Low Peak Inspiratory Flow Rates are Common Among COPD Inpatients and are Associated with Increased Healthcare Resource Utilization: A Retrospective Cohort Study.

Background: Patients with chronic obstructive pulmonary disease (COPD) can have low peak inspiratory flow (PIF), especially after hospitalization for acute exacerbation of COPD (AECOPD). Purpose: To characterize patients hospitalized for AECOPD, and to assess the prevalence of low PIF, changes in PIF after hospitalization, and the association of low PIF with healthcare resource utilization (HRU) outcomes. Patients and
Methods: A retrospective cohort study was conducted using electronic health record data of hospitalized COPD patients in the Wake Forest Baptist Health system (01/01/2017 through 06/30/2020). Patients with a first eligible AECOPD hospitalization (index hospitalization) who were discharged before 05/31/2020 were included. PIF was measured using the In-Check DIAL™ at both medium-low resistance (R-2) and high resistance (R-5) during the index hospitalization. For R-2 and R-5, PIF was divided into low PIF (< 60 L/min; < 30 L/min) and high PIF (≥ 60 L/min; ≥ 30 L/min) groups. The primary outcome was the prevalence of low PIF. The stability of PIF after hospitalization was described. Adjusted regression models evaluated associations between low PIF and subsequent 30-day readmissions, 90-day readmissions, and HRU outcomes, including hospitalizations, emergency department visits, inpatient days, and intensive care unit (ICU) days.
Results: In total, 743 patients with PIF measured at R-2 and R-5 during a AECOPD hospitalization were included. The prevalence of low PIF was 56.9% at R-2 and 14.7% at R-5. PIF values were relatively stable after hospitalization. Adjusted analyses showed significant increases in HRU (all-cause hospitalizations [31%], COPD hospitalizations [33%], COPD inpatient days [46%], and COPD ICU days [24%]) during the follow-up period among patients with low PIF (< 60 L/min) at R-2. The 30- and 90-day readmission risks were similar between patients with low PIF and high PIF.
Conclusion: Low PIF is common among patients hospitalized for AECOPD, relatively stable after hospital discharge, and associated with increased HRU.

Plain Language Summary

Patients with chronic obstructive pulmonary disease (COPD) have difficulty breathing, and worsening of symptoms can require hospitalization. They are often discharged from the hospital and provided with medications delivered by a dry powder inhaler, which is affected by peak inspiratory flow (PIF). This study examined the rates of airflow that patients with COPD could achieve while inhaling, using a device that measured PIF at different resistance levels, during hospitalization for an exacerbation of COPD. We aimed to identify the percentage of patients who could not achieve high PIF rates and assess their characteristics. We also observed the stability of PIF after hospitalization and evaluated associations between PIF and rates of healthcare visits after hospitalization.

This single-center study used electronic health record data from 743 patients hospitalized for COPD exacerbations between January 2017 and June 2020. Patients were categorized based on PIF measured at first hospitalization. PIF data collected after hospitalization during follow-up visits were also used for analysis. More than half (57%) of the patients had a low PIF of less than 60 liters per minute (L/min) when measured at medium-low resistance, and 15% had a low PIF of less than 30 L/min when measured at the high-resistance setting. Patients who could not achieve a PIF of at least 60 L/min at the medium-low resistance setting were found to have significantly more hospitalizations during the follow-up period, both all-cause hospitalizations (31%) and COPD hospitalizations (33%). These findings indicate that patients hospitalized for COPD often had low PIF, which was associated with higher rates of future hospitalization.

Introduction

Chronic lower respiratory diseases, including chronic obstructive pulmonary disease (COPD), were the fourth most common cause of death in the US in 2019 and are associated with significant morbidity, as well as substantial economic and social burdens.1,2 The main goals of treatment for COPD are reduction of symptoms and future risk of acute exacerbations of COPD (AECOPD), which the Global Initiative for Chronic Obstructive Lung Disease (GOLD) defines as an acute worsening of respiratory symptoms that result in additional therapy.3 One type of maintenance treatment modality for COPD is the use of dry powder inhalers (DPIs); while simpler to use than most other devices, DPIs are breath-actuated and require fast and hard inhalations to optimally release medication.4

