Statins and renal disease progression, ophthalmic manifestations, and neurological manifestations in veterans with diabetes: A retrospective cohort study

Ishak A Mansi; Matheu Chansard; Ildiko Lingvay; Song Zhang; Ethan A Halm; Carlos A Alvarez

doi:10.1371/journal.pone.0269982

. 2022 Jul 21;17(7):e0269982. doi: 10.1371/journal.pone.0269982

Statins and renal disease progression, ophthalmic manifestations, and neurological manifestations in veterans with diabetes: A retrospective cohort study

Ishak A Mansi ^1,^2,^3,^*, Matheu Chansard ⁴, Ildiko Lingvay ^3,⁵, Song Zhang ⁵, Ethan A Halm ⁶, Carlos A Alvarez ^5,⁷

Editor: James M Wright⁸

PMCID: PMC9302779 PMID: 35862466

Abstract

Background

Statins increase insulin resistance, which may increase risk of diabetic microvascular complications. Little is known about the impact of statins on renal, ophthalmologic, and neurologic complications of diabetes in practice. The objective of this study was to examine the association of statins with renal disease progression, ophthalmic manifestations, and neurological manifestations in diabetes.

Methods

This is a retrospective cohort study, new-user active comparator design, that included a national Veterans Health Administration (VA) patients with diabetes from 2003 to 2015. Patients were age 30 years or older and were regular users of the VA with data encompassing clinical encounters, demographics, vital signs, laboratory tests, and medications. Patients were divided into statin users or nonusers (active comparators). Statin users initiated statins and nonusers initiated H2-blockers or proton pump-inhibitors (H2-PPI) as an active comparator. Study outcomes were: 1) Composite renal disease progression outcome; 2) Incident diabetes with ophthalmic manifestations; and 3) Incident diabetes with neurological manifestations.

Results

Out of 705,774 eligible patients, we propensity score matched 81,146 pairs of statin users and active comparators. Over a mean (standard deviation) of follow up duration of 4.8 (3) years, renal disease progression occurred in 9.5% of statin users vs 8.3% of nonusers (odds ratio [OR]: 1.16; 95% confidence interval [95%CI]: 1.12–1.20), incident ophthalmic manifestations in 2.7% of statin users vs 2.0% of nonusers (OR: 1.35, 95%CI:1.27–1.44), and incident neurological manifestations in 6.7% of statin users vs 5.7% of nonusers (OR: 1.19, 95%CI:1.15–1.25). Secondary, sensitivity, and post-hoc analyses were consistent and demonstrated highest risks among the healthier subgroup and those with intensive lowering of LDL-cholesterol.

Conclusions

Statin use in patients with diabetes was associated with modestly higher risk of renal disease progression, incident ophthalmic, and neurological manifestations. More research is needed to assess the overall harm/benefit balance for statins in the lower risk populations with diabetes and those who receive intensive statin therapy.

Introduction

Type 2 diabetes mellitus has been considered a “cardiovascular risk equivalent” [1], resulting in a universal recommendation of statins for all patients with diabetes aged 40 to 75 with LDL-cholesterol 70 to 189 mg/dL for primary prevention of cardiovascular diseases (CVD) [2]. Despite their cardiovascular benefits, statins have also been shown to increase insulin resistance [3–8], which is thought to be a main driver of the pathogenesis of diabetic microvascular complications [9–13].

There is a paucity of data on the effects of statins on diabetic microvascular complications. The landmark cardiovascular randomized controlled trials (RCTs) that support the current guidelines for statin use for primary prevention did not, a-priori, evaluate their potential impact on diabetic microvascular complications. A handful of observational studies reported an increased risk of diabetes microvascular complications associated with statin use [14–17], of which two studies were significantly larger (60,455 patients followed for a mean of 4 years and 25,970 patients followed for 6.4 years) [14, 15] than RCTs which established statins’ safety. However, other observational studies found no association between statin use and increased risk of diabetic neuropathy and/or diabetic retinopathy [18–20] and two small trials (less than 50 participants each) associated statin use with improvement in diabetic retinopathy [21, 22].

Reasons for these conflicting results include inadequate adjustment for baseline confounders and the short duration of follow up. On one hand, statin use may be falsely associated with better outcomes because of healthy-user bias, and being a surrogate for higher quality of care, or better access to healthcare [23, 24]. Alternatively, statin use may be falsely associated with worse outcomes because of more exposure to healthcare resulting in ascertainment bias or confounding by indication [24].

