Training Effects Following Resection Surgery in Patients With Lung Cancer
NCT ID: NCT01771796
Last Updated: 2016-02-17
Study Results
The study team has not published outcome measurements, participant flow, or safety data for this trial yet. Check back later for updates.
Basic Information
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COMPLETED
NA
48 participants
INTERVENTIONAL
2012-11-30
2016-02-29
Brief Summary
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Detailed Description
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Chronic diseases are the leading cause of morbidity and mortality worldwide and is known that regular exercise has a beneficial effect on most of them. Many studies have shown the benefit of exercise in patients diagnosed with cancer, especially breast and colorectal cancer, even during active phases of specific treatment, however few studies refers to possible benefit of exercise in patients with lung cancer following surgical resection. Lung cancer is one of the most common cancers in Spain, the second in the general population and the first if we refer exclusively to the male population. Not only it is a common type of cancer, but also presents a high mortality with a survival rate at 5 years of approximately 12%. However, survival improves significantly in stage I (60-80% at 5 years) and progressively worse until stage IV (\<5% at 5 years). Surgery is the treatment of choice for lung cancer in stages I and IIa. Despite the good results in terms of survival, it is not free of side effects. Depending on the extent of lung resection, it may result in functional limitations and impact on the patients' quality of life. Pulmonary lobectomy entails a significant reduction of the functional reserve: impaired lung function (FEV1 of 15%) and reduced exercise capacity (16% in the shuttle test). In contrast, in the pneumonectomy, reduced pulmonary function is disproportionately higher (FEV1 of 35%) in comparison with the exercise limitation (23%). To date we have no knowledge of studies that have specifically evaluated the effects of exercise training in these patients.
Dysfunction of the diaphragm and other respiratory muscles, prevalent in COPD (chronic obstructive pulmonary disease) patients, has important clinical implications. It associates with susceptibility to hypercapnic ventilatory failure, ineffective cough, and even higher incidence of repeated hospital admissions and mortality. Therefore, respiratory muscle weakness described in some patients justifies the need to train respiratory muscles because there is no general exercise (bicycle, legs, arms) able to induce an overload enough to achieve training effect on respiratory muscles. Since a large proportion of lung cancer patients also suffer from COPD, endurance and strength of respiratory muscles are expected to be reduced. Moreover, after lobectomy patients have some degree of peripheral muscle deconditioning, which could be linked to the loss of reserve function, but also the relative rest. Although muscle training has been successfully used to restore function in patients with various chronic diseases and frailty, there is little evidence on the beneficial effects of muscle training in patients after lung cancer surgery.
Many studies have related the insulin-like growth factor I (IGF-I) and its major regulatory proteins, Insulin-like growth factor binding protein (IGFBP-3) with various malignancies, including lung cancer. In healthy subjects with sedentary lifestyle, caloric diet leads to obesity and alterations of hormonal, metabolic and inflammatory modulate carcinogenesis. These disorders include chronic hyperinsulinemia, elevated plasma IGF-I, plasma enhanced bioavailability and increased steroid sex hormones of systemic inflammation markers. Physical exercise, in addition to its cardiovascular effects and/or muscular strength and endurance produces a response on plasmatic levels of IGF-I and IGFBP-3. This variability has been justified, in most cases, depending on type, intensity and/or duration of the exercise performed.
Conditions
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Study Design
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RANDOMIZED
PARALLEL
TREATMENT
DOUBLE
Study Groups
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Aerobic and muscle resistance training
Aerobic and muscle resistance training
After having been allocated randomly to one of the two groups, patients of Intervention Group are encouraged to follow a training program (aerobic and endurance muscle training) during 8 weeks.
Usual care group
All patients (intervention and usual care group) are patients with lung cancer who underwent a resection surgery.
No interventions assigned to this group
Interventions
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Aerobic and muscle resistance training
After having been allocated randomly to one of the two groups, patients of Intervention Group are encouraged to follow a training program (aerobic and endurance muscle training) during 8 weeks.
Eligibility Criteria
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Inclusion Criteria
* 2\) patients with lung cancer stage I or II with surgery indication.
* 3\) ability to understand and accept the trial procedures and to sign an informed consent.
Exclusion Criteria
* 2\) complementary cancer treatment pre-or post-surgery.
* 3\) treatment with drugs with potential effect on muscle structure and function (steroids, anabolic steroids, thyroid hormones and immunosuppressive).
* 4\) cognitive or language barriers that impede the realization of the objective of the study and / or collaboration in the exercise program.
18 Years
80 Years
ALL
No
Sponsors
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Hospital de Sant Pau
OTHER
Parc de Salut Mar
OTHER
Responsible Party
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Esther Marco Navarro
PhD
Locations
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1) Physical Medicine and Rehabilitation Dpt. Parc de Salut Mar.
Barcelona, Barcelona, Spain
2) Respiratory Medicine Dpt. Hospital de la Santa Creu i Sant Pau.
Barcelona, Barcelona, Spain
Countries
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Other Identifiers
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PSM/RHB/CR/12
Identifier Type: -
Identifier Source: org_study_id
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