Peak inspiratory flow (PIF) rate is defined as the maximal airflow (in liters per minute) achieved during a forced inspiratory maneuver.5,6 PIF rates required for the ideal delivery of medication from commonly used DPIs are published and have previously been termed “optimal PIF”.5,7 These depend upon the internal resistance of DPIs, thus varying among device brands. PIF rates below these thresholds have been defined as “suboptimal PIF”; however, the exact threshold values defining minimal effective PIFs remain under debate.5 In several reports, low PIF has been associated with poor drug delivery and inadequate drug de-aggregation.5,8–11 Two gamma scintillography trials further demonstrated that when using the Turbuhaler® powder inhaler, higher PIF was associated with improved lung deposition.12,13 Patients with COPD commonly have low PIF, especially during hospitalization for AECOPD.4,14 The prevalence of low PIF in COPD ranges from 32% to 52% in patients hospitalized for AECOPD,4 and low PIF is most prevalent among the elderly, women, and patients with a small stature or lung hyperinflation.6,15

Data on whether patients with COPD can achieve a clinical benefit using a DPI if they have low PIF are limited.4,14,16 In a randomized cross-over study in patients with low PIF (< 60 L/min), the use of a nebulized bronchodilator was associated with a higher forced expiratory volume in 1 second (FEV1) than the use of a DPI after 30 minutes, but not after 2 hours.17 In a phase 3b trial, use of a nebulized bronchodilator in patients with low PIF (< 60 L/min) produced numerically greater improvements from baseline in trough FEV1 compared with a DPI.18 One retrospective study of patients hospitalized for AECOPD showed that compared with patients with high PIF, those with low PIF had a significant increase in 90-day COPD readmissions and a shorter time to all-cause and COPD readmissions.14 However, a prospective observational study showed contrasting results.19 Thus, while it has been demonstrated that low PIF is associated with decreased drug delivery in vitro, there is a lack of clinical data showing whether low PIF is associated with poor patient outcomes and subsequent increases in healthcare resource utilization (HRU).

This study aimed to identify the prevalence of low PIF in a real-world population of patients hospitalized for AECOPD and to assess their demographic, clinical, and treatment characteristics, by PIF status. We also characterized the stability of PIF after hospitalization and evaluated potential associations between low PIF and HRU.

Patients and Methods

Study Design and Population

This retrospective, observational cohort study used electronic health record data from patients in the Wake Forest Baptist Health (WFBH) integrated health system between January 1, 2017, and June 30, 2020. In 2014, WFBH established a care plan for AECOPD hospitalizations that was found to reduce readmissions from occurring within 30 days of discharge; in 2018, it began measuring PIF using the In-Check DIAL™ at 2 different resistance settings (medium-low [R-2] and high [R-5]) as a component of the care plan.14,20 The In-Check DIAL™ imposes resistance to mimic different DPIs according to their internal resistance. R-2 DPIs include Accuhaler®, Diskhaler®, and Ellipta®, and R-5 DPIs include Easyhaler M® and Handihaler®. PIF was measured regardless of current inhaler use in patients hospitalized for AECOPD, as part of their outpatient post-discharge follow-up visit, as well as on initial assessment at pulmonary rehabilitation.20 Measurements were recorded by trained respiratory therapists at least once during hospital admission when patients were no longer in respiratory distress, able to complete a full sentence, and not using accessory muscles of respiration. Seated patients were told to inhale from functional residual capacity as fast and as hard as they could into the device; the best of 3 efforts was considered.

Eligible patients, aged ≥ 40 years, had ≥ 1 PIF measured using In-Check DIAL™ (Clement Clarke International Ltd, Harlow, UK and Alliance Tech Medical, Granbury, TX, USA) at both R-2 and R-5 during an AECOPD hospitalization. Patients were excluded if they had a diagnosis of cystic fibrosis or alpha-1 antitrypsin deficiency. Only the first eligible COPD hospitalization for each patient with a date of discharge prior to May 31, 2020, was included and used as the index hospitalization, defined as the first hospitalization in which PIF measurements by In-Check DIAL™ at the R-2 and R-5 levels of resistance were obtained. Patients were followed from the index hospitalization discharge date until 1 year, death, or study end (June 30, 2020), whichever occurred first.

