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PLOS One logoLink to PLOS One
. 2017 Aug 16;12(8):e0181815. doi: 10.1371/journal.pone.0181815

Diabetes risks and outcomes in chronic obstructive pulmonary disease patients: Two nationwide population-based retrospective cohort studies

Chao-Shun Lin 1,2,3, Chih-Chung Liu 1,2,3, Chun-Chieh Yeh 4,5, Yi-Cheng Chang 6, Chi-Li Chung 7, Hsin-Long Lane 8, Chun-Chuan Shih 8, Ta-Liang Chen 1,2,3,#, Chien-Chang Liao 1,2,3,9,10,*,#
Editor: Yu Ru Kou11
PMCID: PMC5558949  PMID: 28813433

Abstract

Objective

The relationship between chronic obstructive pulmonary disease (COPD) and diabetes remains incompletely understood. This study evaluated diabetes risk and post-diabetes outcomes in COPD patients with and without exacerbations.

Methods

We identified 4671 adults newly diagnosed with COPD exacerbations and 9342 adults newly diagnosed with COPD without exacerbations during 2000–2008 using Taiwan’s National Health Insurance Research Database. A comparison cohort of 18684 adults without COPD, matched by age and sex, was randomly selected from the same dataset for the control group. Diabetes events during 2000–2013 were ascertained from medical claims during the follow-up period. Adjusted hazard ratios (HRs) and 95% confidence intervals (CIs) of diabetes associated with COPD with or without exacerbations were calculated. We conducted another nested cohort study of 395516 patients with diabetes hospitalization during 2002–2013 and calculated adjusted odds ratios (ORs) and 95% CIs of histories of COPD and COPD exacerbations associated with adverse events after diabetes admission.

Results

During the follow-up period, the incidences of diabetes for patients without COPD and for patients with COPD without or with exacerbations were 3.4, 4.1 and 7.4 per 1000 person-years, respectively (P < 0.0001). Increased risk of diabetes for patients with COPD without exacerbations (HR 1.09, 95% CI 1.02–1.17) and COPD with exacerbations (HR 2.18, 95% CI 1.88–2.52) was noted. Post-diabetes pneumonia (OR 3.28, 95% CI 3.13–3.43), intensive care admission (OR 1.32, 95% CI 1.26–1.39) and mortality (OR 2.06, 95% CI 1.88–2.25) were associated with COPD exacerbations.

Conclusion

Prevention and intervention strategies for diabetes and post-diabetes outcomes are needed for this susceptible population.

Introduction

In the United States, diabetes is one of the leading causes of adult death and disability. It also represents a large and rapidly growing economic burden, with an estimated cost of US$245 billion in 2012 [1,2]. Although diabetes’ epidemiology, pathogenesis, treatment guidelines and prevention programs have been well established over 204 years [3], it remains a pandemic disease that will reach an estimated global prevalence of 4.4% by 2030 [4].

Type 2 diabetes is considered a common comorbidity for patients with chronic obstructive pulmonary disease (COPD) and reduced lung function [510]. Epidemiological investigations show that diabetes is much more likely in patients with COPD than in control subjects [11,12]. A controversial population-based study using an Italian database found patients with COPD had an increased risk for diabetes compared to non-COPD subjects [13,14].

Although the association between COPD and diabetes risk was reported in previous studies [1116], the risk of diabetes for COPD patients in previous studies were limited by cross-sectional study design [1114], lack of adequate control subjects [1114], poor adjustment for potential confounders [15,16], short follow-up and incorrect selection of COPD cases [15]. The impact of COPD exacerbations on diabetic patients’ risk and outcomes is also unclear.

Based on the context described above, we hypothesized that patients with COPD may have increased the risk and adverse outcomes of diabetes. Using claims data from Taiwan’s National Health Research Database [6,7], we conducted a nationwide longitudinal cohort study to assess the risks of diabetes, post-diabetes mortality and complications in patients with COPD.

Methods

Source of data

Reimbursement claims used in this study were collected from the National Health Insurance Research Database. This insurance program was implemented in March 1995 and covers more than 99% of Taiwan’s 23 million residents. The National Health Research Institutes established this database to record beneficiaries’ medical services, including inpatient and outpatient demographic characteristics, physicians’ primary and secondary diagnoses, treatment procedures, prescriptions and medical expenditures. Research articles based on this database have been accepted in prominent scientific journals worldwide [6,7]. To protect personal privacy, the database was decoded and patient identifications were scrambled for further public access for this research. This study was evaluated and approved by the Joint Institutional Review Board of Taipei Medical University (TMU-JIRB-201605049) and E-DA Hospital (EDA-JIRB-2017004).

