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Krafttraining

  • Joachim Wiskemann
  • Christiane Hedrich
  • Marcel Bannasch

Zusammenfassung

Systematisches Krafttraining stellt eine anerkannte Methode in der begleitenden bewegungstherapeutischen Behandlung zahlreicher chronischer Erkrankungen dar. Erst mit Beginn des Jahres 2003 wurden vermehrt Untersuchungen zur Machbarkeit und Wirksamkeit von Krafttraining bei onkologischen Erkrankungen veröffentlicht. Heute liegen mehr als 25 randomisierte, kontrollierte Untersuchungen vor, welche die Wirkung von Krafttraining als ausschließliche Intervention, in Kombination mit Ausdauertraining oder innerhalb eines multimodalen Therapieansatzes, bei Krebspatienten untersuchen.

Literatur

  1. Adamsen L, Midtgaard J, Rorth M, Borregaard N, Andersen C, Quist M, Moller T, Zacho M, Madsen JK, Knutsen L (2003) Feasibility, physical capacity, and health benefits of a multidimensional exercise program for cancer patients undergoing chemotherapy. Support Care Cancer 11:707–716Google Scholar
  2. Adamsen L, Andersen C, Midtgaard J, Moller T, Quist M, Rorth M (2009a) Struggling with cancer and treatment: young athletes recapture body control and identity through exercise: qualitative findings from a supervised group exercise program in cancer patients of mixed gender undergoing chemotherapy. Scand J Med Sci Sports 19:55–66Google Scholar
  3. Adamsen L, Quist M, Andersen C, Moller T, Herrstedt J, Kronborg D, Baadsgaard MT, Vistisen K, Midtgaard J, Christiansen B, Stage M, Kronborg MT, Rorth M (2009b) Effect of a multimodal high intensity exercise intervention in cancer patients undergoing chemotherapy: randomised controlled trial. BMJ 339:b3410Google Scholar
  4. Al Majid S, Waters H (2008) The biological mechanisms of cancer-related skeletal muscle wasting: the role of progressive resistance exercise. Biol Res Nurs 10:7–20Google Scholar
  5. Alberga AS, Segal RJ, Reid RD, Scott CG, Sigal RJ, Khandwala F, Jaffey J, Wells GA, Kenny GP (2011) Age and androgen-deprivation therapy on exercise outcomes in men with prostate cancer. Support Care CancerGoogle Scholar
  6. Alibhai SM, Breunis H, Timilshina N, Johnston C, Tomlinson G, Tannock I, Krahn M, Fleshner NE, Warde P, Canning SD, Klotz L, Naglie G (2010) Impact of androgen-deprivation therapy on physical function and quality of life in men with nonmetastatic prostate cancer. J Clin Oncol 28:5038–5045Google Scholar
  7. Barnard KL, Adams KJ, Swank AM, Mann E, Denny DM (1999) Injuries and muscle soreness during the one repetition maximum assessment in a cardiac rehabilitation population. J Cardiopulm Rehabil 19:52–58Google Scholar
  8. Battaglini C, Bottaro M, Dennehy C, Rae L, Shields E, Kirk D, Hackney AC (2007) The effects of an individualized exercise intervention on body composition in breast cancer patients undergoing treatment. Sao Paulo Med J 125:22–28Google Scholar
  9. Boeckh-Beherens W-U, Buskies W (2009) Fitness-Krafttraining. Die besten Übungen und Methoden für Sport und Gesundheit. Rowohlt, ReinbekGoogle Scholar
  10. Bohannon RW (2006) Test-retest reliability of the MicroFET 4 hand-grip dynamometer. Physiother Theory Pract 22:219–221Google Scholar
  11. Brown JC, Huedo-Medina TB, Pescatello LS, Pescatello SM, Ferrer RA, Johnson BT (2011) Efficacy of exercise interventions in modulating cancer-related fatigue among adult cancer survivors: a meta-analysis. Cancer Epidemiol Biomarkers Prev 20:123–133Google Scholar