Patient characteristics and COPD treatments were assessed on or before the index hospitalization discharge date. Relevant diagnoses and other clinical characteristics were identified using International Classification of Diseases 9th or 10th revision, clinical modification (ICD-9/10-CM) codes (). Baseline HRU was measured during the baseline period, defined as 1 year prior to the index hospitalization discharge date. eFrailty scores21 were available for patients aged ≥ 65 years who had the minimum number of elements necessary for score calculation. The Social Deprivation Index (SDI), a composite measure of area-level deprivation based on the demographic characteristics collected in the American Community Survey, was computed according to US census ZIP Code Tabulation Areas from 5-digit ZIP codes22 as a measure of the social determinants of health. Mortality data from the North Carolina (NC) State Center for Health Statistics were linked to the study database using a deterministic algorithm that utilizes name, sex, race, and date of birth and was used to censor patient follow-up.

Variables and Outcomes

The primary outcome was low PIF prevalence in the overall cohort. PIF measurements were dichotomized into low PIF and high PIF groups, separately for both R-2 and R-5, by PIF values obtained during the index hospitalization closest to the discharge date. Low PIF was defined as < 60 L/min and < 30 L/min for R-2 and R-5, respectively. High PIF was defined as ≥ 60 L/min and ≥ 30 L/min for R-2 and R-5, respectively.

PIF measurements after discharge from the index hospitalization, either in outpatient pulmonary clinics or during rehospitalizations, were available for subsets of patients and were used to explore the stability of PIF over time. Patients may have multiple PIF measurements on separate days during the post-discharge follow-up assessment period.

HRU outcomes during the follow-up period included 30-day all-cause readmissions, 90-day all-cause and disease-specific readmissions, and all-cause and disease-specific rates of inpatient hospitalizations, emergency department visits, inpatient days (length of stay [LOS]), and intensive care unit (ICU) days. Disease-specific outcomes included COPD and composite COPD or pneumonia events. COPD events were defined as the presence of a primary diagnosis of COPD or a primary diagnosis of acute respiratory failure plus a secondary diagnosis of COPD. Pneumonia events were defined as the presence of a primary diagnosis of pneumonia or a primary diagnosis of sepsis with a secondary diagnosis of pneumonia and no secondary diagnosis of severe sepsis present on admission ().

Statistical Analysis

Descriptive statistics summarized low PIF prevalence, patient demographics, and clinical characteristics. Student’s t-test and chi-square test were used to evaluate the differences in patient characteristics between PIF groups. Among subsets of patients with PIF measured after discharge from the index admission (eg, during readmission within 30 days), the proportion of patients who did not change PIF group (from low PIF to high PIF, or vice versa) was reported. Median (minimum, maximum) PIFs were plotted over time, according to PIF group at index (low PIF or high PIF), for the subsets of patients with PIF measured during specified time intervals over 1 year after discharge (eg, 30 to 60 days).

Poisson regression was used to assess the association between low PIF and incidence rates of HRU outcomes over the follow-up period. The offset term was the logarithm of person-years at risk. Person-years was used to accommodate the differences in at-risk time due to death or reaching the end of the study data. Multivariable logistic regression was used to assess the association between low PIF at index hospitalization and subsequent 30-day all-cause readmissions. Cox proportional hazards models were used to assess the association between low PIF and time to first readmission within 90 days of discharge from the index hospitalization. Separate models were developed for all-cause and disease-specific readmissions. Mortality data were used as a right censor for 90-day readmissions. Patients with ZIP codes outside of NC were excluded from the analysis of 30-day readmissions since any deaths occurring in this population would not be captured by the state death index, as were patients who died within 30 days of hospital discharge.

Regression models were adjusted for covariates including age, sex, race, Charlson Comorbidity Index score, number of all-cause admissions in the year prior to the index admission, body mass index, LOS for the index admission, and SDI. Due to small numbers of patients in the “other” race categories, it was necessary to simplify race as a binary variable (White vs other) for the regression models. Restricted cubic splines were included with each of the continuous variables to relax the linearity assumptions of the models. Splines were removed from variables in which the nonlinear components were not statistically significant. Missing data were reported for each variable. Body mass index was manually extracted from the electronic health record for a small number of patients where necessary. Variables with missing data were excluded from the regression analysis. All analyses were performed in R Studio (version 4.0.3).

