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Fisioterapia em Movimento

On-line version ISSN 1980-5918

Fisioter. mov. vol.30  supl.1 Curitiba  2017

http://dx.doi.org/10.1590/1980-5918.030.s01.ao13 

Original articles

Respiratory muscle strength of patients with esophagus and stomach neoplasms

Força muscular respiratória de pacientes com neoplasia de esôfago e estômago

Evelyn Aline Boscolo Ruivo1 

Juliana Rodrigues Correia Mello1 

Odete Mauad Cavenaghi1 

Alexandre Lins Werneck1 

Lucas Lima Ferreira1  * 

1Faculdade de Medicina de São José do Rio Preto (FAMERP), São José do Rio Preto, SP, Brazil

Abstract

Introduction:

In cancer patients, the reduced food intake causes weight loss and promotes protein-calorie malnutrition. This results in loss of lean body mass, which affects both skeletal muscles and respiratory muscles.

Objective:

Evaluate and compare the respiratory muscle strength of patients with esophageal and stomach neoplasia during the preoperative period.

Methods:

This is a cross-sectional study carried out with 24 patients of both genders hospitalized in a teaching hospital. They underwent a physical therapy evaluation composed of anthropometric data and measurement of respiratory muscle strength through manovacuometry. Paired and unpaired t-tests were used to compare the values obtained with the predicted equations.

Results:

Regarding the disease prevalence, 66.66%(16) of the individuals had stomach neoplasm and 33.33%(8) esophageal neoplasm. Of the patients with esophageal neoplasm, 100% were men with a mean age of 63 ± 9.16 years. Of those with stomach neoplasm, 68.75% were men with a mean age of 69.36 ± 10.92 years. Female patients with stomach neoplasm had significantly higher BMI (p = 0.01) than male patients, and they were classified as overweight. Both neoplasms had significantly lower real values (p ≤ 0.05) than predicted values at the maximal expiratory pressure.

Conclusion:

Patients with esophageal and stomach neoplasms in the preoperative period present reduction in the expiratory muscle strength. There were no statistically significant differences, when we compared the maximum respiratory pressures between the two types of neoplasms investigated.

Keywords: Muscle Strength; Respiratory Muscles; Neoplasms; Esophagus; Stomach

Resumo

Introdução:

Em pacientes com câncer, a diminuição da ingestão de alimentos ocasiona perda ponderal e promove uma desnutrição protéico-calórica que resulta na perda de massa corporal magra, acometendo tanto músculos esqueléticos, quanto a musculatura respiratória.

Objetivo:

Avaliar e comparar a força muscular respiratória de pacientes com neoplasia de esôfago e estômago durante o período pré-operatório.

Métodos:

Estudo transversal com 24 pacientes de ambos os sexos internados em um Hospital-Escola, os quais foram submetidos a uma avaliação fisioterapêutica composta por dados antropométricos e mensuração da força muscular respiratória, por meio da manovacuometria. Comparações dos valores obtidos com as equações preditas foram realizadas pelo teste t pareado e não pareado.

Resultados:

Quanto à prevalência, 66,66%(16) dos indivíduos apresentavam neoplasia de estômago e 33,33%(8), neoplasia de esôfago. Dos pacientes com neoplasia de esôfago, 100% eram homens com média de 63 ± 9,16 anos e, na neoplasia de estômago, 68,75% eram homens com 69,36 ± 10,92 anos. Os pacientes com neoplasia de estômago, do sexo feminino, apresentaram IMC significativamente maior (p= 0,01) do que os pacientes do sexo masculino, sendo classificadas como sobrepeso. Na pressão expiratória máxima, ambas as neoplasias apresentaram valores reais significativamente menores (p ≤ 0,05) aos valores preditos.

Conclusão:

Pacientes com neoplasia de esôfago e estômago no período pré-operatório apresentam redução na força muscular expiratória. Na comparação das pressões respiratórias máximas, entre os dois tipos de neoplasias investigadas, não houve diferenças estatisticamente significativas.

