I can’t believe we’re already up to 5 parts on this topic! In case you missed it.

Part 1 Part 2 Part 3 Part 4

Do you guys remember upper crossed syndrome from Part 3? For a refresher look to the left. I like to think of upper crossed syndrome as an example of the most common postural problems. In reality everyone is going to have their own postural variations. Upper crossed syndrome paints a nice picture for understanding what poor posture looks like. It also gives us an understanding of what muscles could be lending to these problems flash player 8 downloaden.

So what’s going on with poor posture seen in Upper-Crossed Syndrome? (1)

Forward Head Posture

Increased Upper Cervical Lordosis (upper neck overarching)

Rounded Shoulders

Increased Thoracic Kyphosis (More upper back rounding)

What gets tight and shortened? (1)

Suboccipitals, Upper Trapezius, Levator Scapulae

Pectoralis Major and Minor

What gets weak and lengthened? (1)

Deep Cervical Flexors

Rhomboids and Lower Trapezius

So why do we worry about achieving better posture? Once again it all comes back to the subacromial space, or the room between our humeral head and acromion that when decreased can lead to impingement or “pinching” in the shoulder revit families.

Albeit by a small amount, slouched posture has been shown to significantly decrease subacromial space during elevation of the arms overhead in individuals with rotator cuff disease (2).

As described above, poor posture can be attributed to tight musculature on the front of our chest. If the pectoralis minor becomes tight and shortened it can end up causing scapular winging and scapular anterior tilting. If we recall from part 3, this combination is associated with decreased subacromial space and impingement (3,9).

Decreased subacromial space = more risk for impingement. Seems to be the trend here.

Food for thought: I’m making a huge case for posture and shoulder problems but research shows us that static posture might not be as important as we once thought for impingement patients (4) smart notebook gratisen. What seems to be important is decreased dynamic mobility (4). This essentially means that people with impingement and normal pain free individuals have similar static postures at rest. The difference is in their mobility once you ask them to start moving their arms overhead.

My issue with having poor static posture is that over time it will definitely lead to decreased active mobility over time. We need to nip this in the bud.

So what causes poor posture?

Our daily habits: The postures we assume while working, reading, sitting, standing etc. all form the basis for our posture. On top of that, the exercises we choose to perform in the gym can influence our posture as well. Our emotions: I’m far from an expert on this subject but was able to drum up some research that correlates emotion and posture radio kostenlos herunterladen. The research seems to show that our emotions at the moment are related to our posture (5). This is far from cause and effect but it’s certainly an interesting bit of information. That being said, the way we hold our posture on a daily basis has to do with our emotional state and is probably an issue in fixing poor posture. Breathing – This one needs a bit of extra explanation…



In order to get oxygen into our body we need to fill the lungs with air throughout the day. We end up taking somewhere between 15,000 to 20,000 breaths every day. Normally, the fatigue resistant diaphragm is the predominant muscle of choice in order to get the job done. When we engage in strenuous exercise we start to call in secondary breathing muscles to expand our rib cage and pull extra air in to help feed more oxygen to hungry muscles musik auf iphone herunterladen app.

While traditional quiet breathing (breathing at rest) is supposed to use the diaphragm predominantly to accomplish respiration, research shows us that healthy individuals also get a good deal of thoracic movement in quiet breathing (6). Using a pattern of breathing that causes more movement from the ribcage is a sign that the accessory breathing muscles are overworking when they’re supposed to be quiet.

Accessory breathing muscles are not as fatigue resistant as the diaphragm and they’re likely to become hypertrophied and shortened with excessive use.

A list of the accessory breathing muscles – specifically muscles of inhalation (7):

External Intercostals

Upper trapezius

Sternocleidomastoid

Scalenes

Serratus Anterior

Pec Major

Pec Minor

Abdominals

Latissimus Dorsi

If the bolded muscles become shortened they’re going to contribute directly to the postural faults seen in upper crossed syndrome herunterladen.

The pec minor can cause scapular winging. When the pecs and lats get shortened they’ll produce internal rotation of the shoulder.

Image Source, License, Attribution: LLCAnatomography / CC BY-SA 2.1 JP – Edited by Fitness Pain Free

Remember that in part 1, internal rotation of the shoulder is usually a provocative position for pain in individuals with impingement. This is due to the greater tuberosity of the humerus banging up against the acromion when we raise our arms overhead (8). If we’ve got increased gleno-humeral (shoulder joint) internal rotation during overhead movements we run the risk of impinging structures in the subacromial space. (Another case for improving your technique when lifting) This is yet another area that must be addressed in order to achieve normal motion at the shoulder.

So these are the basics of shoulder impingement! I hope you guys enjoyed the article series thus far. In the future I plan on putting together strategies for rehabbing subacromial impingement film aus mediathek downloaden.

Find Part 6: Do You Have Shoulder Impingement? HERE

Sitting here writing is terrible for my posture,

Dan Pope

P.S. If you enjoyed this article then sign up for the newsletter to receive the FREE guide – 10 Idiot Proof Principles to Crossfit Performance and Injury Prevention as well as to keep up to date with new information as it comes out via weekly emails.

Resources:

1. Page, P., Frank, C. C., & Lardner, R. (2010). Assessment and treatment of muscle imbalances the janda approach. (pp. 195-207). Champaigne, IL: Human Kinetics.

2. Kalra, N., Seitz, A., Douglas Boardman, N., & Michener, L. (2010). Effect of posture on acromiohumeral distance with arm elevation in subjects with and without rotator cuff disease using ultrasonography zeichenprogramme zum downloaden kostenlos.Journal of Orthopaedic and Sports Physical Therapy, 40(10), Retrieved from http://www.jospt.org/issues/articleID.2473,type.2/article_detail.asp

3. Ludewig, P., & Reynolds , J. (2009). The association of scapular kinematics and glenohumeral joint pathologies. Journal of Orthopaedic and Sports Physical Therapy, 39(2), 90-104. Retrieved from http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2730194/pdf/nihms-114923.pdf

4. McClure, P., Michener, L., & Karduna, A. (2006). Shoulder function and 3-dimensional scapular kinematics in people with and without shoulder impingement syndrome. Physical Therapy, 86(8), 1075-1090 herunterladen. Retrieved from http://ptjournal.apta.org/content/86/8/1075.full

5. Dael, N., Mortillaro, M., & Scherer, K. (2012). Emotion expression in body action and posture. Emotion,12(5), 1085-1101. Retrieved from http://www.ncbi.nlm.nih.gov/pubmed/22059517

6. Kaneko, H. (2012). Breathing movements of the chest and abdominal wall in healthy subjects. Respiratory Care, 57(9), 1442-1451. Retrieved from http://rc.rcjournal.com/content/57/9/1442.abstract

7. Clarkson, H: Musculoskeletal Assessment – Joint ROM and Manual Muscle Strength. 2nd ed. Philadelphia: Lippincott Williams & Wilkins, 2000.

8. Brown DP, Freeman ED, Cuccurullo S, et al. Shoulder Disorders. In: Cuccurullo S, editor herunterladen. Physical Medicine and Rehabilitation Board Review. New York: Demos Medical Publishing; 2004. Available from: http://www.ncbi.nlm.nih.gov/books/NBK27311/

9. Escamilla, R., Yamashiro, K., Paulos, L., & Andrews, J. (2009). Shoulder muscle activity and function in common shoulder rehabilitation exercises. Sports Medicine, 39(8), 663-685. Retrieved from http://www.ncbi.nlm.nih.gov/pubmed/19769415