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From Fellrnr.com, Running tips
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The design and selection of running shoes does not match the available science. The commonly held beliefs follow this logic: Runners get injured due to impact and excessive [[Pronation]], running shoes reduce impact and pronation, and therefore running shoes reduce injury. Unfortunately, every part of this rationale seems to be flawed. There are other aspects of shoe design, such as the raise heel or arch support that have even less evidence to support them.
* '''Injuries due to impact. '''There is surprisingly little evidence that impact forces cause injuries, and there is even some evidence that lower impact forces are associated with higher injury rates. It's been suggested that excessive impact can result in injury, while more moderate impact can produce important adaptations that are necessary for improved performance.
* '''Injuries due to over pronation. '''The science around [[Pronation]] and injury rates is quite mixed. Part of the problem is science does not generally look at pronation directly, but uses arch height with the assumption that low arches pronate more. There is some evidence that high or low arches have slightly higher injury rates, or that different arch heights have different patterns of injury.
* '''Running shoes reduce injury'''. There is no evidence that running shoes reduce injury rates. Assigning shoes based on arch height does not change injury rate, nor is there any indication that more cushioned shoes have a lower injury rates. There is some evidence that motion control shoes cause greater leg pain and more training days lost, and this applies to all arch types.
* '''Raised heel. '''Another common feature of running shoes is a raised heel, which is intended to reduce the strain on the Achilles tendon. However there is little evidence that the raised heel actually reduces the strain on the Achilles tendon, and no evidence that the raised heel actually reduces Achilles tendon injuries.
* '''Arch support.''' Often running shoes have a raised area under the arch that is intended to provide support. I found no evidence to support this idea.
* '''Barefoot running.''' The reduced impact seen with barefoot running led many people (myself included) to believe that this would in turn result in lower injury rates. However, there is no evidence that barefoot runners have a lower injury rates. More importantly, there is a growing body of evidence to suggest that the transition to barefoot running is associated with a high injury risk.
=The Myth of Running Shoe Types=
* A study of 10 experienced rear foot runners were tested with shoes of varying heel flare<ref name="Clarke-1983"/>. This heel flare is how much wider the heel is at the bottom than the top, and the flared heels reduced pronation from 12.6 to 11.1 degrees (1.5 degree decrease) when compared with any heel without any flare. In practice, it's rare for a shoe to be this narrow at its base, and other studies have not shown this effect<ref name="Nigg-1987"/><ref name="Stacoff-2001"/>. [[File:Clarke-1983-Heel-Flare.jpg|none|thumb|200px]]
* The heel counter is intended to link the heel of the foot to the shoe, but a study found that a rigid heel counter did not prevent slippage within the shoe any better than a flexible heel counter<ref name="Gheluwe-1995"/>. Also, the pronation of the foot can be twice as large as the pronation when measured on the shoe<ref name="Stacoff-2001"/>.
* A study of 7 people compared pronation when stepping down from a platform in shoes and when barefoot<ref name="FukanoFukubayashi2014"/>. The shoe was the Adidas Response Cushion and the platform was 4 inches/10 cm high. Pronation with shoes was less (17.9 degrees) than when barefoot (20.5 degrees). However, because the reduction was so small, the study concluded that it was impractical to alter pronation with this type of footwear. =Running Shoes and & Achilles Strain =
A common feature in running shoes is for the heel to be thicker than the forefoot, something that is commonly called "drop". In the 1980's a drop of 12-15mm was recommended to prevent Achilles tendon and calf injuries<ref name="Clement-1980"/>, but there is little evidence to support this:
* No studies have shown raised heels reduce Achilles (or other) injuries<ref name="van Gent-2007"/>.
* A study looked at 30 runners that were either assigned a minimal drop shoe (4mm) or were trained to adopt a midfoot strike (MFS) pattern<ref name="Giandolini-2013"/>. The minimal drop shoe reduced heel impact, but the MFS training had no effect.