Palavras-chave: Força Muscular; Músculos Respiratórios; Neoplasia; Esôfago; Estômago

Introduction

Esophageal cancer (EC) affects more than 450,000 people worldwide each year. In men, it is the fifth most frequent tumor and it ranks 13th in women. Stomach cancer is the second-leading cause of cancer deaths in both sexes worldwide. It is the second most frequent tumor in men and the third in women1. These types of neoplasms evolve with protein-calorie malnutrition. This is a fact that changes the strength of the respiratory muscles, especially the expiratory one, resulting in a greater impact on type II fibers, thus, reducing the capacity of relaxation and contraction of these muscles2.

Studies have shown that EC is common in men (3:1) and in blacks in the 6th and 7th decades of life. Risk factors such as age, alcoholism, and smoking contribute to its etiology, as well as clinical conditions such as megaesophagus and Barrett esophagus. The incidence of gastric CA increases between the ages of 35 to 40 years, and it reaches its apex between the age of 50 to 70 years. It follows different rhythms, and in terms of prevalence, it includes exaggerated consumption of salt, H. pylori infection, precancerous conditions, such as chronic gastritis, intestinal metaplasia, and those undergoing subtotal gastrectomies. Elderly men and underprivileged socioeconomic groups are the most affected ones, regardless of geographic location3), (4), (5), (6), (7), (8.

Patients with unintentional weight loss of 5% or more, at one month, are less likely to survive than those with stable weight are9. In patients with advanced CA, decreased food intake causes weight loss and promotes protein-calorie malnutrition. The result of this is the loss of lean body mass, functional impairment, and deterioration of physical function caused by catabolism and tissue alteration of skeletal muscles10), (11), (12), (13.

Studies have shown that the loss of respiratory muscles is proportional to that of other skeletal muscles, and it may be even greater in some cases. There are changes in lung parenchyma structure, surfactant quality, and inefficient ion transport in the respiratory system. There is a reduction in the thickness, length, and muscular mass of the diaphragm. With decrease of muscle strength, cough becomes less effective and leads to a reduction in eliminating secretions. There is an increased risk of atelectasis and pneumonia. It is essential to maintain adequate nutritional support, combined with skeletal muscle training, once muscle weakness is a great predictor of functional degeneration14), (15.

Respiratory muscles are considered the motor driving-force of the pulmonary system, once breathing is a vital function performed by such muscles. Every surgical procedure presents some degree of pulmonary dysfunction, even when the lungs are not directly involved. Therefore, since the beginning of preoperative period, respiratory muscle strength should be recommended16. Thoracic and/or abdominal surgeries compromise these muscles, which leads to a decrease in strength, hypoxemia, and/or acute respiratory failure with a high prevalence of postoperative complications17. Manovacuometry is a low-cost procedure capable of stratifying the risk of changes in respiratory function. It aims through guidelines and evaluation of risk factors the faster patient recovery after the surgery18.

Currently, esophageal and stomach neoplasms have been prominent in the world statistics. Thus, it is critical to identify the effects of cancer and its treatment over functional aspects, especially regarding respiratory muscle strength, once this directly affects the patients’ quality of life. It is expected that the individual with esophageal and stomach neoplasms presents respiratory muscle strength deficit due to poor nutritional status, weight loss, and lean body mass with consequent functional impairment. Therefore, there is a need for further studies on the proposed theme, so that the functional diagnosis can be established early and therapeutic interventions can be effective in the patient rehabilitation. The objective of this study was to evaluate and compare the respiratory muscle strength of patients with esophageal and stomach neoplasms during the preoperative period.

Methods

This is an observational, cross-sectional, prospective study developed at Hospital de base, in the city of São José de Rio Preto - São Paulo, Brazil.

Inclusion criteria were patients of both sexes, age above 18 years, who were hospitalized and undergoing investigation procedure of esophagus or stomach neoplasms from July to September 2015. The study sample was composed of all individuals hospitalized in this period. Exclusion criteria were individuals with a general state of physical or mental impairment that hindered their collaboration in the functional evaluation; those without a confirmed diagnosis; those with diseases with increased risk of intrathecal pressure, and those already in the postoperative period. The Local Institutional Ethics Committee approved the study under Opinion n# 1.126.078 and written informed consent was obtained from each patient.

The study participants have undergone a physiotherapeutic evaluation, and the information collected was attached to a file prepared by the researchers, which contained data such as age, gender, body mass index (BMI), and evaluation of respiratory muscle strength through manovacuometry.

Regarding functional evaluation (BMI), the patient's body weight and height were taken into account for low weight, adequate weight, pre-obesity, and obesity levels (class I, II, and III)19.