Results

Patient Population

The study cohort included 743 patients with PIF measured at both R-2 and R-5 during the index hospitalization. Reasons for patient exclusion are given in Figure 1. Patient demographics and clinical characteristics are presented in Table 1. The median (interquartile range) age was 66.10 (59.65, 73.55) years, and 49.9% of patients were female. Compared with patients with high PIF, patients with low PIF had a higher median age, had a lower median body mass index, and were more often female. There was no significant difference between the low PIF and high PIF groups in eFrailty Index scores. GOLD status based on percent predicted FEV1 was only available in 46% of patients at baseline (Table 1). Maintenance COPD medications prescribed upon discharge from the index hospitalization were similar across PIF groups, with most patients prescribed triple therapy (long-acting muscarinic antagonist [LAMA] + long-acting beta2-agonist [LABA] + inhaled corticosteroid) (). Over 65% of patients were prescribed at least one DPI at discharge. In the year prior to the index hospitalization, the median number of hospital inpatient admissions and ICU days were similar between patients with low PIF and high PIF (all P > 0.05). During the index hospitalization, patients with low PIF had a significantly longer median LOS (R-2, P < 0.001; R-5, P < 0.001) than patients with high PIF, and significantly more patients with low PIF were admitted to the ICU (R-2, P = 0.001; R-5, P = 0.002) (Table 2).

Figure 1

Patient flowchart.

Table 1

Baseline Demographics and Clinical Characteristics by PIF Group

	R-2			R-5
	Low PIF < 60 L/min (n = 423)	High PIF ≥ 60 L/min (n = 320)	P value	Low PIF < 30 L/min (n = 109)	High PIF ≥ 30 L/min (n = 634)	P value
Age (years), median (IQR)	67.20 (60.80, 74.55)	64.70 (57.80, 72.62)	< 0.001	69.00 (63.30, 76.90)	65.60 (59.20, 73.27)	0.001
Sex, female, n (%)	229 (54.1)	142 (44.4)	0.01	66 (60.6)	305 (48.1)	0.022
BMI (kg/m2), median (IQR)	25.76 (20.70, 31.64)	27.10 (22.39, 33.12)	0.009	23.68 (19.49, 29.39)	26.72 (21.85, 32.62)	< 0.001
eFrailty Index, median (IQR)	0.19 (0.14, 0.25)	0.19 (0.14, 0.25)	0.79	0.19 (0.15, 0.26)	0.19 (0.14, 0.25)	0.437
Missing, n	137	110		208	39
Race, n (%)			0.592			0.604
White	330 (78.0)	257 (80.3)		83 (76.1)	504 (79.5)
Black	86 (20.3)	60 (18.8)		25 (22.9)	121 (19.1)
Other	7 (1.7)	3 (0.9)		1 (0.9)	9 (1.4)
Charlson Comorbidity Index, median (IQR)	4.00 (2.00, 7.00)	3.00 (2.00, 7.00)	0.566	4.00 (2.00, 8.00)	3.50 (2.00, 7.00)	0.516
CAT score, median (IQR)	25.00 (18.00, 31.00)	24.00 (17.00, 31.00)	0.408	27.00 (20.50, 33.00)	24.00 (17.00, 31.00)	0.011
Missing, n (%)	46 (10.9)	35 (10.9)		10 (9.2)	71 (11.2)
SDI, median (IQR)	65.00 (54.00, 77.50)	70.00 (57.00, 78.00)	0.097	68.00 (57.00, 78.00)	66.00 (55.00, 78.00)	0.64
GOLD categorya, n (%)			0.036			0.215
I (FEV1 ≥ 80% predicted)	9 (2.1)	5 (1.6)		2 (1.8)	12 (1.9)
II (50% ≤ FEV1 < 80% predicted)	65 (15.4)	68 (21.2)		12 (11.0)	121 (19.1)
III (30% ≤ FEV1 < 50% predicted)	80 (18.9)	61 (19.1)		20 (18.3)	121 (19.1)
IV (FEV1< 30% predicted.)	38 (9.0)	13 (4.1)		11 (10.1)	40 (6.3)
Missing	231 (54.6)	173 (54.1)		64 (58.7)	340 (53.6)

Notes: aGOLD status (I–IV): based on FEV1% predicted from outpatient pulmonary function tests measured during the 1-year baseline period through 30 days after the index date. GOLD I (mild): FEV1 ≥ 80% predicted; GOLD II (moderate): 50% ≤ FEV1 < 80% predicted; GOLD III (severe): 30% ≤ FEV1 < 50% predicted; GOLD IV (very severe): FEV1< 30% predicted.

