributed to growth spurts, where high levels of cellular activity in the growth zones of bone can’t be matched by the attaching muscles, resulting in traction on the inherently weak enthesis. Usual subjective presentation is that of an ache during, or more prominently, after activity. Gradually pain has been worsening over a period of days or weeks. Eases with rest. However, occasionally we see examples of players that have been kicked or landed on their knees in acute incidents but will display all the characteristics of OSD. But this doesn’t fit with our understanding of growth and traction…

Sailly et al (2013) looked at symptomatic adolescent male athletes competing in elite sport and using Doppler ultrasound they compared the ATT complex to gauge different stages of maturation. Within these stages of maturation, they could attribute pain scores from symptomatic athletes to determine the more vulnerable stages of growth (figure 2 below). The best descriptions for these stages that I have heard are from Sid Ahamed on his Adolescent Injuries course. He describes the enthesis as a continuum that develops with maturation from a stable state to an increasingly unstable state as the cartilage calcified with age.

Figure 2
Classification system of the maturation status of the ATT from stages 1 to 4. ATT, anterior tibial tuberosity; B, bursa; FP, fat pad; HC, hyaline cartilage; M, metaphysic; O, ossicle; P, physis; PT, patellar.

In Sailly’s study they found that no players reported pain during the “stable” first phase but increasing scores of VAS in stage 2. As the enthesis calcified and unites in stage 3 and 4, the numbers decrease again.
So what is happening in this 2nd stage of maturation? The use of Doppler ultrasound opens some new theories. In these symptomatic stage 2 patients, there was Doppler activity within the pre-patella and deep infra patella bursa, indicating the presence of neo-vessels within these structures. Recently, Seth O’Neil (physio matters podcast) explained that most of these pain inducing neovascular structures are actually present in peritendon & surrounding tissues like the bursa, fat pads and fascia. Maybe the same is true with the adolescent population.
The synovium that surrounds the enthesis is highly prone to compressive forces and as such, prone to inflammation. In the developing ATT, the patellar ligament attaches to the tibial tubercle but also to the physis of the tibial growth plate and to the periosteum of the metaphysis of the tibia (see figure 1 at top) . Sailley et al propose that this anatomical area is not only prone to traction that we normally associate with OSD, but also compression. Perhaps this explains the sudden onset OSD in the clinic alongside those rumbling insidious case loads.

Management:

As I mentioned, we now follow the Strickland protocol at our club in terms of treatment, but I still believe the key is in prevention rather cure. We regularly discuss loading with our coaches at every age group. If you consider that most of our players at school boy level will also play and train for their school, probably be selected for other sports such as cricket and rugby and will generally tear around everywhere at 100mph. Basically their day consists of sprinting, jumping, bounding and kicking. Consider the load on those immature structures (both compressive and tensile). As part of a warm up, does that player then need to do a series of hurdle drills or jumps? Could they not spend their conditioning sessions doing low impact movement patterns, balance & proprioception, or co-ordination drills for their newly elongated and uncontrollable limbs? Perhaps every now and then having a training session where the lads don’t have to strike a ball? Like basketball maybe, where you teach spacial awareness and evading the opponent? Or placing a technical bias on the session and reducing the pace?
If we can help coaches, players and parents understand that modifying activities and occasionally, resting, is the best thing in the long run for all parties, I think we will continue to see a drop in training / matches missed due to OSD.

Yours in sport
Sam