Study design and population

We used the National Health Insurance Research Database to perform two nationwide, population-based retrospective cohort studies. Using the database’s representative sample of one million beneficiaries, we conducted a retrospective cohort study of 9,342 COPD patients without exacerbations and 4671 patients with newly diagnosed COPD exacerbations with frequency matching by age and sex (COPD: COPDe = 2:1). We defined COPD patients as follows: people had at least two medical visits for outpatient care with physician’s primary diagnosis of COPD within one year. We defined patients with COPD exacerbations as follows: people received physician’s care due to COPD in the hospitalization ward or emergency room These definitions of COPD and COPD exacerbations were based on previous reports [1719,20,21]. For comparison, 18,684 frequency-matched individuals without COPD were selected (controls: COPDe = 4:1). These three cohorts, with subjects aged ≥40 years, were established between January 1, 2000, and December 31, 2005, and then followed until December 31, 2013. We calculated person-years during the follow-up period for each participant until diagnosis of diabetes or until censored because of death, withdrawal from the insurance system, or loss to follow-up. The non-COPD group included the remaining people who did not develop COPD during the follow-up period.

Using a diabetes cohort consisting of all incident diabetes patients among the total population of 23 million people from the National Health Insurance Research Database, we identified 395,516 new-onset diabetes patients hospitalized during 2000–2013. We compared sociodemographics, co-morbidities and medications for diabetes patients with no COPD, COPD, and COPDe. Risks of pneumonia, intensive care and mortality during diabetes admission were also estimated.

Measures and definition

We identified income status and defined low-income patients as those qualifying for waived medical copayment, which was verified by the Bureau of National Health Insurance. The International Classification of Diseases, Ninth Revision, Clinical Modification (ICD-9-CM) was used to define chronic obstructive pulmonary disease (ICD-9-CM 491, 492, 496) [17,18], diabetes (ICD-9-CM 250), co-morbidities and post-diabetes complications. Co-morbidities included hypertension (ICD-9-CM 401–405), mental disorders (ICD-9-CM 290–319), ischemic heart disease (ICD-9-CM 410–414), stroke (ICD-9-CM 430–438), liver cirrhosis (ICD-9-CM 571), hyperlipidemia (ICD-9-CM 272.0, 272.1, and 272.2), heart failure (ICD-9-CM 428), anemia (ICD-9-CM 280–285), Parkinson’s disease (ICD-9-CM 332), atrial fibrillation (ICD-9-CM 427.31), and peripheral vascular disease (ICD-9-CM 443). Renal dialysis was identified by administration code (D8, D9). In-hospital 30-day mortality after the index diabetes admission was considered the primary outcome, and post-diabetes pneumonia (ICD-9-CM 480–486), intensive care, length of hospital stay and medical expenditure were considered secondary outcomes in the nested cohort study. We also considered the impact of invasive respiratory treatments on diabetes risk and outcomes, and these treatments included endotracheal tube insertion, tracheal stent insertion, tracheostomy, laryngotracheal reconstruction, repair of tracheobronchial tree, and endobronchial dilatation.

Statistical analyses

Using the analysis of chi-square tests, we compared sociodemographic factors (such as age, sex and low income), co-morbidities (such as hypertension, mental disorders, liver cirrhosis, stroke, hyperlipidemia, heart failure, anemia, atrial fibrillation, peripheral vascular disease and renal dialysis), and medications (such as anticoagulant, anti-platelet agents and lipid-lowering agents) for people with no COPD, with COPD or with COPDe. The adjusted hazard ratios (HRs) and 95% confidence intervals (CIs) of diabetes associated with COPDe were calculated using multivariate Cox proportional hazard models. In the further stratified analysis, the adjusted HRs and 95% CIs of diabetes associated with COPD or COPDe were also calculated in both sexes and all age groups.

