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The Functional Impacts of Strength Training in Cerebral Palsy[edit | edit source]

Paper reviewed:Functional Outcomes of Strength Training in Spastic Cerebral Palsy By Diane L Damino and Mark F. Abel^[1]

Background to this research:[edit | edit source]

Physical weakness is a recognized clinical characteristic of spastic cerebral palsy. Despite this, such symptoms are rarely addressed therapeutically. With the increasing rate of diagnosis (2-3% per 1000 births)^[2] the pre-existing prejudice towards using strength training programs as a treatment initiative for children and adolescences with cerebral palsy has been overlooked as researchers become more open to the concept. New treatment initiatives for juvenile cerebral palsy patients are been proposed, including resistance training programs.

Where is the research from?[edit | edit source]

Diane L. Damiano and Mark F. Abel, two researchers from a cerebral palsy clinic in Virginia proposed the foundations for the investigation. The study was commenced in 1998 through the partnership of: The American Congress of Rehabilitation and Medicine as well as The American Academy of Physical Medicine and Rehabilitation. The research was carried out in a paediatric rehabilitation centre using resources and facilities from a tertiary.

What did the research involve?[edit | edit source]

Cerebral palsy patients can be divided into several clinical subgroups, for this study two diagnosed populations were involved: patients with spastic hemiplegia and patients with moderate-severe spastic diplemia. A more severe diagnosis class was selected for the diplemia group, to allow researchers to observe and compare the impacts training may have on a spectrum of diagnosed individuals.

A total of 11 participants met the pre-requisite conditions and were approved for the study. Finding appropriate subjects for research was difficult, many eligible candidates had additional underlying medical conditions. As opposed to searching tirelessly for a larger subject base, investigators settled for quality over quantity.

The 11 chosen subjects were aged between 8-14 years old. All participants demonstrated less than 50% of normal muscular strength. The research involved trials that compared the strength of 8 predetermined muscle groups before and after the introduction of the resistance training. The training program lasted for 6 weeks and included 3 allocated sessions per week. Numerous tests were used to evaluate the results including: hand-held dynamometers, gait analysis, gross motor function measure and energy expenditure. The intensity of each individuals program was specific to their age and functional capabilities.

What kind of research was this?[edit | edit source]

The investigation design was a prospective before and after trial, the concluded results determined the clinical effectiveness of the program. During both trials the isometric strength of 8 muscle groups located in the upper and lower extremities were evaluated by measuring strength output, range of motion and general functionality, which encompassed assessments such as grip strength. Functional measurements including gait velocity were utilized to investigate the impacts of the training on general mobility.

The variety in diagnosis amongst the participants is an advantage of this study. Comparisons between the subjects allowed for conclusions to be denoted in relation to potential limitations and advantages of the resistance training. Having two different subgroups represented, along with varying symptom severity, provided an insight into how this treatment could benefit all subgroups.

A weakness of the study design was the small subject base; due to the availability of appropriate subjects. Appealing to rehabilitation institutes or advertising an expression of interest, could have assisted in increasing the participant number. Not limiting the participants to particular clinical subgroups would allow researchers to compare how different diagnostic symptoms are affected by resistance training. Administering tailored programs derived from the individual’s subgroup would allow more physically capable individuals to excel and complete more advanced testing procedures. Extending the duration of the training program would improve the prospective results and created more reliable data.

What were the basic results?[edit | edit source]

Both groups displayed significant strength gains in the targeted muscles. The overall cohort experienced: an increase in gait velocity and cadence, an improved gross motor function measure and no change in energy expenditure. The hemiplegia patients previously displayed astonishing strength differences (asymmetry) between the two sides of their body. The average improvement in strength asymmetry imbalance was 21%. The typical absolute strength gain across all muscle groups was 22.7 Newtons. The diplemia group experienced an average bilateral strength increase of 39%. However, this improvement only totalled their accumulated muscle strength to 51% of normal body strength. The average absolute strength gain across all muscles was 34.5 Newtons.