  12. Brzycki M (1993) Strength testing: predicting a one-rep max from a repsto-fatigue. J Phys Educ Recreation Dance 64:88–90Google Scholar
  13. Campbell WW, Crim MC, Young VR, Evans WJ (1994) Increased energy requirements and changes in body composition with resistance training in older adults. Am J Clin Nutr 60:167–175Google Scholar
  14. Cheema B, Gaul CA, Lane K, Fiatarone Singh MA (2008) Progressive resistance training in breast cancer: a systematic review of clinical trials. Breast cancer research and treatment 109:9–26Google Scholar
  15. Clarkson PM, Kaufman SA (2010) Should resistance exercise be recommended during breast cancer treatment? Med Hypotheses 75(2):192–195Google Scholar
  16. Coleman EA, Coon S, Hall-Barrow J, Richards K, Gaylor D, Stewart B (2003) Feasibility of exercise during treatment for multiple myeloma. Cancer Nurs 26:410–419Google Scholar
  17. Courneya KS, Segal RJ, Reid RD, Jones LW, Malone SC, Venner PM, Parliament MB, Scott CG, Quinney HA, Wells GA (2004) Three independent factors predicted adherence in a randomized controlled trial of resistance exercise training among prostate cancer survivors. J Clin Epidemiol 57:571–579Google Scholar
  18. Courneya KS, Segal RJ, Mackey JR, Gelmon K, Reid RD, Friedenreich CM, Ladha AB, Proulx C, Vallance JK, Lane K, Yasui Y, McKenzie DC (2007) Effects of aerobic and resistance exercise in breast cancer patients receiving adjuvant chemotherapy: a multicenter randomized controlled trial. J Clin Oncol 25:4396–4404Google Scholar
  19. Cramp F, James A, Lambert J (2010) The effects of resistance training on quality of life in cancer: a systematic literature review and meta-analysis. Supportive care in cancer : official journal of the Multinational Association of Supportive Care in Cancer 18:1367–1376Google Scholar
  20. De Backer IC, Schep G, Backx FJ, Vreugdenhil G, Kuipers H (2009) Resistance training in cancer survivors: a systematic review. International journal of sports medicine 30:703–712Google Scholar
  21. De Backer IC, Van Breda E, Vreugdenhil A, Nijziel MR, Kester AD, Schep G (2007) High-intensity strength training improves quality of life in cancer survivors. Acta Oncol 46:1143–1151Google Scholar
  22. De Backer IC, Vreugdenhil G, Nijziel MR, Kester AD, van Breda E, Schep G (2008) Long-term follow-up after cancer rehabilitation using high-intensity resistance training: persistent improvement of physical performance and quality of life. Br J Cancer 99:30–36Google Scholar
  23. Fleck SJ, Kraemer WJ (2004) Designing resistance training programs. Human Kinetics, Champaign, IllinoisGoogle Scholar
  24. Fröhlich M, Schmidtbleicher D (2008) Trainingshäufigkeit im Krafttraining– ein metaanalytischer Zugang. Deutsche Zeitschrift für Sportmedizin 58:4–12Google Scholar
  25. Galvao DA, Taaffe DR, Spry N, Joseph D, Newton RU (2010) Combined resistance and aerobic exercise program reverses muscle loss in men undergoing androgen suppression therapy for prostate cancer without bone metastases: a randomized controlled trial. J Clin Oncol 28:340–347Google Scholar
  26. Gottlob A (2001) Differenziertes Krafttrainingmit Schwerpunkt Wirbelsäule. Urban & Fischer, JenaGoogle Scholar
  27. Gross M, Huffman GM, Phillips CN, Wray JA (1991) Intra-Machine and inter-Machine reliability of Biobex and Cybex II for knee flexion and extension peak torque and angular work. J Orthop Sports Phys Ther 13:329–335Google Scholar
  28. Hanson ED, Hurley BF (2011) Intervening on the side effects of hormone-dependent cancer treatment: the role of strength training. J Aging Res 2011:903291Google Scholar