Abbreviations: BMI, body mass index; CAT, Chronic Obstructive Pulmonary Disease Assessment Test; FEV1, forced expiratory volume in one second; GOLD, Global Initiative for Chronic Obstructive Lung Disease; IQR, interquartile range; PIF, peak inspiratory flow; R-2, medium-low resistance; R-5, high resistance; SDI, Social Deprivation Index.

Table 2

Baseline and Index HRU by PIF Group

	R-2			R-5
	Low PIF < 60 L/min (n = 423)	High PIF ≥ 60 L/min (n = 320)	P value	Low PIF < 30 L/min (n = 109)	High PIF ≥ 30 L/min (n = 634)	P value
During index hospitalization
LOS (days), median (IQR)	4.99 (3.30, 8.00)	3.98 (2.81, 5.84)	< 0.001	6.37 (4.04, 10.15)	4.19 (2.93, 6.54)	< 0.001
ICU visit during admission, n (%)	155 (36.6)	81 (25.3)	0.001	49 (45.0)	187 (29.5)	0.002
ICU LOS (days), median (IQR)	0.00 (0.00, 1.98)	0.00 (0.00, 0.53)	0.001	0.00 (0.00, 2.48)	0.00 (0.00, 1.25)	0.001
Time from PIF to discharge (days), median (IQR)	2.24 (1.18, 4.27)	1.94 (1.00, 3.13)	< 0.001	3.19 (1.24, 5.21)	2.07 (1.10, 3.34)	< 0.001
In the year before index hospitalization
Inpatient hospitalizations, median (IQR)	1.00 (0.00, 2.00)	1.00 (0.00, 2.00)	0.473	1.00 (0.00, 2.00)	1.00 (0.00, 2.00)	0.846
ICU days, median (IQR)	0.00 (0.00, 0.00)	0.00 (0.00, 0.00)	0.413	0.00 (0.00, 0.00)	0.00 (0.00, 0.00)	0.056

Abbreviations: HRU, healthcare resource utilization; ICU, intensive care unit; IQR, interquartile range; LOS, length of stay; PIF, peak inspiratory flow; R-2, medium-low resistance; R-5, high resistance.

Prevalence of Low PIF

Approximately half of the patients (56.9%; n = 423) had low PIF (< 60 L/min) for R-2 and 14.7% (n = 109) had low PIF (< 30 L/min) for R-5 during their index hospitalization. The median (minimum–maximum) PIF was 50 (15–110) L/min for patients at R-2 and 40 (15–100) L/min for those at R-5 ().

Healthcare Resource Utilization

The person-years of follow-up was 280.1 in the low PIF R-2 group and 225.0 in the high PIF R-2 group. Adjusted analyses showed low PIF at R-2 was associated with significant increases in rates of HRU outcomes, including all-cause hospitalizations (31%), COPD hospitalizations (33%), COPD inpatient days (46%), and COPD ICU days (24%) during the follow-up period (Table 3).

Table 3

Incidence Rates and Unadjusted and Adjusted IRRs for HRU Outcomes During Follow-Upa

Outcomes	R-2 Low PIF < 60 L/min Cohort (n = 404)			R-2 High PIF ≥ 60 L/min Cohort (n = 300)
	n Events	PY	Events/PY	n Events	PY	Events/PY	IRR Crude (95% CI)	Adjusted IRR (95% CI)
All-cause hospitalization	400.0	280.1	1.43	237.0	225.0	1.05	1.36 (1.16–1.59)	1.31 (1.11–1.55)
COPD hospitalization	193.0	280.1	0.69	113.0	225.0	0.50	1.37 (1.09–1.74)	1.33 (1.05–1.69)
COPD or pneumonia hospitalization	222.0	280.1	0.79	132.0	225.0	0.59	1.35 (1.09–1.68)	1.30 (1.05–1.63)
All-cause inpatient days	2067.2	280.1	7.38	1144.6	225.0	5.09	1.45 (1.35–1.56)	1.39 (1.29–1.5)
COPD inpatient days	1052.4	280.1	3.76	554.8	225.0	2.47	1.52 (1.38–1.69)	1.46 (1.32–1.63)
COPD or pneumonia inpatient days	1210.1	280.1	4.32	660.8	225.0	2.94	1.47 (1.34–1.62)	1.42 (1.29–1.57)
All-cause ICU days	511.2	280.1	1.83	254.9	225.0	1.13	1.08 (0.93–1.26)	1.31 (1.11–1.55)
COPD ICU days	297.6	280.1	1.06	188.8	225.0	0.84	1.27 (1.06–1.52)	1.24 (1.02–1.49)
COPD or pneumonia ICU days	328.8	280.1	1.17	209.3	225.0	0.93	1.26 (1.06–1.5)	1.2 (1.01–1.44)
COPD ED visits	249.0	280.1	0.89	162.0	225.0	0.72	1.23 (1.01–1.51)	1.24 (1.01–1.52)
COPD or pneumonia ED visits	287.0	280.1	1.02	185.0	225.0	0.82	1.25 (1.04–1.5)	1.25 (1.03–1.51)

