Rationale and Feasibility of Resistance Training in hEDS/HSD: A Narrative Review
Abstract
:1. Introduction and Rationale
1.1. Background, Features, and Habits of hEDS/HSD
1.2. Musculoskeletal Features
1.2.1. Bone
1.2.2. Muscles and Tendons
1.3. Decreased Proprioception and Balance
1.4. BMI and Body Composition
1.5. Physical Activity, Exercise Habits, and Physical Therapy Experiences in hEDS/HSD Populations
2. Materials and Methods
3. Review of the Literature Using Resistance training in the hEDS/HSD Population
3.1. Case Studies
3.2. Studies in Children and Adolescents
3.3. Studies in Adults
3.3.1. Primary Training Goal: Knee Proprioception
3.3.2. Primary Training Goal: Lumbar Stabilization
3.3.3. Primary Training Goal: Optimize Activities of Daily Living
3.3.4. Primary Training Goal: Gaining Muscular Strength
3.3.5. Primary Research Goal: Feasibility of Heavy Shoulder Resistance Training Program in hEDS/HSD Populations
4. Conclusions and Future Directions
- 1.
- What should a rehabilitation program look like for the hEDS/HSD population and what is the proper progression, both regionally (e.g., training muscle groups in a specific order) and with regards to intensity/mode, to employ in such settings?
- 2.
- Can an hEDS/HSD patient who has successfully completed a supervised rehabilitation program and no longer experiences chronic dislocations, subluxations, or excessive pain safely progress to unsupervised resistance training in a gym setting? How?
- 3.
- Most research has been reactive in nature (i.e., training was prescribed in response to symptoms)—is there a proactive exercise program that could be given to patients as soon as they are diagnosed with hEDS/HSD in an attempt to “get in front of” injuries or symptoms?
Funding
Institutional Review Board Statement
Informed Consent Statement
Acknowledgments
Conflicts of Interest
References
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Study | Subject | Diagnosis | Intervention Goal | Intervention | Mode of Resistance | Duration; Frequency | Results |
---|---|---|---|---|---|---|---|
Hinton, 1986 [62] | 10-year-old female | Primary: EDS type III or type XI | Increase strength, coordination, proprioception | Shoulder ab/adduction, internal/external rotation, and horizontal ab/adduction Shoulder press/lat pull down Bench press/shoulder retraction Hip ab/adduction Isometric eccentric exercises (all affected joints) Neuromuscular training (all affected joints) | Isokinetic dynamometer, weight machines, balance devices, body weight | 11 weeks; 1–3×/week 11 months later returned to 2×/week for 4 weeks | At 5 weeks: Pain-free range of motion (shoulders) No subluxations At 10 weeks: ↑ strength in all muscle groups At 13 weeks: Return to play and normal activities Continued ankle instability At 1 year: ↔ strength (from 10 weeks) ↑ school attendance ↑ peer interaction |
Russek, 2000 [63] | 28-year-old female | Primary: Hyper-mobility syndrome | Manage pain and return to physically active lifestyle | Reduce “excessive” exercise Eliminate wrist weights during jogging Eliminate or limit calisthenics or martial arts Use protective and supportive splints (no exercise intervention was administered) | NA | Follow-up at 1 month and 1 year | At 1 month: ↓ pain Returned to jogging and martial arts At 12 months: ↓ pain frequency ↔ pain Decreased jogging No calisthenics Significant joint pain in new locations |