In the nested cohort study, analysis of chi-square tests compared differences in sociodemographics, co-morbidities and medications for diabetes patients in the three groups. By using multivariate logistic regressions, we calculated adjusted odds ratios (ORs) and 95% CIs for risks of pneumonia, intensive care and mortality after diabetes. The mean length of stay and medical expenditure were also compared by analysis of variance for diabetic patients without COPD or with COPD or COPDe.

Results

After matching by age and sex among cohorts without COPD, with COPD and COPDe, proportionately more patients with COPDe had low-income status, hypertension, mental disorders, ischemic heart disease, stroke, liver cirrhosis, hyperlipidemia, heart failure, anemia, Parkinson’s disease, atrial fibrillation, peripheral vascular disease and renal dialysis, compared with people without COPD (p<0.0001). Use of medications such as anticoagulants, anti-platelet agents and lipid-lowering agents was also higher in patients with COPDe than in those without COPD (Table 1) (p<0.0001).

Table 1. Baseline characteristics of people with and without COPD.

No COPD N = 18684 COPD N = 9342 COPDe N = 4671 P value
Sex n (%) n (%) n (%) 1.0000
 Female 9256 (49.5) 4628 (49.5) 2314 (49.5)
 Male 9428 (50.5) 4714 (50.5) 2357 (50.5)
Age, years 1.0000
 40–49 5064 (27.1) 2532 (27.1) 1266 (27.1)
 50–59 5292 (28.3) 2646 (28.3) 1323 (28.3)
 60–69 5744 (30.7) 2872 (30.7) 1436 (30.7)
 70–79 2584 (13.8) 1292 (13.8) 646 (13.8)
Low income 289 (1.6) 295 (3.2) 231 (5.0) <0.0001
Co-morbidities
 Hypertension 8667 (46.4) 5405 (57.9) 2803 (60.0) <0.0001
 Mental disorder 5296 (28.4) 4225 (45.2) 2213 (47.4) <0.0001
 Ischemic heart disease. 3140 (16.8) 2900 (31.0) 1621 (34.7) <0.0001
 Stroke 2941 (15.7) 2095 (22.4) 1324 (28.4) <0.0001
 Liver cirrhosis 3316 (17.8) 2628 (28.1) 1151 (24.6) <0.0001
 Hyperlipidemia 3948 (21.1) 2841 (30.4) 1142 (24.5) <0.0001
 Heart failure 511 (2.7) 612 (6.6) 555 (11.9) <0.0001
 Anemia 1139 (6.1) 858 (9.2) 416 (8.9) <0.0001
 Parkinson's disease 355 (1.9) 245 (2.6) 166 (3.6) <0.0001
 Atrial fibrillation 209 (1.1) 236 (2.5) 161 (3.5) <0.0001
 Peripheral vascular disease 399 (2.1) 331 (3.5) 156 (3.3) <0.0001
 Renal dialysis 232 (1.2) 131 (1.4) 117 (2.5) <0.0001
Anticoagulants 540 (2.9) 450 (4.8) 307 (6.6) <0.0001
Anti-platelet agents 7884 (42.2) 5461 (58.5) 2965 (64.5) <0.0001
Lipid-lowering agents 5660 (30.3) 3732 (40.0) 1877 (40.2) <0.0001

COPD = chronic obstructive pulmonary disease; COPDe = chronic obstructive pulmonary disease with exacerbations.

Table 2 shows a higher incidence of diabetes in patients with previous COPD and COPDe than those without COPD (4.1 and 7.4 vs. 3.4 per 1000 person-years, p<0.0001) during the follow-up period. The corresponding HRs for diabetes associated with COPD or COPDe were 1.09 (95% CI, 1.02–1.17) and 2.18 (95% CI, 1.88–2.52), respectively. The association between COPDe and diabetes risk was significant in females (HR, 2.11; 95% CI, 1.72–2.58), males (HR, 2.27; 95% CI, 1.83–2.82) and people in all age groups, specifically 40–49 years (HR, 3.73; 95% CI, 2.41–5.79), 50–59 years (HR, 2.88; 95% CI, 2.16–3.86), 60–69 years (HR, 1.71; 95% CI, 1.35–2.16) and 70–79 years (HR, 1.73; 95% CI, 1.23–2.42). HRs for diabetes risk associated with COPDe for people with 0, 1, 2, ≥3 co-morbidities were 2.68 (95% CI 1.74–4.11), 2.52 (95% CI 1.86–3.42), 2.19 (95% CI 1.65–2.90) and 1.81 (95% CI 1.45–2.26) respectively. Compared with the non-COPD cohort or the COPD cohort (Fig 1), patients with COPDe showed a significantly increased probability of developing diabetes during the follow-up years (log-rank test, p<0.0001). The diabetes risk associated with respiratory invasive treatment for patients with COPDe (HR 1.47, 95% CI 0.95–2.52) was not significant.

