Sage Journals: Discover world-class research

Abstract

Rope and harness vertical dance takes place off the floor with the dancer suspended from his or her center of mass in a harness attached to a rope from a point overhead. Vertical dance represents a novel environment for training and performing in which expected stresses on the dancer's body are different from those that take place during dance on the floor. Two male and eleven female dancers with training in vertical dance performed six typical vertical dance movements with electromyography (EMG) electrodes placed bilaterally on rectus abdominus, external oblique, erector spinae, and latis-simus dorsi. EMG data were expressed as a percentage of maximum voluntary isometric contraction (MVIC). A simplified musculoskeletal model based on muscle activation for these four muscle groups was used to estimate the compressive force on the spine. The greatest muscle activation for erector spinae and latissimus dorsi and the greatest trunk compressive forces were seen in vertical axis positions where the dancer was moving the trunk into a hyper-extended position. The greatest muscle activation for rectus abdominus and external oblique and the second highest compressive force were seen in a supine position with the arms and legs extended away from the center of mass (COM). The least muscle activation occurred in positions where the limbs were hanging below the torso. These movements also showed relatively low muscle activation compression forces. Post-test survey results revealed that dancers felt comfortable in these positions; however, observation of some positions indicated insufficient muscular control. Computing the relative contribution of muscles, expressed as muscle activation and estimated spinal compression, provided a measure of how much the muscle groups were working to support the spine and the rest of the dancer's body in the different movements tested. Additionally, identifying typical muscle recruitment patterns in each movement will help identify key exercises for training that should promote injury prevention.

Get full access to this article

View all access options for this article.

References

Wilson

, Kwon

YH.

The role of biomechanics in understanding dance movement: a review.

J Dance Med Sci. 2008;12(3):109–16.

Krasnow

, Wilmerding

, Stecyk

, . Biomechanical research in dance: a literature review. Med Probl Perform Art. 2011 Mar;26(1):3–23.

Simpson

, Kanter

Jump distance of dance landings influencing internal joint forces: I.

Axial forces. Med Sci Sports Exerc. 1997 Jul;29(7):916–27.

Kulig

, Fietzer

, Popovich

Jr.

Ground reaction forces and knee mechanics in the weight acceptance phase of a dance leap take-off and landing.

J Sports Sci. 2011 Jan;29(2):125–31.

Shippen

, May

Calculation of muscle loading and joint contact forces during the rock step in Irish dance.

J Dance Med Sci. 2010;14(1):11–8.

Mayers

, Bronner

, Agraharasa-makulam

, Ojofeitimi. Lower extremity kinetics in tap dance. J Dance Med Sci. 2010;14(1):3–10.

Personal communication, Wanda Moretti, Il Posto Dance Company, 4/19/2013.

Long

Yoga Mat Companion 3: Anatomy for Backbends and Twists.

Plattsburgh, NY: Bandha Yoga Publications LLC, 2010.

Clippinger

Dance Anatomy and Kinesiology.

Champaign, IL: Human Kinetics, 2007.

10.

Marras

, Sommerich

CM.

A three-dimensional motion model of loads on the lumbar spine: II.

Model validation. Hum Factors. 1991 Apr;33(2):139–49.

11.

Marras

, Granta

KP.

The development of an EMG-assisted model to assess spine loading during whole-body free-dynamic lifting.

J Electro-myogr Kinesiol. 1997 Dec;7(4):259–68.

12.

Escamilla

, Babb

, DeWitt

, . Nontraditional abdominal exercises: implications for rehabilitation and training. Phys Ther. 2006 May;86(5):656–71.

13.

Beim

, Giraldo

, Pincivero

, . Abdominal strengthening exercises: a comparative EMG Study. J Sports Rehab. 1997;6:11–20.

14.

Floyd

, Silver

PHS.

Electromyographic study of patterns of activity in the anterior abdominal wall muscles in man.

J Anat. 1950 Apr;84(2):132–46.

15.

De Luca

CJ.

The use of surface electromyography in biomechanics.

J Appl Biomech. 1997;13:135–63.

16.

Dai

, Sorensen

, Derrick

, Gillette

JC.

The effects of postseason break on knee biomechanics and lower extremity EMC in a stop-jump task: implications for ACL injury.

J Appl Biomech. 2012 Dec;28(6):708–17.

17.

de Leva

Adjustments to Zatsi-orsky-Seluyanov's segment inertia parameters.

J Biomech. 1996 Sep;29(9):1223–30.

18.

McGill

, Grenier

, Kavcic

Cholewicki

Coordination of muscle activity to assure stability of the lumbar spine.

J Electromyogr Kinesiol. 2003 Aug;13(4):353–9.

19.

Vera-Garcia

, Brown

SHM

, Gray JR , McGill

SM.

Effects of different levels of torso coactivation on trunk muscular and kinematic responses to posteriorly applied sudden loads.

Clin Biomech (Bristol, Avon). 2006 Jun;21(5):443–55.

20.

Stokes

IAF

, Gardner-Morse

, Henry

SM.

Abdominal muscle activation increases lumbar stability: analysis of contributions of different muscle groups.

Clin Biomech (Bristol, Avon). 2011 Oct;26(8):797–803.

21.

Marras

, Jorgensen

MJ.

Granata

, Wiand

Female and male trunk geometry: size and prediction of the spine loading trunk muscles derived from MRI.

Clin Biomech (Bristol, Avon). 2001 Jan;16(1):38–46.

22.

Quint

, Wikle

, Shirazi-Adl

, . Importance of the intersegmental trunk muscles for the stability of the lumbar spine. A biomechanical study in vitro. Spine (Phila Pa 1976). 1998 Sep;23(18):1937–45.

23.

Dias

, Menacho Mde

, Ma-zuquin

, . Comparison of the electromyographic activity of the anterior trunk during the execution of two Pilates exercises—teaser and longspine—for healthy people. J Electromyogr Kinesiol. 2014 Oct;24(5):689–97.

24.

Marques

, Morcelli

, Hallal

, Goncalves

EMG activity of trunk stabilizer muscles during Centering Principle of Pilates Method.

J Bodyw Mov Ther. 2013 Apr: 17(2): 185–91.

25.

Liebenson

, Karpowiz

, Brown

, . The active straight leg raise test and lumbar spine stability. PM R. 2009 Jun;1(6):530–5.

Trunk Muscle Activation and Estimating Spinal Compressive Force in Rope and Harness Vertical Dance

Abstract

Get full access to this article

References