Pennetti, 2018 [64] | 35-year-old female | Primary: hEDS w/TNXB gene mutation Secondary: Cervical and lumbar radiculitis | Manage pain; return to physically active lifestyle | Postural reeducation Proprioceptive neuromuscular facilitation (PNF) of the scapula Myofascial trigger point release for lumbar spine and pelvis Spinal mobilization Core stabilization | Body weight, otherwise not specified | 14 months; 2×/week for 16 weeks; 1×/week thereafter | Pain-free cervical and lumbar AROM ↑ periscapular strength ↑ hip strength ↑ neck flexor endurance ↓ pain (NPRS) ↑ function (PSFS) |
Zhou et al., 2018 (Case 1) [65] | 41-year-old female | Primary: hEDS | Manage chronic pain | Medication Coping strategies Education on postural awareness and body mechanics Kinesiotaping instruction “Exercise prescription with graded exercises, including pool activity.” | Not specified | 2 months | ↓ pain intensity after 2 and 18 months ↑ ADL ability after 2 and 18 months |
Zhou et al., 2018 (Case 2) [65] | 23-year-old female | Primary: EDS (type unspecified, assumed hEDS) | Manage chronic pain | Medication Coping strategies Education on symptom control and exercise program Relaxation techniques | Not specified | Not Specified | ↓ pain |
Kitagawa et al., 2020 [66] | 14-year-old Female | Primary: hEDS Secondary: MDI of the shoulder | Improve scapular motor control and decrease MDI | Months 1–3: Isometric Movements Shoulder abduction In/external rotation Extension, and flexion Months 4–6: The Watson Program for MDI | Resistance band | 6 Months; 1–2×/week | ↑ Active Flexion ↑ Active Abduction ↑ Stability @ 6 mo. ↓ Stability @ 12 mo. after discharge to home program ↑ Motion ↑ Function Positive Sulcus sign @ 6 and 12 months |
Study | N (% Female) | Comparison Group (n) | Age (Years) | Inclusion Criteria | Target | Mode of Resistance | Duration; Frequency | Results |
---|---|---|---|---|---|---|---|---|
Kemp et al., 2010 [67] | 57 (33%) | Yes (27, generalized program) | 10.9 (2.5) | Primary: BJHS | LE | Not specified | 8 weeks; 6 total sessions Home program 7×/week throughout | At 8 weeks: ↓ pain ↓ parental assessment of pain ↓ Global score (Targeted only) ↔ 6 min shuttle test At 5 months: ↓ pain ↓ parental assessment of pain (Targeted only) ↓ Global score (Targeted only) |
Pacey et al., 2013 [68] | 26 (69%) | Yes (14, neutral ROM) | 12.0 (2.9) | Primary: JHS Secondary: Knee pain | LE | Body weight, resistance bands | 8 weeks; 2×/week for 4 weeks, once per two weeks thereafter Home program 5×/week throughout | Both Groups: ↑ thigh strength ↓ knee pain ↑ parent-reported physical and psychosocial summary scores ↔ stair ascent ↔ CHAQ functional measures Hyperextension ROM Group: ↑ CHQ psychosocial score ↑ self-esteem ↑ mental health Neutral ROM Group: ↑ physical summary score |
Van Meulenbroek et al., 2020 [69] | 14 | None | 17.5 (16.0–20.3) * | Primary: hEDS/HSD Secondary: Kinesiophobia | Core LE | Not specified | 15 weeks total (8 weeks of exercise intervention followed by 5 weeks of exposure therapy) | ↓ pain ↑ functional ability ↑ muscle strength ↑ motor performance |
Study | Total N (% Female) | Control Group (n) | Age (years) | Inclusion Criteria | Target | Mode of Resistance | Duration; Frequency | Results |
---|---|---|---|---|---|---|---|---|
Ferrell et al., 2004 [70] | 18 (89%) | No | 27.3 (10.4) | Primary: JHS Secondary: knee pain | LE | Body weight, balance board | 8 weeks; 4×/week | ↑ proprioception ↑ balance ↑ peak and avg quadricep strength ↑ peak and avg hamstring strength |
Sahin et al., 2008 [56] | 40 (73%) | Yes (25) | 26.9 (7.2) | Primary: BJHS Secondary: knee pain | LE | Body weight, Balance board, mini-trampoline | 8 weeks; 3×/week | ↓ joint angle error ↑ occupational activity (AIMS-2) |
Bathen et al., 2013 [71] | 12 (100%) | No | 35 * | Primary: EDS-HT/JHS | WB | Body weight, Resistance bands, Exercise ball | 12 weeks; 5×/week | ↓ tandem walking backwards time ↓ stair walking up time ↑ calf raise performance ↔ pain |