Table 2. Risk of diabetes for patients with and without COPD by sex and age.

n Events Person-years Incidenceb HR (95% CI)a
No COPD 18684 563 167874 3.4 1.00 (reference)
COPD 9342 360 87209 4.1 1.09 (1.02–1.17)
COPDe 4671 308 41658 7.4 2.18 (1.88–2.52)
COPDe treatmentc 646 23 3289 7.0 1.47 (0.95–2.26)
Female No COPD 9256 302 85915 3.5 1.00 (reference)
COPD 4628 188 43903 4.3 1.08 (0.99–1.19)
COPDe 2314 162 21576 7.5 2.11 (1.72–2.58)
Male No COPD 9428 261 81959 3.2 1.00 (reference)
COPD 4714 172 43306 4.0 1.10 (0.99–1.22)
COPDe 2357 146 20082 7.3 2.27 (1.83–2.82)
40–49 years No COPD 5064 42 50281 0.8 1.00 (reference)
COPD 2532 47 25346 1.9 1.37 (1.10–1.70)
COPDe 1266 50 12465 4.0 3.73 (2.41–5.79)
50–59 years No COPD 5292 123 49787 2.5 1.00 (reference)
COPD 2646 79 24917 3.2 1.16 (1.00–1.35)
COPDe 1323 89 12312 7.2 2.88 (2.16–3.86)
60–69 years No COPD 5744 263 50401 5.2 1.00 (reference)
COPD 2872 159 26638 6.0 1.04 (0.94–1.15)
COPDe 1436 119 12363 9.6 1.71 (1.35–2.16)
70–79 years No COPD 2584 135 17405 7.8 1.00 (reference)
COPD 1292 75 10307 7.3 1.03 (0.89–1.19)
COPDe 646 50 4518 11.1 1.73 (1.23–2.42)
0 co-morbidity No COPD 5249 99 40532 2.4 1.00 (reference)
COPD 1284 36 10600 3.4 1.17 (0.96–1.45)
COPDe 627 37 4744 7.8 2.68 (1.74–4.11)
1 co-morbidity No COPD 5527 188 49963 3.8 1.00 (reference)
COPD 2279 77 20501 3.8 1.02 (0.87–1.19)
COPDe 1073 71 8965 7.9 2.52 (1.86–3.42)
2 co-morbidities No COPD 4219 135 40313 3.3 1.00 (reference)
COPD 2404 98 22626 4.3 1.08 (0.95–1.24)
COPDe 1200 92 10570 8.7 2.19 (1.65–2.90)
≥ 3 co-morbidities No COPD 3689 141 37065 3.8 1.00 (reference)
COPD 3375 149 33481 4.5 1.08 (0.97–1.20)
COPDe 1771 108 17380 6.2 1.81 (1.45–2.26)

CI = confidence interval; COPD = chronic obstructive pulmonary disease; e = exacerbations; HR = hazard ratio.

aAdjusted for all covariates listed in Table 1.

bPer 1000 person-years.

cInvasive treatments for patients with COPD or COPDe was included.

Fig 1. Probability of diabetes risk estimated using the Kaplan-Meier method for people with no COPD, COPD, and COPDe.

Fig 1

Compared with non-COPD cohort or COPD cohort, patients with COPDe showed significantly increased probability of developing diabetes during the follow-up years (log-rank test, p<0.0001).

Compared with patients without COPD, diabetic patients with previous COPDe more frequently were male, were older, had low income status, and had higher proportions of hypertension, mental disorders, ischemic heart disease, stroke, heart failure, dementia, hyperlipidemia, anemia, Parkinson’s disease, atrial fibrillation, liver cirrhosis, peripheral vascular disease, and renal dialysis (Table 3) (all p<0.001).

Table 3. Characteristics of hospitalized diabetic patients with and without COPD history.

