The Difference Between Slow and Forced Vital Capacity Increases With Increasing Body Mass Index: A Paradoxical Difference in Low and Normal Body Mass Indices

Discussion

Our study reveals that the difference between FVC and other measurements of VC depends on BMI. In individuals with a BMI < 25 kg/m² who do not have obstruction (defined as FEV₁/FVC ratio lower than LLN), FVC is larger than SVC. In contrast, in overweight and obese individuals, SVC is larger than FVC, and the SVC-FVC difference is positively correlated with BMI. To our knowledge, this is the first report of BMI influencing the difference between SVC and FVC. This discordance could lead to a falsely lower rate of OAD diagnosis when using FEV₁/FVC in overweight and obese individuals.

The discordance between FVC and other measurements of VC has been reported previously.¹² It has been suggested that the difference between VC (measured either as SVC or inspiratory VC) and FVC reflects small airway obstruction.^13,14 Individuals with OAD may have a substantially reduced FVC compared with SVC (the accepted standard measurement of VC). This difference could result in a falsely normal FEV₁/FVC ratio, leading to underdiagnosis of OAD.² For this reason, the ATS/ERS task force recommends the use of FEV₁/SVC instead of FEV₁/FVC.¹

Several authorities have reported the effect of weight on VC.^5,6 The VC decreases with increasing BMI. Obesity reduces lung compliance,¹⁵ and, as a consequence, it decreases VC. Its effect on chest wall compliance varies in different studies,^16–18 and some authors have reported normal chest wall compliance.^16,17,19 Moreover, it results in airway closure, pulmonary gas trapping, diffuse microatelectasis, and relatively increased intrathoracic blood volume and, thereby, an increase in respiratory system elastance.⁷ In addition, reduced VC may result from OAD in obese individuals.²⁰ Several studies report that obesity is associated with OAD, but such an association is still unclear.^21,22

FVC may be also reduced more than SVC in obesity due to airway closure and this discrepancy increases further in OAD.² In our cohort, the SVC was always larger than FVC in subjects with obstruction based on a FEV₁/FVC ratio lower than the LLN. In subjects without obstruction using the same criteria, SVC was larger than FVC only in BMI > 25 kg/m², and their difference increases as a function of BMI (Fig. 1). Surprisingly, the FVC was larger than SVC in individuals with BMI < 25 kg/m² and no evidence of obstruction in their PFTs. Similarly, the FEV₁/FVC ratio was smaller than FEV₁/SVC in these individuals. To our knowledge, this paradoxical difference has not been reported previously and is most likely due to the use of different maneuvers. FVC requires not only a forced expiration but also a forced inspiration.⁹ A force inspiratory maneuver may lead to a larger inspiratory reserve volume only in normal weight individuals who have larger respiratory compliance compared with the overweight and obese.⁷ On the other hand, the SVC maneuver requires a slow inspiration.⁹ Another explanation could be that more individuals with OAD are in the category of BMI < 25 kg/m² in our cohort, as we did not have clinical information for these individuals. However, this is less likely, as the numbers in each category are large and we subcategorized the subjects based on the presence or absence of obstruction defined by FEV₁/FVC < LLN.

The fact that FVC is larger in BMI < 25 kg/m² and smaller than SVC in BMI > 25 kg/m² adds to the existing literature regarding the limitation of FEV₁/FVC to diagnose OAD in overweight and obese individuals.² Two people of the same age, sex, race, and height with different BMIs also have different FVC and FEV₁/FVC values, although they have the same predicted values based on Hankinson equations.¹¹ Because there are no available FEV₁/SVC predicted values, we computed the observed FEV₁/SVC percentage values based on the FEV₁/FVC predicted values.¹¹ Although we cannot conclude with certainty, as there are no predicted FEV₁/SVC values, our findings indicate that potentially 1 out of 10 patients (50 of 520, given that 520 individuals had obstruction based on FEV₁/SVC ratio) with normal FVC, most of them overweight or obese, might be erroneously diagnosed as “normal” despite their symptoms. Interestingly, 32 subjects with a normal FEV₁/SVC had an abnormally low FEV₁/FVC ratio; 16 of these subjects had a BMI < 25 kg/m,² whereas 9 were overweight.

The subject sample was racially homogenous (predominantly white), which limits the generalizability of our results to other racial and ethnic groups. Race was unspecified for a large number (1,416) of our subjects, although race was self-identified. The staff in our PFT laboratories performed the data entry in the PFT software. Our PFT software calculates the predicted values for unspecified using data for whites. Our staff know this information and often use unspecified instead of white. In some occasions, our staff may even prefer unspecified over white, as some of the patients have different racial origins. We have no way to identify in which cases the race was truly unspecified, but we assume that would be a small minority. Nevertheless, 85.3% of the local population is “white alone” according to 2010 American Census Bureau.²³ Another limitation of our study is that we did not have clinical data to correlate with the PFTs for all the subjects in our cohort.

Our findings lead us to question whether equations for predicted values of FVC and FEV₁/FVC should include BMI. This potentially is clinically relevant, as the obese and overweight constitute 69.2% of the total United States population.²⁴ Mannino et al²⁵ reported that individuals who have normal FEV₁/FVC ratio using the LLN criteria are at risk for early respiratory death if they have FEV₁/FVC ratio lower than 0.7. We suggest comparison of SVC with FVC should be used when there is doubt until equations of FEV₁/FVC that include BMI or FEV₁/SVC predicted values become available for the United States population.