How did the researchers interpret the results?[edit | edit source]

The results revealed all participants experienced an increase in gait velocity and no change in energy expenditure. Subjects who displayed greater improvements in velocity tended to experience a worsening in gait efficiency. This was caused by the body’s delayed adaptive response to the strength gains. Those subjects who excelled at a rapid pace had much higher heart rates during exercise, indicating their body had not yet accommodated for the new level of activity intensity. Subjects who demonstrated smaller and more gradual improvements increased their gait velocity and efficiency simultaneously.

From these observations researchers considered the opportunity for further improvements in cadence and velocity with a continuation of the resistance training. Consequential increases in strength resulting from the program had a strong correlation to an improvement in an individual’s gross motor function measure. These improvements were primarily due to the frequent utilization of the lower extremities. The extent of improvement in other body regions was difficult to assess due to the participants limited motor capabilities.

Conclusions and implications of this research[edit | edit source]

During the investigation no participants experienced a deterioration in functionality. The short term resistance program demonstrated positive functional outcomes for all participants, regardless of their diagnostic subgroup. To improve the results of similar investigations more physically challenging assessment tools should be introduced for those individuals who have more advanced motor capabilities, this would encourage continuous improvement. The hemiplegia group experienced improvements in strength asymmetry; the average strength difference was reduced to 20%. However, by clinical diagnosis a strength difference greater than 10% is considered significant ^[3] .

From the results of this research it was proposed that implicating strength asymmetry correction treatment prior to the commencement of resistance training could prove beneficial. As a result of this investigation several related studies have been completed. These investigations include: The effects of early deep tissue treatment in cerebral palsy youths ^[4] , alternatives to surgical correction in cerebral palsy ^[5] and improvements in muscle symmetry in children with cerebral palsy using hippotherapy ^[6] . Following this investigation, more research focussing on the potential of extended resistance and strength training regimes has been conducted. In addition, other clinical symptoms of cerebral palsy are being addressed therapeutically, including muscle shortening and spasticity. Different methods of therapy are been trialled including hydrotherapy ^[7] , hippotherapy (horse riding), postural correction ^[8] and new medications. With further trials and research it’s possible that early resistance training will become a prominent treatment initiative for cerebral palsy.

References[edit | edit source]

1. ↑ Diane L Damino, Mark F Abel. Functional Outcomes of Strength Training in Spastic Cerebral Palsy. Arch Phys Med Rehabil 1998;79:119-25.
2. ↑ Data and Statistics: Cerebral Palsy, NCBDDD, released 2015. Data and Statistics of Cerebral Palsy, Available at: http://www.cdc.gov/ncbddd/cp/data.html. Accessed 23 September 2015
3. ↑ Better Health, 2014, Symptoms and Causes of Cerebral Palsy, http://www.betterhealth.vic.gov.au/bhcv2/bhcarticles.nsf/pages/cerebral_palsy_causes_and_implications, Accessed 16/9/15
4. ↑ William Benda, Nancy H. McGibbon, and Kathryn L. Grant. The Journal of Alternative and Complementary Medicine. December 2003, 9(6): 817-825. doi:10.1089/107555303771952163
5. ↑ Liptak, G. S. (2005), Complementary and alternative therapies for cerebral palsy. Ment. Retard. Dev. Disabil. Res. Rev., 11: 156–163. doi: 10.1002/mrdd.20066
6. ↑ William Benda, Nancy H. McGibbon, and Kathryn L. Grant. The Journal of Alternative and Complementary Medicine. December 2003, 9(6): 457-464. doi:10.1089/107555303771952163.
7. ↑ Michelle Kelly and Johanna Darrah (2005). Aquatic exercise for children with cerebral palsy. Developmental Medicine & Child Neurology, , pp 838-842. doi:10.1017/S0012162205001775.
8. ↑ Bobath K, Bobath B (1964) The facilitation of normal postural reactions and movements in the treatment of cerebral palsy. Physiotherapy 50: 246–262