No COPD N = 308709 COPD N = 72554 COPDe N = 14253 P value
Gender n (%) n (%) N (%) <0.0001
 Female 131332 (42.5) 31734 (43.7) 5210 (36.6)
 Male 177377 (57.5) 40820 (56.3) 9043 (63.4)
Age, years <0.0001
 40–49 61709 (20.0) 6285 (8.7) 1002 (7.0)
 50–59 97039 (31.4) 14726 (20.3) 2168 (15.2)
 60–69 84093 (27.2) 22117 (30.5) 3796 (26.6)
 70–79 65868 (21.3) 29426 (40.6) 7287 (51.1)
Low income 13676 (4.4) 4335 (6.0) 1211 (8.5) <0.0001
Co-morbidities
 Hypertension 113546 (36.8) 36863 (50.8) 7087 (49.7) <0.0001
 Mental disorder 41068 (13.3) 15923 (22.0) 3402 (23.9) <0.0001
 Ischemic heart disease 31594 (10.2) 14787 (20.4) 3241 (22.7) <0.0001
 Stroke 30325 (9.8) 10939 (15.1) 2800 (19.6) <0.0001
 Heart failure 4579 (1.5) 4199 (5.8) 1569 (11.0) <0.0001
 Dementia 4020 (1.3) 2179 (3.0) 657 (4.6) <0.0001
 Hyperlipidemia 26809 (8.7) 8670 (12.0) 1146 (8.0) <0.0001
 Anemia 5203 (1.7) 2104 (2.9) 429 (3.0) <0.0001
 Parkinson's disease 2652 (0.9) 1327 (1.8) 368 (2.6) <0.0001
 Atrial fibrillation 1857 (0.6) 1107 (1.5) 321 (2.3) <0.0001
 Liver cirrhosis 7704 (2.5) 1767 (2.4) 336 (2.4) 0.4085
 Peripheral vascular disease 2365 (0.8) 945 (1.3) 173 (1.2) <0.0001
 Renal dialysis 2610 (0.9) 623 (0.9) 157 (1.1) 0.0052

COPD = chronic obstructive pulmonary disease; e = exacerbations.

Concerning adverse outcomes during admissions due to diabetes (Table 4), patients with COPDe had a higher risk of pneumonia (OR 3.28, 95% CI 3.13–3.43) and admission to intensive care (OR 1.32, 95% CI 1.26–1.39). Diabetic patients with COPDe had longer length of hospital stays (16.8±66.8 vs. 10.5±48.1 days, p<0.0001) and higher medical expenditures (2838±8983 vs. 2157±5243 US dollars, p<0.0001) than those without COPD. Mortality after diabetes hospitalization was also significantly associated with history of COPDe (OR 2.06, 95% CI 1.88–2.25).

Table 4. Outcomes during diabetes hospitalization in patients with COPD.

No COPD COPD COPDe Risk for COPD Risk for COPDe
Events (%) Events (%) Events (%) OR (95% CI)a OR (95% CI)a
Pneumonia 19848 (6.4) 9841 (13.6) 3110 (21.8) 2.04 (1.98–2.10) 3.28 (3.13–3.43)
ICU 29527 (9.6) 7973 (11.0) 2183 (15.3) 1.01 (0.98–1.04) 1.32 (1.26–1.39)
Mortality 5114 (1.7) 1778 (2.5) 655 (4.6) 1.23 (1.16–1.30) 2.06 (1.88–2.25)
ME, US dollarsb 2157±5243 2292±6482 2838±8983 p<0.0001 p<0.0001
Length of stay, daysb 10.5±48.1 11.6±48.8 16.8±66.8 p<0.0001 p<0.0001

CI = confidence interval; COPD = chronic obstructive pulmonary disease; e = exacerbation; ME = medical expenditure; OR = odds ratio.

aAdjusted for all covariates listed in Table 3.