  29. Hauner H (2003) Adipositas – Klinik und Ernährungstherapie. Enährungsmedizin. Urban & Fischer, MünchenGoogle Scholar
  30. Herrero F, San Juan AF, Fleck SJ, Balmer J, Perez M, Canete S, Earnest CP, Foster C, Lucia A (2006) Combined aerobic and resistance training in breast cancer survivors: A randomized, controlled pilot trial. Int J Sports Med 27:573–580Google Scholar
  31. Herrero F, San Juan AF, Fleck SJ, Foster C, Lucia A (2007) Effects of detraining on the functional capacity of previously trained breast cancer survivors. Int J Sports Med 28:257–264Google Scholar
  32. Hunter GR, Wetzstein CJ, Fields DA, Brown A, Bamman MM (2000) Resistance training increases total energy expenditure and free-living physical activity in older adults. J Appl Physiol 89:977–984Google Scholar
  33. Jones LW, Eves ND, Kraus WE, Potti A, Crawford J, Blumenthal JA, Peterson BL, Douglas PS (2010) The lung cancer exercise training study: a randomized trial of aerobic training, resistance training, or both in postsurgical lung cancer patients: rationale and design. BMC Cancer 10:155Google Scholar
  34. Keating NL, O’Malley AJ, Freedland SJ, Smith MR (2010) Diabetes and cardiovascular disease during androgen deprivation therapy: observational study of veterans with prostate cancer. J Natl Cancer Inst 102:39–46Google Scholar
  35. Keilani MY, Posch M, Zorn C, Knötig M, Pircher M, Quittan M, Fialka-Moser V, Jirasek U, Crevenna R (2007) Vergleichende Analyse der Messwertergebnisse von zwei Dynamometern zur Messung der isokinetischen Kraft der kniegelenksbewegenden Muskulatur. Phys Rehab Kur Med 17:327–333Google Scholar
  36. Kemmler W et al. (2007) Umsetzung leistungssportlicher Prinzipien in der Osteoporose-Prophylaxe – Zusammenfassende Ergebnisse der Erlanger Fitness- und Osteoporose Präventions-Studie (EFOPS). Deutsche Zeitschrift für Sportmedizin 58:427–432Google Scholar
  37. Kilbreath SL, Refshauge KM, Beith JM, Ward LC, Simpson JM, Hansen RD (2006) Progressive resistance training and stretching following surgery for breast cancer: study protocol for a randomised controlled trial. BMC Cancer 6:273Google Scholar
  38. Knols RH, Aufdemkampe G, de Bruin ED, Uebelhart D, Aaronson NK (2009) Hand-held dynamometry in patients with haematological malignancies: measurement error in the clinical assessment of knee extension strength. BMC Musculoskelet Disord 10:31Google Scholar
  39. Koutroumpi M, Pitsavos C, Stefanadis C (2008) The role of exercise in cardiovascular rehabilitation: a review. Acta Cardiol 63:73–79Google Scholar
  40. Lastayo PC, Larsen S, Smith S, Dibble L, Marcus R (2010) The feasibility and efficacy of eccentric exercise with older cancer survivors: a preliminary study. Journal of geriatric physical therapy 33:135–140Google Scholar
  41. Lastayo PC, Marcus RL, Dibble LE, Smith SB, Beck SL (2011) Eccentric exercise versus usual-care with older cancer survivors: the impact on muscle and mobility – an exploratory pilot study. BMC Geriatrics 11:5Google Scholar
  42. Latham NK, Bennett DA, Stretton CM, Anderson CS (2004) Systematic review of progressive resistance strength training in older adults. The journals of gerontology Series A, Biological sciences and medical sciences 59:48–61Google Scholar
  43. Layne JE, Nelson ME (1999) The effects of progressive resistance training on bone density: a review. Medicine and science in sports and exercise 31:25–30Google Scholar