The study participants’ weight loss of pre and post-diagnosis of esophagus and stomach neoplasms was considered in the BMI item, but the anthropometric variables were not considered outcome variables for this study. This data was highlighted because the literature associates the loss of body mass resulting from cancer with functional impairments due to weakness in the skeletal and respiratory musculature. However, we did not use statistical analysis to correlate weight loss with reduction of inspiratory and expiratory muscle strengths among the evaluated patients.

Respiratory evaluation was obtained using an analog manovacuometer (Wika®). Patient was positioned seated on bed with pending lower limbs, keeping his/her shoulders relaxed, as well as accessory muscles of the breath. In order to obtain maximal inspiratory pressure (MIP) measurement, the patientwas askedto perform maximum inspiratory and expiratory efforts to reach the residual volume, and afterwards the patient should perform a maximum inspiratory effort. At maximal expiratory pressure (MEP), the evaluation occurred through maximal inspiration up to the total lung capacity, followed by a maximum expiratory effort. For each pressure, three repetitions were performed. An interval of one-minute recovery was observed after each repetition to learn the technique. We considered the highest value obtained20), (21), (22.

In order to calculate maximum respiratory pressures according to age and sex, for men and women aged 20 to 80 years, we used regression equations based on the values predicted by the equations of Neder et al.23.

Men Women
MIPrv (cmH2O) = 155.3 - 0.80 x age MIPRV (cmH2O) = 110.4 - 0.49 x age
MEPtlc (cmH2O) = 165.3 - 0.81 x age MEPTLC (cmH2O) = 115.6 - 0.61 x age

In a young adult, MIP values range from -90 to -120 cm H2O and MEP of +100 to +150 cm H2O. MIP values between -70 to -45 cm H2O indicates weakness; values ranging from -40 to -25 cm H2O indicates fatigue; values below -20 cm H2O demonstrates respiratory muscle failure, and MIP less than -50 cm H2O suggests inability to breathe large volumes and ineffective cough20.

We did not include a control group because the comparison of the respiratory pressures was made through formulas predicted for each gender and age, which were available within the literature. These were taken as a basis for the calculation of respiratory muscle strength in the patients on this study. This made it possible to compare the normality value, which resembles to a control group for a given gender and age of a healthy individual in relation to the same gender and age. However, in this case, the patient had esophageal and stomach newoplasia.

We used descriptive statistics and data are expressed as mean ± SD, absolute numbers and percentages. We used inferential statistics. Normality was tested with the Shapiro-Wilk tests. Anthropometric and functional variables were compared using paired and unpaired t tests. Statistical analyzes were performed using SPSS for Windows®, version 17.0 (SPSS, Chicago, IL, USA). P ≤ 0.05 was consideredstatistically significant.

Results

The study sample consisted of 24 individuals. Regarding esophagus and stomach neoplasms, the prevalent gender was males 8 (100%) and 11 (68.75%), respectively. Table 1 presents sociodemographic data, including age; body mass, height, and BMI. In relation to patients’ age group with stomach neoplasm, the mean age was 69.36 ± 10.92 years for men (minimum age of 44 and a maximum of 90 years). Women had a mean age of 59.4 ± 14.8 (minimum age of 43 and a maximum of 81 years). In esophagus neoplasm, mean age among males was 63 ± 9.16 years (minimum age of 53 and maximum of 79 years).

Stomach neoplasia female patients had significantly higher BMI (p = 0.01) than male patients, and they were classified as overweight. There were no females in the esophagus neoplasm patients group, which made it impossible to compare genders (Table 1).

Table 1 Patients anthropometric and clinical characteristics 

Variable Stomach Neoplasm Esophagus Neoplasm
Male Female p-value Male Female
n (%) n = 11 (68.75%) n = 5 (31.25%) - n = 8 (100%) -
Age (years) 69.36 ± 10.92 59.4 ± 14.8 0.15 63 ± 9.16 -
Body Mass (kg) 61.45 ± 9.13 72.30 ± 21.09 0.16 62.2 ± 14.8 -
Height (meters) 1.68 ± 0.10 1.60 ± 0.11 0.16 1.71 ± 0.06 -
Body Mass (kg/m2)
Pre-diagnosis 23.88 ± 4.99 29.33 ± 5.48 0.06* 25.03 ± 4.28 -
Post-diagnosis 21.68 ± 2.62 27.91 ± 5.97 0.01* 21.23 ± 4.61 -
p = 0.27 p = 0.76 p = 0.03
Diagnosis time
Between 1 to 5 months 09 04 07
6 months or over 02 01 01

Note: n = number of patients; Kg = kilogram; m = meters; Kg/m2 = kilogram per square meter; *Unpaired t test; †Paired t test.