bMean±SD

The adjusted ORs for COPD patients developing pneumonia after pre-admission for diabetes at 3 months, 6 months, 12 months, and 18 months were 2.77 (95% CI 2.67–2.86), 2.49 (95% CI 2.41–2.57), 2.26 (95% CI 2.20–2.33), and 2.12 (95% CI 2.06–2.18), respectively (Table 5). The risks of mortality and ICU stay associated with COPD also decreased with the time course of COPDe occurrence. Similar results regarding risk of post-diabetes pneumonia, mortality and ICU stay were also found in patients with COPDe. The risk of post-diabetes pneumonia was associated with the occurrences of COPDe within pre-admission for diabetes at 3 months (OR 3.78, 95% CI 3.56–4.02), 6 months (OR 3.46, 95% CI 3.28–3.66), 12 months (OR 3.37, 95% CI 3.21–3.54), and 18 months (OR 3.29, 95% CI 3.13–3.44). The ORs of post-diabetes pneumonia, mortality and ICU stay associated with respiratory invasive treatment in patients with COPDe were 3.30 (95% CI 3.10–3.53), 0.92 (95% CI 0.77–1.10), and 1.52 (95% CI 1.41–1.63), respectively.

Table 5. Time effects of COPD on the outcomes of diabetes admission.

Pneumonia Mortality ICU stay
History of COPD n OR (95% CI) OR (95% CI) OR (95% CI)
No COPD 308709 1.00 (reference) 1.00 (reference) 1.00 (reference)
COPD occurred
 Pre-admission 3 month 29390 2.77 (2.67–2.86) 1.41 (1.31–1.52) 1.09 (1.05–1.13)
 Pre-admission 6 month 38499 2.49 (2.41–2.57) 1.38 (1.28–1.48) 1.06 (1.02–1.09)
 Pre-admission 12 month 52461 2.26 (2.20–2.33) 1.31 (1.23–1.40) 1.04 (1.00–1.07)
 Pre-admission 18 month 63310 2.12 (2.06–2.18) 1.27 (1.20–1.35) 1.02 (0.99–1.05)
COPDe occurred
 Pre-admission 3 month 6520 3.78 (3.56–4.02) 2.26 (2.01–2.55) 1.45 (1.36–1.56)
 Pre-admission 6 month 8350 3.46 (3.28–3.66) 2.27 (2.04–2.52) 1.43 (1.35–1.52)
 Pre-admission 12 month 10858 3.37 (3.21–3.54) 2.21 (2.01–2.43) 1.39 (1.31–1.47)
 Pre-admission 18 month 12733 3.29 (3.13–3.44) 2.10 (1.92–2.31) 1.36 (1.29–1.43)
 With invasive treatment 5896 3.30 (3.10–3.53) 0.92 (0.77–1.10) 1.52 (1.41–1.63)

CI = confidence interval; COPD = chronic obstructive pulmonary disease; e = exacerbation; ICU = intensive care unit; OR = odds ratio.

Discussion

Our retrospective cohort study showed that COPD patients with and without exacerbations showed significantly increased risk of developing diabetes compared with those without COPD. The nested cohort study showed diabetic patients with history of COPD were significantly associated with increased pneumonia, admission to intensive care, prolonged length of stay, increased medical expenditure and mortality. The results of our studies were consistent with previous reports. [1116]

Exacerbation is critically important in the natural history and clinical outcome for COPD patients. Our study showed that COPD patients with or without exacerbations were associated with higher risk of developing diabetes, and COPD per se impacts diabetes outcomes significantly. Patients experiencing frequent exacerbations were at higher risk for declined lung function and increased mortality [2224]. Previous report also suggested that most COPD exacerbations are due to lower respiratory tract infections [25], which significantly worsened outcomes in COPD patients in terms of increased exacerbation rate and mortality [26].

Comorbidities including hypertension, hyperlipidemia, stroke and cardiovascular disease were known as independent factors associated with diabetes also commonly coexisting in patients with COPD [57,11,13,27].To reduce confounding effects, we used multivariate regression models to adjust comorbid conditions and calculated the risk of diabetes in patients with COPD. Age, gender and socioeconomic status were also considered as potential confounding factors associated with COPD and diabetes [12]. All these characteristics were adjusted in the multivariate regression models. Although previous cohort studies used nationwide data to analyze the risk of diabetes in COPD patients, they were limited by inadequate adjustment for potential confounders [15,16]. The present study showed that COPD with exacerbations was associated with risk of developing diabetes in various age groups, co-morbidities and both sexes. However, the association was weaker in subjects with more than three co-morbidities. It is possible that more numerous and complex co-morbidities may dilute the impact of COPD on the risk of diabetes. Compared with non-COPD group, COPDe patients with invasive respiratory treatment did not have increased diabetes risk and post-diabetes mortality in this study. This non-significant association may be due to the beneficial effects of invasive respiratory treatment for patients with COPDe. However, the phenomenon needs future clinical trials for proving the beneficial effects of invasive respiratory treatment.