  44. Lee S, Kuk JL, Katzmarzyk PT, Blair SN, Church TS, Ross R (2005) Cardiorespiratory fitness attenuates metabolic risk independent of abdominal subcutaneous and visceral fat in men. Diabetes Care 28:895–901Google Scholar
  45. LeSuer D, McCormick J, Mayhew J, R.L W, Arnold MD (1997) The accuracy of prediction equations for estimating 1-RM performance in the bench press, squat, and deadlift. Journal of Strength and Conditioning Research 11:211–213Google Scholar
  46. Levinger I, Goodman C, Hare DL, Jerums G, Toia D, Selig S (2009) The reliability of the 1RM strength test for untrained middle-aged individuals. J Sci Med Sport 12:310–316Google Scholar
  47. Ligibel JA, Campbell N, Partridge A, Chen WY, Salinardi T, Chen H, Adloff K, Keshaviah A, Winer EP (2008) Impact of a mixed strength and endurance exercise intervention on insulin levels in breast cancer survivors. J Clin Oncol 26:907–912Google Scholar
  48. Ligibel JA, Giobbie-Hurder A, Olenczuk D, Campbell N, Salinardi T, Winer EP, Mantzoros CS (2009) Impact of a mixed strength and endurance exercise intervention on levels of adiponectin, high molecular weight adiponectin and leptin in breast cancer survivors. Cancer causes & control : CCC 20:1523–1528Google Scholar
  49. Mayhew JL, Prinster JL, Ware JS, Zimmer DL, Arabas JR, Bemben MG (1995) Muscular endurance repetitions to predict bench press strength in men of different training levels. J Sports Med Phys Fitness 35:108–113Google Scholar
  50. McGuire DK, Levine BD, Williamson JW, Snell PG, Blomqvist CG, Saltin B, Mitchell JH (2001) A 30-year follow-up of the Dallas Bedrest and Training Study: I. Effect of age on the cardiovascular response to exercise. Circulation 104:1350–1357Google Scholar
  51. McGuire R, Waltman N, Zimmerman L (2011) Intervention Components Promoting Adherenceto Strength Training Exercise in Breast Cancer Survivors With Bone Loss. West J Nurs Res 33(5):671–689Google Scholar
  52. McKenzie DC, Kalda AL (2003) Effect of upper extremity exercise on secondary lymphedema in breast cancer patients: a pilot study. J Clin Oncol 21:463–466Google Scholar
  53. McKenzie F, Jeffreys M (2009) Do lifestyle or social factors explain ethnic/racial inequalities in breast cancer survival? Epidemiol Rev 31:52–66Google Scholar
  54. McNeely ML, Parliament M, Courneya KS, Seikaly H, Jha N, Scrimger R, Hanson J (2004) A pilot study of a randomized controlled trial to evaluate the effects of progressive resistance exercise training on shoulder dysfunction caused by spinal accessory neurapraxia/neurectomy in head and neck cancer survivors. Head Neck 26:518–530Google Scholar
  55. Mello M, Tanaka C, Dulley FL (2003) Effects of an exercise program on muscle performance in patients undergoing allogeneic bone marrow transplantation. Bone Marrow Transplant 32:723–728Google Scholar
  56. Milne HM, Wallman KE, Gordon S, Courneya KS (2008) Effects of a combined aerobic and resistance exercise program in breast cancer survivors: a randomized controlled trial. Breast Cancer Res Treat 108:279–288Google Scholar
  57. NCCN (2011) National Comprehensive Cancer Network. Clinical Practice Guidelines in Oncology. Cancer-Related Fatigue. Version 1.2011 (www.nccn.org)Google Scholar
  58. Noble M, Russell C, Kraemer L, Sharratt M (2011) UW WELL-FIT: the impact of supervised exercise programs on physical capacity and quality of life in individuals receiving treatment for cancer. Support Care Cancer, May 2 [Epub ahead of print]Google Scholar
