Spirometric reference values in Senegalese black adults

Spirometric volumes and expiratory flows were measured among 448 Senegalese males and females of 25-80 yrs of age. The values obtained are similar to those reported for black Africans and black Americans in the literature. Volumes are 15-25% lower in males and 23% lower in females than in Caucasians. Forced expiratory flow between 25-75% of vital capacity (VC), (FEF25-75) is 5-18% lower in males and 19% lower in females. FEF25-75/VC ratio is higher in blacks than in Whites, but the forced expiratory volume in one second FEV1/VC ratio is similar in black and white subjects. However, we cannot use proportional factors to determine spirometric black standards from white reference values, so, equations of regression and nomograms with age and height are proposed for black Africans.     

Spirometric prediction equations for Hispanic children and adults in New Mexico

We conducted a population-based survey of respiratory diseases and lung function in a New Mexico Hispanic community, and developed spirometric prediction equations based on data from 576 children and adults. Spirometric test procedures were followed as recommended by the American Thoracic Society. For children 6 through 18 yr of age, we used a logarithmic model to predict spirometric parameters. We used simple linear regression for adults 25 through 80 yr of age. On the basis of exploratory analyses, we excluded adult subjects who were obese, defined as a body mass index of 30 kg/m2 or greater. This report describes these regressions. We did not perform regression analysis for those subjects between 19 and 24 yr of age because of small numbers and the inappropriateness of grouping these subjects with older adults for regression analysis. As an alternative to a regression equation for this age group specifically, we propose linear interpolation between values obtained using prediction equations developed for children and for adults. Finally, we compared the percent predicted values obtained from our internal prediction equations with equations from other populations of white children and adults. In general, the comparison equations underestimated the percent predicted values in our population.     

Spirometric reference equations for European females and males aged 65-85 yrs.

The aim of this study was to describe spirometric reference equations for healthy never-smoking European adults aged 65-85 yrs and to compare the predicted values of this sample with those from other studies including middle-aged and/or older adults. Reference equations and normal ranges for forced expiratory volume in one second (FEV1), forced vital capacity (FVC), forced expiratory volume in six seconds (FEV6), FEV1/FVC ratio and FEV1/FEV6 ratio were derived from a healthy subgroup of 458 subjects aged 65-85 yrs. Spirometry examinations followed the 1994 American Thoracic Society recommendations and the quality of the data was continuously monitored and maintained. Reference values and lower limits of normal were derived using a piecewise polynomial model with age and height as predictors. The reference values of FEV1 and FVC from the present study were higher than those given by prediction equations from the European Community for Coal and Steel. By contrast, use of prediction equations from Caucasian-American elderly subjects (Cardiovascular Health Study) consistently overpredicted FVC and FEV1 in females by 8.5 and 2.1%, respectively. In males, equations from the Cardiovascular Health Study overpredicted FVC by 2.8%, whilst underpredicting FEV1 by 2.5%. In conclusion, these results underscore the importance of using prediction equations appropriate to the origin, age and height characteristics of the subjects being studied.     