Although the mechanism for increased risk of diabetes in COPD remains unclear, we suggest that systemic inflammation is a plausible explanation. In patients with COPD, there is much evidence that the serum levels of inflammatory mediators are increased, including tumor necrosis factor alpha (TNF-α), interleukin-6 (IL-6) or C reactive protein (CRP) [28,29]. High levels of TNF-α may interfere with glucose metabolism and insulin sensitivity and increase the risk of new onset diabetes [30, 31]. Elevated levels of IL-6 and CRP have been shown to predict the development of type 2 diabetes [28, 29].

Another possible explanation for increased risk of diabetes in COPD patients might relate to COPD medications. Current international guidelines suggest systemic glucocorticoid therapy, at least a 5-day course, to manage COPD exacerbations [32]. Yet prolonged exposure to corticosteroids is known to lead to substantial side effects in COPD patients, even death [33]. In addition, steroid therapy for COPD can lead to the development or worsening of diabetes [34,35], although controversy surrounds this observation [36,37]. Whether high-dose and/or long-term steroid use in COPD patients causes type 2 diabetes needs further investigation. Oxidative stress is considered an imbalance between oxidants and antioxidants. In COPD patients, either when stable or during exacerbations, oxidative stress was induced mainly by inhaled oxidants such cigarette smoke or pollution [38]. Oxidative stress, mainly smoke-induced in COPD patients, could cause insulin resistance in type 2 diabetes [39].

A previous study found that diabetes is associated with an increased risk of pulmonary infections, disease exacerbations and worsened COPD outcomes [31]. On the other hand, we found that COPD may be considered a novel risk factor for new onset diabetes and this phenomenon may via multiple mechanisms, including steroids therapy and oxidative stress [28,29]. The further investigation is needed to clarify the link between COPD and diabetes.

This study has some limitations. First, we used insurance claims data that lacked detailed information on sociodemographic and lifestyle factors, hormonal status and biomedical measures [6,7]. Second, pulmonary function data were not available, so the severity of COPD was not classified using Global Initiative for Obstructive Lung Disease criteria [40]. When interpreting the findings of this study should be cautioned because the unavailable data of lung function test is a very important limitation. However, exacerbations are generally considered to become more frequent as the severity of underlying COPD increases [41] and findings from this study cannot be compared to those using Global Initiative for Obstructive Lung Disease criteria for disease staging [12,40]. Third, although we used multivariate adjustment to control for confounders, residual confounding is always possible.

In conclusion, COPD is associated with higher risks of developing diabetes or post-diabetes pneumonia, mortality. However, the real mechanism between COPD and diabetes needs further basic lab data and clinical investigations.

Acknowledgments

This study is based in part on data obtained from the National Health Insurance Research Database. This database is provided by the Bureau of National Health Insurance of Taiwan’s Ministry of Health and Welfare, and is managed by the National Health Research Institutes. The authors’ interpretations and conclusions do not represent those of the Bureau of National Health Insurance, the Ministry of Health and Welfare, or the National Health Research Institutes.

Abbreviations

CI

confidence interval

COPD

chronic obstructive pulmonary disease

HR

hazard ratio

ICD-9-CM

International Classification of Diseases, 9th Revision, Clinical Modification

OR

odds ratio

Data Availability

The data are from the National Health Insurance Research Database (NHIRD) Committee and can be contacted at the following email: nhird@nhri.org.tw.

Funding Statement

This research was supported in part by Shuang Ho Hospital, Taipei Medical University (104TMU-SHH-23), Taipei Medical University (TMU101-AE1-B33), and Taiwan’s Ministry of Science and Technology (MOST106-2221-E-038-003; 106-2314-B-038-036-MY3; MOST105-2629-B-038-001; MOST105-2314-B-038-025; MOST105-2221-E-038-014; MOST104-2221-E-038-015; MOST104-2314-B-038-027-MY2; NSC102-2314-B-038-021-MY3). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

The data are from the National Health Insurance Research Database (NHIRD) Committee and can be contacted at the following email: nhird@nhri.org.tw.


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