  59. Rahnama N, Nouri R, Rahmaninia F, Damirchi A, Emami H (2010) The effects of exercise training on maximum aerobic capacity, resting heart rate, blood pressure and anthropometric variables of postmenopausal women with breast cancer. J Res Med Sci 15:78–83Google Scholar
  60. Ratamess NA, Alvar BA, Evetoch TK, Housh TJ, Kibler WB, Kraemer WJ, Triplett NT (2009) American College of Sports Medicine position stand. Progression models in resistance training for healthy adults. Medicine and science in sports and exercise 41:687–708Google Scholar
  61. Ratcliffe MA, Lanham SA, Reid DM, Dawson AA (1992) Bone mineral density (BMD) in patients with lymphoma: the effects of chemotherapy, intermittent corticosteroids and premature menopause. Hematol Oncol 10:181–187Google Scholar
  62. Ruiz JR, Sui X, Lobelo F, Lee DC, Morrow JR, Jr., Jackson AW, Hebert JR, Matthews CE, Sjostrom M, Blair SN (2009) Muscular strength and adiposity as predictors of adulthood cancer mortality in men. Cancer epidemiology, biomarkers & prevention : a publication of the American Association for Cancer Research, cosponsored by the American Society of Preventive Oncology 18:1468–1476Google Scholar
  63. Saad F, Adachi JD, Brown JP, Canning LA, Gelmon KA, Josse RG, Pritchard KI (2008) Cancer treatment-induced bone loss in breast and prostate cancer. J Clin Oncol 26:5465–5476Google Scholar
  64. Schmitz KH (2010) Balancing lymphedema risk: exercise versus deconditioning for breast cancer survivors. Exerc Sport Sci Rev 38:17–24Google Scholar
  65. Schmitz KH, Ahmed RL, Hannan PJ, Yee D (2005) Safety and efficacy of weight training in recent breast cancer survivors to alter body composition, insulin, and insulin-like growth factor axis proteins. Cancer epidemiology, biomarkers & prevention: a publication of the American Association for Cancer Research, cosponsored by the American Society of Preventive Oncology 14:1672–1680Google Scholar
  66. Schmitz KH, Troxel AB, Cheville A, Grant LL, Bryan CJ, Gross C, Lytle LA, Ahmed RL (2009) Physical activity and lymphedema (the PAL trial): Assessing the safety of progressive strength training in breast cancer survivors. Contemp Clin Trials 30(3):233–245Google Scholar
  67. Schwartz AL (2004) Physical activity after a cancer diagnosis: psychosocial outcomes. Cancer Invest 22:82–92Google Scholar
  68. Shaw CE, McCully KK, Posner JD (1995) Injuries during the one repetition maximum assessment in the elderly. J Cardiopulm Rehabil 15:283–287Google Scholar
  69. Siegrist M et al. (2006) Krafttrainingan konventionellen bzw. oszillierenden Geräten und Wirbelsäulengymnastik in der Prävention der Osteoporose bei postmenopausalen Frauen. Deutsche Zeitschrift für Sportmedizin 57:182–187Google Scholar
  70. Smoot B, Wong J, Cooper B, Wanek L, Topp K, Byl N, Dodd M (2010) Upper extremity impairments in women with or without lymphedema following breast cancer treatment. J Cancer Surviv 4(2):167–178Google Scholar
  71. Speck RM, Gross CR, Hormes JM, Ahmed RL, Lytle LA, Hwang WT, Schmitz KH (2010) Changes in the Body Image and Relationship Scale following a one-year strength training trial for breast cancer survivors with or at risk for lymphedema. Breast Cancer Res Treat 121:421–430Google Scholar
  72. Sprod LK, Hsieh CC, Hayward R, Schneider CM (2010) Three versus six months of exercise training in breast cancer survivors. Breast Cancer Res Treat 121:413–419Google Scholar
  73. Strasser B, Siebert U, Schobersberger W (2010) Resistance training in the treatment of the metabolic syndrome: a systematic review and meta-analysis of the effect of resistance training on metabolic clustering in patients with abnormal glucose metabolism. Sports medicine 40:397–415Google Scholar