Source: Data provided by the researchers.

In respiratory muscle strength, data showed that there were no statistically significant differences for Maximum Inspiratory Pressure. According to Table 2, as for Maximum Expiratory Pressure, it was observed that both male and female patients with stomach and esophagus neoplasms had significantly lower values (p ≤ 0.05) than the predicted values.

Table 2 Comparison of maximal respiratory pressures found and predicted of patients with stomach and esophagus neoplasms according to gender 

Gender Stomach Neoplasm
Obtained MIP Predicted MIP p-value* ObtainedMEP Predicted MEP p-value*
Male 94.54 ± 81.53 104.85 ± 6.00 0.67 65.45 ± 45.02 188.85 ± 19.72 < 0.0001
Female 80 ± 73.48 73.02 ± 9.41 0.82 50 ± 34.64 135.87 ± 13.00 0.007
Esophagus Neoplasm
Male 105 ± 58.06 108.35 ± 5.04 0.87 76.25 ± 29.24 204.19 ± 19.52 < 0.0001
Female - - - -

Note: MIP = maximum inspiratory pressure; MEP = maximum expiratory pressure; *paired t test.

Source: Data provided by the researchers.

According to Table 3, when comparing maximal respiratory pressures between the two types of neoplasms investigated, it was verified that there were no statistically significant differences for MIP and MEP.

Table 3 Comparison of maximum respiratory pressures found between male patients with stomach and esophageal neoplasms 

Gender MIP MEP
Stomach Neoplasm Esophagus Neoplasm p-value* Stomach Neoplasm Esophagus Neoplasm p-value*
Male 94.54 ± 81.53 105 ± 58.06 0.76 65.45 ± 45.02 76.25 ± 29.24 0.56

Note: *Unpaired t test. Source: Data provided by the researchers.

Discussion

In this study, the evaluation of maximal respiratory pressures identified that MEP in both neoplasms presented values significantly lower than the predicted ones, which demonstrates a strength deficit in the expiratory muscles. There were no statistically significant differences in the comparison of these pressures between the types of neoplasms. Systematic searches on databases did not identify similar studies investigating patients’ respiratory muscle strength related to esophagus and stomach neoplasms in the preoperative period. This fact prevents any possible comparisons and limits the inferences about the results obtained.

A recent study has evaluated respiratory and peripheral muscle strength in cancer patients (CA) and in patients with benign diseases. The authors divided the 55 patients into two groups: patients with CA and patients with benign disease. They have observed that the CA group presented a decrease in pulmonary function and in both expiratory and peripheral muscle strength when compared to the benign disease group24. These data corroborate the findings of the present study, in which patients with stomach and esophageal neoplasms presented reduction of the expiratory muscle strength. However, the study in question did not characterize in the analyzed population the CA type. According to the literature, this strength deficit of the expiratory muscles in CA patients could be explained by oncologic cachexia and sarcopenia that result in loss of strength and mainly reduction of respiratory capacity in these patients25.

Other authors evaluated respiratory muscle strength in 59 patients with lung cancer with a mean age of 58.5 ± 9.46 years in the preoperative period. Regarding MEP, there was a significant difference between obtained and predicted values. However, there was no relevant difference for MIP26. Once again, we verified that literature data, even in the case of another type of neoplasm, corroborate the results of the current study, in which, for stomach and esophagus neoplasms the values obtained for MEP were significantly lower than the predicted values. Notwithstanding, comparisons between the studies are not plausible because neoplasm sites are different. However, the literature reports that esophagus neoplasm may be a manifestation of lung neoplasm.