Note: a39 patients with addresses outside NC were excluded from this analysis.

Abbreviations: CI, confidence interval; COPD, chronic obstructive pulmonary disease; ED, emergency department; HRU, healthcare resource utilization; ICU, intensive care unit; IRR, incidence risk ratio; NC, North Carolina; PY, person-years; R-2, medium-low resistance.

A total of 686 patients had ZIP codes within NC and were eligible for the 30-day readmission analysis. The adjusted odds ratio (OR) showed numerically increased odds of 30-day all-cause readmissions for patients with low PIF at R-2 compared with patients with high PIF at R-2 (OR: 1.28; 95% confidence interval [CI]: 0.76–2.15), but the result was not statistically significant. The adjusted Cox proportional hazard ratio (HR) showed similar 90-day all-cause readmissions for patients with R-2 low PIF vs high PIF (adjusted HR: 1.22; 95% CI: 0.88–1.71). Adjusted HRs also showed similar 90-day COPD readmissions and 90-day COPD/pneumonia readmissions between groups (HR: 1.14; 95% CI: 0.75–1.73 and HR: 1.06; 95% CI: 0.70–1.59).

The HRU outcomes for R-5 PIF groups are generally consistent with those of the R-2 PIF groups (). Similarly, no statistically significant association was found between low PIF at R-5 and readmission outcomes.

Stability of PIF

PIF was measured in an outpatient pulmonary clinic within 30 days of index hospitalization discharge in 229 patients (30.8%). Of these, over 94% and 97% did not change R-2 and R-5 PIF groups from index, respectively. Similar patterns were seen in the 165 patients who had PIF measured during an all-cause readmission within 90 days of discharge from index hospitalization (). Median PIF, according to index PIF groups (low PIF and high PIF), was plotted for the subsets of patients with PIF remeasured during specified time intervals up to 1 year after index (Figure 2A and B).

Figure 2

Median (minimum and maximum) PIFs in the year after the index admission by index PIF group. (A) PIFR R-2 measured over a year after the index admission; (B) PIFR R-5 measured over a year after the index admission.

Discussion

This retrospective observational study showed that low PIF is common during hospitalizations for AECOPD and that PIF status appeared relatively stable after hospital discharge. Compared with high PIF, low PIF was associated with increased subsequent HRU, including all-cause and COPD-related admissions, LOS, ICU days, and emergency department visits. Adjusted analyses showed that hospital readmissions in the 30 and 90 days after index, however, were statistically similar between the low PIF and high PIF groups. To the best of our knowledge, this is the first study showing an association between low PIF and increased HRU in real-world clinical practice. While low PIF has been shown to be associated with reduced drug delivery in vitro, decreased bronchodilator effect in vivo, and possible increased readmission after AECOPD, the impact of low PIF on outcomes such as LOS, ICU days, and other HRU measures has not been widely evaluated.5,8–10,12,14,17–19

PIF has been shown to affect drug delivery, drug de-aggregation, and particle size in vitro.4 The relationship between PIF and drug delivery is not linear but hyperbolic.23 This leads to greater differences in drug delivery per increment of PIF change at the lower end than at the upper end of the PIF spectrum. Therefore, even small decreases in the PIF below the minimal effective PIF, as published by device manufacturers, may lead to significant reductions in drug delivery.