  74. Sweeney C, Schmitz KH, Lazovich D, Virnig BA, Wallace RB, Folsom AR (2006) Functional limitations in elderly female cancer survivors. J Natl Cancer Inst 98:521–529Google Scholar
  75. Swenson KK, Nissen MJ, Anderson E, Shapiro A, Schousboe J, Leach J (2009a) Effects of exercise vs bisphosphonates on bone mineral density in breast cancer patients receiving chemotherapy. J Support Oncol 7:101–107Google Scholar
  76. Swenson KK, Nissen MJ, Leach JW, Post-White J (2009b) Case-control study to evaluate predictors of lymphedema after breast cancer surgery. Oncol Nurs Forum 36:185–193Google Scholar
  77. Thews G, Mutschler E, Vaupel P (1999) Anatomie, Physiologie, Pathophysiologie des Menschen. Wissenschaftliche Verlagsgesellschaft, StuttgartGoogle Scholar
  78. Ulander K, Jeppsson B, Grahn G (1997) Quality of life and independence in activities of daily living preoperatively and at follow-up in patients with colorectal cancer. Supportive care in cancer: official journal of the Multinational Association of Supportive Care in Cancer 5:402–409Google Scholar
  79. Waltman NL, Twiss JJ, Ott CD, Gross GJ, Lindsey AM, Moore TE, Berg K (2003) Testing an intervention for preventing osteoporosis in postmenopausal breast cancer survivors. J Nurs Scholarsh 35:333–338Google Scholar
  80. Waltman NL, Twiss JJ, Ott CD, Gross GJ, Lindsey AM, Moore TE, Berg K, Kupzyk K (2010) The effect of weight training on bone mineral density and bone turnover in postmenopausal breast cancer survivors with bone loss: a 24-month randomized controlled trial. Osteoporosis international : a journal established as result of cooperation between the European Foundation for Osteoporosis and the National Osteoporosis Foundation of the USA 21:1361–1369Google Scholar
  81. Weineck J (2007) Optimales Training. Spitta Verlag, BalingenGoogle Scholar
  82. Winters-Stone KM, Schwartz A, Nail LM (2010) A review of exercise interventions to improve bone health in adult cancer survivors. J Cancer Surviv 4:187–201Google Scholar
  83. Winters-Stone KM, Dobek J, Nail L, Bennett JA, Leo MC, Naik A, Schwartz A (2011) Strength training stops bone loss and builds muscle in postmenopausal breast cancer survivors: a randomized, controlled trial. Breast Cancer Res Treat 127:447–456Google Scholar
  84. Winzer BM, Paratz JD, Reeves MM, Whiteman DC (2010) Exercise and the Prevention of Oesophageal Cancer (EPOC) study protocol: a randomized controlled trial of exercise versus stretching in males with Barrett’s oesophagus. BMC Cancer 10:292Google Scholar
  85. Wiskemann J, Dreger P, Schwerdtfeger R, Bondong A, Huber G, Kleindienst N, Ulrich CM, Bohus M (2011) Effects of a partly self-administered exercise program before, during, and after allogeneic stem cell transplantation. Blood 117:2604–2613Google Scholar

Copyright information

© Springer-Verlag Berlin Heidelberg 2012

Authors and Affiliations

  • Joachim Wiskemann
    • 1
  • Christiane Hedrich
    • 2
  • Marcel Bannasch
    • 3
  1. 1.Wiss. Koordination - Sektion „Sport und Krebs“ Präventive Onkologie (G110)Nationales Centrum für Tumorerkrankungen (NCT), HeidelbergHeidelbergDeutschland
  2. 2.HeidelbergDeutschland
  3. 3.Abteilungen Präventive Onkologie und Medizinische Onkologie Arbeitsgruppe - Sektion Sport und KrebsNationales Centrum für Tumorerkrankungen (NCT) HeidelbergHeidelbergDeutschland

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