* A study looked at 12 Rear Foot Strike runners using 16 combinations of midsole thickness and drop<ref name="HorvaisSamozino2013"/>. The lower drop shoes had a more midfoot strike pattern, but the thickness had no impact. (Ground contact time was greater with lower drop shoes.)
* A study of 12 male runners looked at foot strike for shoes with 0mm, 4mm, and 8mm of drop, plus barefoot<ref name="ChambonDelattre2013"/>. The barefoot condition was midfoot strike rather than rear foot strike in the shoes. The different drop conditions were not significantly different, though there was a trend towards more rear foot strike with the 8mm drop than with 0mm and 4mm drops.
* A drop of 15mm or 7.5mm did not produce a significant reduction in Achilles tendon stress<ref name="Dixon-1998"/>.
=Injury Rates & Shoes=
** The neutral runners had higher levels of pain in the neutral shoe than the stability shoe. The pronating runners had higher levels of pain in the stability shoe than the neutral shoe. This is the opposite of most recommendations for shoe and foot type.
** Note that while the overall sample size was reasonable (81), each individual subgroup was quite small (5 to 18 runners) and variation within subgroup of results was large. The subgroups also varied significantly in weight, BMI, age, and years of running experience.
=Shoes and Running Economy=
''Main article: [[The Science of Running Economy]]''
Studies have consistently shown that heavier shoes reduce running economy<ref name="LussianaFabre2013"/><ref name="Burkett-1985"/><ref name="Sobhani-2014"/><ref name="Wierzbinski-2011"/>. Each 100g/3.5oz added to the weight of each shoe reduces running economy by about 1%<ref name="Franz-2012"/><ref name="Wierzbinski-2011"/><ref name="Frederick 1985"/><ref name="Frederick-1984"/>.
Studies of cushioning and Running Economy have provided conflicting information. I believe this conflict is due to some studies using a cushioned treadmill to compare barefoot and shod conditions. Not surprisingly, if a study uses a cushioned treadmill, the cushioning provided by the shoe does not confer any additional advantage over the barefoot condition. Analyzing the research, I conclude that a well cushioned running shoe can improve Running Economy by an estimated 2-3.5% compared with a weight matched un-cushioned shoe<ref name="Franz-2012"/><ref name="Wierzbinski-2011"/><ref name="Tung-2014"/>.
=Minimalist & Barefoot Running=
Most research looks at factors that might be related to injury risk, rather than injury rates directly. I found no studies that evaluated barefoot or minimalist running and injury rates. So while barefoot and minimalist running tends to have lower impact, it's unclear if this will have any bearing on injury rates. Of greater concern is some compelling evidence that the transition to barefoot or minimalist footwear is correlated with higher injury rates, especially stress fractures in the foot.