In vivo, low PIF is associated with a decreased bronchodilator effect.18 Use of the nebulized LAMA revefenacin resulted in greater improvement in trough FEV1 compared with use of the dry powder LAMA tiotropium in patients with low PIF.18 Mahler et al showed similar results with the nebulized LABA arformoterol compared with the dry powder LABA salmeterol in patients with low PIF.17 Two studies have examined the effect of low PIF on hospital readmissions after AECOPD.14,19 The first, which measured PIF against no resistance (In-Check DIAL™ R-0), showed a significant association between low PIF and readmission.14 However, the second study, which measured PIF against the simulated resistance of the DISKUS® DPI (In-Check DIAL™ R-2), did not, which was aligned with the findings of our study.19 Compared with the study by Sharma et al,19 our study had a larger sample size and readmission analysis was adjusted for potential confounders. Our study did not show a statistically significant association between low PIF and 30- or 90-day readmissions; however, we observed an association between low PIF and several measures of HRU, including rates of hospitalizations, emergency department visits, and inpatient and ICU days. These findings are essential to clinical practice and health policy evaluations, as AECOPD is responsible for up to 70% of COPD-related healthcare costs, with hospital readmissions alone costing over $15 billion annually in direct costs.2

The association of low PIF with HRU is important. However, whether this relationship is causal and, if so, what the causal link could be is unknown. An important consideration of our study is that we did not define low PIF relative to patient’s current DPI use, because the lack of insurance claims data availability limited the assessment of medication/inhaler use during the follow-up period. However, over 65% of the patients in our study were prescribed at least one DPI at the time of discharge from the index admission, and low PIF was associated with increased HRU after discharge. Low PIF has been associated with age, female sex, small stature, and lung function impairment.6,15 Elderly women with a small stature and impaired lung function are more likely to have low PIF and to be considered frail,6,15 and frailty is linked with increased HRU.24 Although limited, our frailty data suggest that the link between low PIF and greater HRU may not be related to frailty.

In this study, 57% of patients had low PIF for an R-2 inhaler and 15% for an R-5 inhaler. These seemingly divergent values may be explained by the work of Barnes et al who showed that a PIF of 60 L/min against an R-2 resistance is roughly equivalent to a PIF of 40 L/min against an R-5 resistance.25 In exploring the distribution of PIF in this study, we found that 49% of patients had a PIF < 40 L/min against an R-5 resistance, thereby confirming the work of Barnes et al and aligning the low PIF threshold for R-2 and R-5 resistances.

For the subset of patients with PIF measured during a readmission within 90 days of index or at outpatient pulmonary clinic within 30 days, less than 6% changed their PIF group, indicating that PIF is relatively stable after hospitalization. However, it should be noted that in our study, the PIF for the index hospitalization was measured close to the discharge date when patients were no longer in respiratory distress. Although lung function deteriorates during AECOPD, PIF and inhalation volume increase during early recovery up to the stable stage.11,26

This study was conducted at a single health center; therefore, the generalizability of the results is limited. However, the prevalence of low PIF was consistent with that seen in other studies of PIF in COPD.14,15,27–30 Additionally, the retrospective and uncontrolled nature of this study is prone to inherent bias and limitations. We were unable to use SDI at the census block group level due to the inability to geocode some addresses, leading us to link SDI at the 5-digit ZIP code level instead. Although informative, the eFrailty Index was not included as a covariate since it is only designed for use in patients ≥ 65 years of age. Therefore, the authors relied on the less precise Charlson Comorbidity Index score as a measure of comorbidity. Loss to follow-up is also a concern for retrospective cohort studies, particularly in our study which used electronic medical record data alone. It is unknown if patients sought care elsewhere. However, our use of the NC state death registry should have reduced the potential bias introduced by loss to follow-up due to patient demise. The registry identifies deaths for NC residents regardless of where the deaths occur. Observational COPD studies are also potentially biased due to inaccurate COPD diagnoses based on ICD codes. One strength of this study is that all patients included were evaluated by respiratory therapists during index admission and deemed appropriate for inclusion in the COPD care pathway. A prospective design would be useful in validating these data and should be considered for further investigation.

DPIs require certain inspiratory force (flow, duration, and initiation of flow) to disperse, de-aggregate, and distribute the drug deep into distal airways.31 Therefore, future work exploring whether the association of low PIF with greater HRU is tied to DPI use would be of interest. This important question may best be answered with a prospective randomized trial assigning patients with low PIF to DPI devices or non-DPI devices, such as metered dose inhalers, nebulized medication, or soft mist devices.

Conclusions

We have shown that low PIF is common among patients hospitalized for COPD, relatively stable after hospital discharge, and associated with greater HRU. Our real-world evidence findings support clinical practice recommendations and health policy decisions considering the prevalence of low PIF and subsequent HRU among patients with AECOPD.