The objective of this study was to address these methodological concerns by employing a new user design with active comparators to examine the association of statin therapy with incidence of renal disease progression, and diabetes with ophthalmic and neurological manifestations in a large national cohort of patients with diabetes in the Veterans Affairs (VA) health system who had significant longitudinal follow-up and who have detailed data on healthcare utilization, medical encounters, medication history, vital signs, and laboratory investigations to minimize confounding.

Methods

Study design

This is a retrospective cohort study using the national VA Corporate Data Warehouse (CDW), which encompasses inpatient and outpatient diagnosis/procedure codes, pharmacy, vital signs, and laboratory data. CDW catalogues its data according to published protocols (S1 File) [25]. This study cohort was assembled from a national VA cohort with diabetes identified using a validated algorithm [26] that has been described previously [27]. Briefly, we assembled a cohort of statin users and nonusers (overall cohort), aged 30 years or older, and who are regular VA users. We defined regular VA users as having all of the followings during each of the baseline and the follow-up periods: 1) at least one VA health care encounter; 2) blood pressure and weight measurements; 3) pharmacy records of medications; and 4) laboratory data that included blood/serum glucose, creatinine, and LDL-cholesterol. Available data for included patients encompassed all encounters from fiscal year (FY) 2003 to FY2015 (10/1/2002 to 9/30/2015) regardless of the date in which the patients were diagnosed with diabetes.

We used an active comparator, new user design, to mitigate the risk of immortal time bias and minimize confounding due to unmeasured characteristics [28]. We used newly initiated H2-blockers or proton pump-inhibitors (H2-PPI) as an active comparator to identify statin nonusers if they were not concurrently prescribed statins. Statin users were also newly initiated on statins. We excluded patients who previously filled prescriptions of either medication class within 12 months from cohort entry.

Index date was the date of the first prescription of statins or H2- PPI in their perspective groups. Since the study data included all available encounters from FY 2003 to FY 2015 regardless when patients were diagnosed with diabetes, the index date could have preceded, coincided, or followed their diagnosis of diabetes.

Study intervals

The study encompassed two intervals. The baseline period, which was used to describe baseline characteristics, included the year preceding the index date. The follow-up period, which was used to ascertain outcomes, started from the index date and continued until either: (1) the last available date of VA care, or (2) end of study period, (3) death, or (4) date of statin initiation in active comparators who subsequently used a statin; among this subset of patients who entered the cohort as active comparators but subsequently used a statin, the follow up period ended as active comparators (or outcomes were censored in time-to-event analysis) at date of statin initiation and were subsequently allowed entry into the cohort as statin users starting from the date of their statin initiation as a new index date for the statin user group. We excluded patients with fewer than 60 days of follow up duration from both groups since our main outcomes would be highly unlikely to be due to fewer than 60 days of statin exposure.

Outcomes

We used a combination of International Classification of Diseases, 9^th Revision, Clinical Modification [ICD-9-CM] codes and laboratory investigations to identify outcomes. As previously published, to increase specificity of chronic diseases diagnoses using ICD-9-CM codes, we required each diagnosis to be present in ≥ 2 separate encounters [26, 29, 30].

Primary outcomes

These incident outcomes occurred during follow up period but not at baseline

Renal disease progression composite outcome: This dichotomous outcome comprised the presence of any of the following:
1. Doubling of mean serum creatinine during the last year of follow up in comparison to mean serum creatinine during baseline.
2. Incident stage 5 chronic kidney disease (CKD): Incident decrease in mean estimated glomerular filtration rate (eGFR) during the last year of follow up to <15 mL/min/1.73m² (stage 5) [31], using The Modification of Diet in Renal Disease (MDRD) equation (S1 File) [32].
3. Incident renal replacement therapy (S1 File).
4. Incident diabetic nephropathy: As defined by the Agency for Health Research and Quality Clinical Classifications Software (AHRQ-CCS) multilevel diagnosis category 3.3.2 (S1 File) [33].
5. Incident CKD: As defined by AHRQ-CCS diagnosis categories 156 and 158. Administrative diagnostic codes for renal events have been widely used to identify kidney diseases [34, 35] and their specificity was high (95–99%) [36].
Incident Diabetes with ophthalmic manifestations: As defined by AHRQ-CCS multi-level category 3.3.3 [33].
Incident Diabetes with neurological manifestations: As defined by AHRQ-CCS multi-level category 3.3.4 [33]. Administrative codes were commonly used in identifying patients with diabetic neuropathy in clinical research and utilization studies [37–40].