<ref name="Stacoff-2001">A. Stacoff, C. Reinschmidt, BM. Nigg, AJ. Van Den Bogert, A. Lundberg, J. Denoth, E. Stüssi, Effects of shoe sole construction on skeletal motion during running., Med Sci Sports Exerc, volume 33, issue 2, pages 311-9, Feb 2001, PMID [http://www.ncbi.nlm.nih.gov/pubmed/11224823 11224823]</ref>
<ref name="Gheluwe-1995">Van Gheluwe, Bart, Rudi Tielemans, and Philip Roosen. "The influence of heel counter rigidity on rearfoot motion during running." Sort 100 (1995): 250.</ref>
<ref name="FukanoFukubayashi2014">Mako Fukano, Toru Fukubayashi, Changes in talocrural and subtalar joint kinematics of barefoot versus shod forefoot landing, Journal of Foot and Ankle Research, volume 7, issue 1, 2014, pages 42, ISSN [http://www.worldcat.org/issn/1757-1146 1757-1146], doi [http://dx.doi.org/10.1186/s13047-014-0042-9 10.1186/s13047-014-0042-9]</ref>
<ref name="ChambonDelattre2013">N. Chambon, N. Delattre, E. Berton, N. Guéguen, G. Rao, The effect of shoe drop on running pattern, Computer Methods in Biomechanics and Biomedical Engineering, volume 16, issue sup1, 2013, pages 97–98, ISSN [http://www.worldcat.org/issn/1025-5842 1025-5842], doi [http://dx.doi.org/10.1080/10255842.2013.815919 10.1080/10255842.2013.815919]</ref>
<ref name="Tung-2014">KD. Tung, JR. Franz, R. Kram, A test of the metabolic cost of cushioning hypothesis during unshod and shod running., Med Sci Sports Exerc, volume 46, issue 2, pages 324-9, Feb 2014, doi [http://dx.doi.org/10.1249/MSS.0b013e3182a63b81 10.1249/MSS.0b013e3182a63b81], PMID [http://www.ncbi.nlm.nih.gov/pubmed/24441213 24441213]</ref>
<ref name="LussianaFabre2013">T. Lussiana, N. Fabre, K. Hébert-Losier, L. Mourot, Effect of slope and footwear on running economy and kinematics, Scandinavian Journal of Medicine & Science in Sports, volume 23, issue 4, 2013, pages e246–e253, ISSN [http://www.worldcat.org/issn/09057188 09057188], doi [http://dx.doi.org/10.1111/sms.12057 10.1111/sms.12057]</ref>
<ref name="Burkett-1985">LN. Burkett, WM. Kohrt, R. Buchbinder, Effects of shoes and foot orthotics on VO2 and selected frontal plane knee kinematics., Med Sci Sports Exerc, volume 17, issue 1, pages 158-63, Feb 1985, PMID [http://www.ncbi.nlm.nih.gov/pubmed/3982270 3982270]</ref>
<ref name="Sobhani-2014">S. Sobhani, S. Bredeweg, R. Dekker, B. Kluitenberg, E. van den Heuvel, J. Hijmans, K. Postema, Rocker shoe, minimalist shoe, and standard running shoe: a comparison of running economy., J Sci Med Sport, volume 17, issue 3, pages 312-6, May 2014, doi [http://dx.doi.org/10.1016/j.jsams.2013.04.015 10.1016/j.jsams.2013.04.015], PMID [http://www.ncbi.nlm.nih.gov/pubmed/23711621 23711621]</ref>
<ref name="Wierzbinski-2011">The separate effects of shoe mass and cushioning on the energetic cost of barefoot vs. shod running. Wierzbinski, Corbyn. University of Colorado at Boulder. Departmental Honors Thesis. http://digitool.library.colostate.edu///exlibris/dtl/d3_1/apache_media/L2V4bGlicmlzL2R0bC9kM18xL2FwYWNoZV9tZWRpYS8xMTkyODM=.pdf</ref>
<ref name="Franz-2012">JR. Franz, CM. Wierzbinski, R. Kram, Metabolic cost of running barefoot versus shod: is lighter better?, Med Sci Sports Exerc, volume 44, issue 8, pages 1519-25, Aug 2012, doi [http://dx.doi.org/10.1249/MSS.0b013e3182514a88 10.1249/MSS.0b013e3182514a88], PMID [http://www.ncbi.nlm.nih.gov/pubmed/22367745 22367745]</ref>
<ref name="Frederick-1984">Frederick, E. C., Physiological and ergonomics factors in running shoe design. Applied Ergonomics 15(4): 281-287, 1984</ref>
<ref name="Frederick 1985">Frederick , E. C. The energy cost of load carriage on the feet during running. In: Winter, D.A., R. W. Norman, R. P. Wells, K. C. Hayes, and A. E. Patla (Editors), Biomechanics IX-B Human Kinetics Publ., Champaign, IL, pp.295-300, 1985</ref>
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[[Category:Science]]
[[Category:Injury]]