Spirometric reference values for the 6-s FVC maneuver

STUDY OBJECTIVES: The guidelines of the National Lung Health Education Program for COPD screening proposed a shorter FVC maneuver (forced expiratory volume at 6 s of exhalation [FEV(6)]). Although reference values for FEV(6) are available from the third National Health and Nutrition Examination Survey, forced expiratory flow between 25% and 75% of FVC (FEF(25-75%)) reference values for the shorter 6-s maneuver are not available and are needed. In particular, calculation of largest observed volume during the first 6 s of an FVC maneuver (FVC(6)), from a shortened FVC maneuver, is necessary because the FEF(25-75%) measurement is based on a percentage of FVC or, for a shorter maneuver, FVC(6). DESIGN: We reanalyzed the raw volume-time curves from the third National Health and Nutrition Examination Survey to calculate FVC(6), forced expiratory volume at 0.5 s of exhalation, forced expiratory volume at 3 s of exhalation, ratio of the FEV(1) to largest observed volume during the first 6 s of an FVC maneuver expressed as a percentage (FEV(1)/FEV(6)%), and forced expiratory flow between 25% and 75% of the largest observed volume during the first 6 s of an FVC maneuver (FEF(25-75%6)) in addition to the previously reported values for FEV(1), FEV(6), and FEV(1)/FEV(6)%. PATIENTS OR PARTICIPANTS: Using the same normal, asymptomatic, nonsmoking reference population from a previous study, reference values for these parameters were derived from best values. RESULTS: A total of 2,261 white, 2,564 African-American, and 2,666 Mexican-American subjects aged 8 to 80 years were included in the analysis. Fifty-four subjects from the previous study were not included due to missing raw volume-time curves. CONCLUSIONS: These reference values, utilizing the FVC(6), provide investigators with the means of evaluating the relative merits of using the shorter FVC maneuver as a surrogate for the traditional FVC. They are needed particularly for calculating FEF(25-75%), as statistically significant differences were observed between the FEF(25-75%) and FEF(25-75%6).     

Spirometric reference values in Tunisian children

BACKGROUND: In Tunisia, there are no normal values of pulmonary function for healthy Tunisian children. OBJECTIVES: The purpose of this study was to set reference values for spirometric lung function in Tunisian children and to compare these results with other data sets. METHODS: Spirometric values were measured with a Minato portable spirometer in 1,114 asymptomatic, nonsmoking Tunisian children (581 boys and 533 girls) 6-16 years of age. Natural logarithmic values of lung function and standing height were used in the final regression model. RESULTS: Prediction equations for forced vital capacity (FVC), forced expiratory volume in 1 s (FEV(1)), FEV(1)/FVC x 100, maximum mid expiratory flow (MMEF 25-75%) and peak expiratory flow (PEF) for both sexes are presented with standing height as the dependent variable. Our data show a significant increase in lung function with standing height in both sexes. Comparing our results with recent data, values of FVC and FEV(1) in both sexes in the present study are close to those in European, white US and Asian children, whereas our values are higher than the Libyan ones. CONCLUSIONS: Healthy Tunisian children showed similar spirometric reference values compared to European, white US and Asian children. Thus, these standards of lung function could also be used in Tunisia.     

Spirometric reference values for white European children and adolescents: Polgar revisited

We analyzed six spirometric data sets collected in the Netherlands, Austria, the United Kingdom, Spain, and Italy. The objectives were to establish whether (1) it was possible to describe spirometric indices from childhood to adulthood, taking into account the adolescent growth spurt, and (2) there are systematic differences in ventilatory function between children and adolescents in different parts of Western Europe. The study comprised 2,269 girls and 3,592 boys, aged 6–21 years. The range in standing height was 110–185 in girls, 110–205 in boys. The model applicable to all data sets was In FVC or In FEV₁ = a + (b + c · A)· H, where H = standing height and A = age; this model prevents the phase shift between the adolescent growth spurt in length and lung volume from leading to an age-dependent bias in predicted values. There was surprising agreement between most of the data sets; systematic differences are probably due to technical factors arising from ATPS-BTPS corrections and from defining the end of breath with pneumotachometer systems. Taking those into account, prediction equations for FVC, FEV₁, and FEV₁%FVC were developed with “lower limits of normal” which should be applicable to children and adolescents of European descent. It is proposed that the approach of analyzing available data sets should also be applied to other ventilatory indices, data collected in adults and elderly subjects, or in other ethnic groups, and that an international data base be set up to that end. © 1995 Wiley-Liss, Inc.     

Spirometric reference values in a large Middle Eastern population.