Palmer et al., 2016 [72] | 18 (94.7%) | Yes (Advice Only, 7) | 33.5 (7.4) | Primary: JHS Secondary: no other conditions causing MSK pain | WB | Resistance band, body weight, ankle weights | 16 weeks; 6 supervised sessions | ↓ pain MDHAQ vs. advice only † ↓ global MDHAQ vs. advice only † ↓ fatigue vs. advice only † ↑ VAS Pain most affected joint † |
Toprak-Celeny and Ozer, 2017 [73] | 38 (100%) | No | 20.6 (2.2) | Primary: BJHS Excluded EDS | Core | Body Weight, Resistance band (Weeks 3–8 only), Exercise Ball (Weeks 6–8 only) | 8 weeks; 3×/week | ↓ pain ↑ stability with eyes closed (static and dynamic) |
Reychler et al., 2019 [74] | 19 (100%) | Yes (10) | 40.7 (14.1) | Primary: hEDS Secondary: reduced inspiratory muscle strength | IM | Breathing trainer | 6 weeks; 5×/week | ↑ 6MWT distance vs. baseline and control ↑ SNIP vs. baseline and control ↑ FEV1 vs. baseline and control |
Daman et al., 2019 [75] | 24 (100%) | No | 22.0 (1.9) | Primary: JHS Excluded regular exercisers/ athletes | LE | Body weight | 4 weeks; 3×/week | ↑ joint position sense ↓ pain ↑ quality of life |
To and Alexander, 2019 [49] | 102 (16%) | Yes (26) | 34.9 (10.4) | Primary: JHS, GJH Secondary: Anterior knee pain (limited) (Primary diagnosis for control) | LE | Not specified but suspected to be body weight | 16 weeks; 3×/week | ↑ strength, all groups ↑ torque, all groups ↓ pain, all groups ↔ rate of strength gain between groups |
Liaghat et al., 2020 [76] | 12 (92%) | No | 39.3 (13.9) | Primary: hEDS/HSD Secondary: Shoulder pain/ dislocations/ atraumatic instability | UE | Free weights | 16 weeks; 3×/week | ↑ self-report shoulder stability † ↓ pain † ↓ fatigue † ↑ isometric strength † ↓ proprioception error † |
Luder et al., 2021 [77] | 51 (100%) | Yes (24) | 26.5 (4.5) | Primary: GJH (hEDS/HSD included in sample) Excluded regular exercisers (4+ h/week) | LE Core | Not specified but suspected to be free weights and/or machines as reference to 1RM and %1RM are made | 12 weeks; 2×/week | ↔ knee flexor strength ↔ knee extensor strength ↔ muscle CSA ↔ muscle mass ↔ muscle density |
Identify and validate specific outcome measures that can be used in the hEDS/HSD population to enhance comparison between studies. |
Conduct more research on children and adolescents utilizing control groups. |
Identify proper progression of exercises and modes in adults and report ample detail on the exercises and modes being employed to allow for replication and implementation. |
Investigate a proactive exercise prescription that can be recommended upon diagnosis. |
Explore the relationship between baseline physical fitness and response to training programs in the hEDS/HSD population. |
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Zabriskie, H.A. Rationale and Feasibility of Resistance Training in hEDS/HSD: A Narrative Review. J. Funct. Morphol. Kinesiol. 2022, 7, 61. https://doi.org/10.3390/jfmk7030061
Zabriskie HA. Rationale and Feasibility of Resistance Training in hEDS/HSD: A Narrative Review. Journal of Functional Morphology and Kinesiology. 2022; 7(3):61. https://doi.org/10.3390/jfmk7030061
Chicago/Turabian StyleZabriskie, Hannah A. 2022. "Rationale and Feasibility of Resistance Training in hEDS/HSD: A Narrative Review" Journal of Functional Morphology and Kinesiology 7, no. 3: 61. https://doi.org/10.3390/jfmk7030061
APA StyleZabriskie, H. A. (2022). Rationale and Feasibility of Resistance Training in hEDS/HSD: A Narrative Review. Journal of Functional Morphology and Kinesiology, 7(3), 61. https://doi.org/10.3390/jfmk7030061