Respiratory muscle strength was also evaluated in 20 patients undergoing breast cancer surgery. In the preoperative period, it was found reduced respiratory muscle strength in relation to the predicted values for each patient. MIP and MEP were 43.14% and 40.09% of predicted, respectively. Comparing preoperative respiratory muscle strength and postoperative results, we found that MIP and MEP (p < 0.001) presented reduction in the postoperative period27. These findings are credited by the authors due to the effects of the surgical procedure, such as anesthesia, pain-dependent hypoventilation, ineffective cough, and central nervous system depression imposed by anesthetic drugs.

According to the literature, the reduction of MEP may be associated with changes in respiratory mechanics, which alter the ventilatory pattern. Overweight or obesity may cause a decrease of alveolar ventilation and explain the reduced value of maximal expiratory pressures. On the other hand, the reduction of MIP is associated with diaphragmatic dysfunction, which reduces ventilation in the lower lung lobes and has an impact on tidal volume and vital capacity17.

In the sample analyzed in the present study, there was a reduction of body mass in both neoplasms. However, this reduction was only significant for the esophagus neoplasm group of patients. According to the literature, malnutrition caused by neoplasms affecting the gastrointestinal tract alters the strength of the expiratory muscles. This malnutrition causes a greater impact on type II muscle fibers, reducing the capacity of relaxation and contraction of these muscles. As inspiratory muscles, especially the diaphragm, have a greater portion of type I muscle fibers, which are relatively spared during the weight loss process, it is possible to justify MIP maintenance and MEP decrease in these individuals2), (14.

Current evidence suggests that cancer patients with normal or elevated body mass also have a high prevalence of sarcopenia, indicating that this characteristic is not necessarily related to malnutrition28. This can be observed among the women of the present study who were classified as overweight. It can also be observed in those individuals who did not show weight loss because during evaluation, they have shown a reduction from the maximum respiratory pressures.

Another study reports that the decrease in MEP also occurs due to the lack of training of the expiratory musculature, because during quiet breath, the expiration happens passively, but it becomes active during physical activity and voluntary hyperventilation. Therefore, changes in the MEP can trigger dysfunction of the tonsil capacity with the buildup of secretions and consequent pneumonia16.

Conversely, other authors concluded that patients with CA show a decrease of 50% in MIP, generated during the manovacuometry. This inability to generate normal pressures may be due to the effects of CA on the central nervous system, inspiratory muscle atrophy, or isotonic contractile dysfunction of the diaphragm29), (30. These findings differ from the results of the present study, which did not identify loss of inspiratory muscle strength. An experimental study demonstrated a 14% decrease in the percentage of type I muscle fibers and a 13% increase in type II muscle fibers of the diaphragm. The animals evaluated showed a significant decrease in the strength of this muscle. The cause was related to a sarcomeric dysfunction with degradation of myosin heavy chain with a decrease of 27% without decrease in actin, troponin, and tropomyosin31), (32.

The scarcity of articles evaluating respiratory muscle strength of patients with esophagus and stomach neoplasms made it impossible to compare and discuss the results obtained in the present study with the findings of the literature. Nevertheless, according to the bibliographic survey, the expiratory musculature seems to be more commonly affectedcompared to the inspiratory muscle, even in different situations than the neoplasm itself.

The present study has as limitations, the small sample size resulting from the prospective inclusion of the patients and the absence of classification of CA stage. Besides, the theme is not much addressed. Such limitations were due to the reduced period for inclusion of patients, and it can be inferred that longer periods could make the sample more homogeneous. In view of this reality, the importance of developing more studies that evaluate the respiratory muscle strength of patients with esophageal and stomach neoplasms in the daily clinic is essential. The results of this study demonstrated that these patients present a decrease in MEP. According to the course of the disease, a significant weight loss is expected over a short period, with loss of lean body mass leading to degeneration of skeletal and respiratory muscle function.

Conclusion

Patients with esophageal and stomach neoplasms evaluated in the preoperative period had an expiratory muscle strength reduction when the value obtained was compared to the predicted one. No differences in respiratory muscle strength were observed comparing esophageal and stomach neoplasms.

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Received: May 12, 2016; Accepted: June 21, 2016

*EABR: BS, email: evelyn.ruivo.fisio@gmail.com

JRCM: BS, email: jrcfisio@yahoo.com.br

OMC: MS, email: bebelmauad2009@hotmail.com

ALW: PhD, email: alexandrelinswerneck@gmail.com

LLF: MS, email: lucas_lim21@hotmail.com

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