Ethnic differences in pulmonary function have been frequently reported. The purposes of this study were to derive equations for the prediction of normative spirometry values for a large population of Persians in Isfahan and compare them to reference values from a White Euro-USA population. Spirometry measurements were obtained from 4,341 randomly selected healthy nonsmoker subjects in Isfahan, Iran, utilising American Thoracic Society guidelines and a vigorous quality assurance program. Measured data from 3,213 subjects were analysed using multiple regression techniques to derive prediction equations for spirometric variables; the remaining 1,128 subjects were used as a control group to test the validity of the derived equations. In addition, predicted values were compared with values derived from recently published equations for the USA. Derived prediction equations showed good performance for most spirometric parameters. Compared with USA Whites, adult Persians have minimally lower forced vital capacities, while the values for children are close to USA Whites. In comparison with reference equations based on European or USA populations, local reference values are more biologically and technically suitable for the interpretation of spirometric data from Iranian populations.     

Functional exercise for older adults

Australia's population is aging. Recent figures released by the Australian Bureau of Statistics indicate that by the year 2013, 3.1 million people will be over the age of 65 as compared with 2.1 million in 1993. This trend is projected to continue well into the 21st century, and has important implications for health and fitness professionals. Age related decline in muscle power predicts falls, motor impairment and disability. The author suggests that training programs should be tailored to maximise muscle power. Explosive heavy resistance training is safe and well tolerated in healthy adults even in the eighth decade of life and elicits adaptive neuromuscular changes in physiological variables that are commonly associated with the risk of falls and disability in aged individuals.     

The prevalence and risk factors for sarcopenia in older adults and long-living older adults

PurposeSarcopenia is a muscular syndrome that is related to several adverse risks. The present study aimed to evaluate the prevalence of risk of sarcopenia and associated factors in older adults and long-living older adults.MethodsA crosssectional epidemiological study of older adults patients at a geriatric outpatient clinic. The older adults were evaluated for sarcopenia risk using the SARC-F questionnaire supplemented with the measurement of the calf circumference. In addition, nutritional status was characterized using the Mini Nutritional Assessment, and the relationship of sarcopenia with associated factors (comorbidities, polypharmacy, smoking).ResultsA total of 100 eligible older adults with a mean age of 77.2 ± 1.8 years in the older adults and 86.3 ± 4.2 years in the long-living older adults (p < 0.001) were evaluated. The long-living older adults (OR = 6.1; 95 % CI: 1.44–16.09; p = 0.01) and older adults at risk of malnutrition (OR = 13.6; 95 % CI: 1.55–11.38; p < 0.05) had a higher risk of sarcopenia, whereas BMI ≥ 27 kg/m 2 (OR = 0; 95 % CI: 0–0.06; p < 0.001) was a protective factor. The risk of sarcopenia was six times higher in the over-80 s (95 % CI = 1.44, 16.09), while the older adults with malnutrition or at nutritional risk ran a 13 times higher risk of sarcopenia (95 % CI = 1.55, 11.38).ConclusionThe prevalence of risk of sarcopenia was higher in the long-living older adults and the older adults at nutritional risk, making its early evaluation in clinical practice important.     

Coping-with-hearing-loss model for older adults.

We proposed a coping-with-hearing-loss model that explains how hearing loss, psychosocial factors (i.e., attitudes about aging, personal adjustment to hearing loss, and perceived social support), and perceived strategy effectiveness affect the use of adaptive and maladaptive strategies. Adaptive strategies are behaviors that improve communication (i.e., asking others to repeat). Maladaptive strategies are coping behaviors that do not promote communication (i.e., pretending to understand the conversation). Nonaudiological variables were more important than physical hearing loss (as measured by an audiological examination) in predicting coping behaviors for hearing loss. The use of adaptive strategies was predicted by perceived strategy effectiveness. The use of maladaptive strategies was predicted by perceived effectiveness of the strategies to cope with hearing loss in daily life, poor adjustment to hearing loss, and poor social support. The results suggest that psychosocial issues may need to be addressed when older adults have difficulties coping with their hearing loss.