Overall, administrative codes are useful for identifying diabetic complications [41–45]. The sensitivity and specificity of ICD-9 codes for diagnosing diabetes with complications were 63.6% and 98.9%, respectively [46]. Diabetic complications codes are essential components in calculation of the Charlson comorbidity index [47] and the Elixhauser comorbidity score [48] from administrative data; both these scores are widely used [49].

Secondary outcomes

All individual components of the composite renal disease progression outcome.
Change in mean creatinine (mg/dL) of individual patients during the last year of follow up in comparison to baseline.

Negative control outcomes

To ensure that our findings were not due to unidentified confounders [50], we used two other outcomes that should not be affected by statins: 1) Chronic obstructive pulmonary disease (COPD) and 2) Suicide (S1 File) [51, 52].

Cohort characterization

Patients’ baseline characteristics [47], Charlson Comorbidity Index [47], and cardiovascular risk [53] were defined (S1 File). We created a propensity score to match statin-users and nonusers in the overall cohort at a ratio of 1:1 using 99 variables chosen a priori. Using the routine of Leuven and Sianesi, we performed multivariable logistic regression to estimate the propensity score and perform nearest number matching with a caliper of 0.0008 with no replacement (S1 File) [54, 55].

Primary analysis

We compared our primary, secondary, and negative control outcomes in the propensity score matched overall cohort using conditional logistic regression.

Secondary analyses

We compared our primary outcomes in the following prespecified cohorts (S1 File):

The Overall cohort: Included all eligible patients before propensity score matching.
Healthy cohort: Included only patients with a Charlson comorbidity index of zero at baseline.
Intensive cholesterol lowering statin users in comparison to nonusers in the overall cohort [2].
Medium-intensity cholesterol lowering statin users in comparison to nonusers in the overall cohort [2].
Low-intensity cholesterol lowering statin users in comparison to nonusers in the overall cohort [2].
Time-to-event analysis in the propensity score matched cohort: We estimated the hazard ratio (HR) in statin users in comparison to nonusers using survival regression analysis of the following outcomes: a) Incident CKD; b) Incident diabetes with ophthalmic manifestations; and c) Incident diabetes with neurological manifestations. We performed a separate regression analysis for each of these outcomes.
Time-to-event analysis in the propensity score matched cohort with death as a competing risk: We estimated the subhazard ratio (SHR) in statin users in comparison to nonusers using survival regression analysis using similar outcomes to previous analysis.

Sensitivity analysis

We examined the odds of primary outcomes after excluding those who were diagnosed with incident diabetes, incident diabetic complications, or incident cardiovascular disease within 60 days of the index date. Since it is highly unlikely that statins influenced any of these outcomes within 60 days, excluding those patients further mitigated confounding by indication or residual confounding [56–58].

Post-hoc analysis

We performed several post-hoc analyses:

Propensity score-matched prevalent diabetes cohort: In this analysis, we restricted analysis to subjects with prevalent diabetes at index date. We, thereafter, created a propensity score to match statin-users and nonusers in this restricted cohort at a ratio of 1:1 using the same technique used earlier. We achieved balance in between comparison groups using a caliper of 0.00002 with no replacement.
Ever user vs never user cohort: Excluded patients who started as active comparators and crossed over to statin users group.
Incident diabetes complications cohort: Excluded patients who had any component of diabetes complications at baseline.
Statin duration-based analysis: We stratified statin users by duration of statin use as < 3 year of statin use, or > 3 years of statin use. Each stratum of statin users was compared to nonusers for risk of each outcome in a separate logistic regression model adjusting for the propensity score and duration of follow up.
Survival regression analysis with death as a competing risk in the intensive cholesterol lowering statin users in comparison to nonusers in the overall cohort and adjusting for propensity score. We performed this analysis because our secondary analysis showed that this cohort had the highest risk of complications among all other cohorts.
Any retinopathy and its complications: Rather than using AHRQ-CCS codes, we used a different set of ICD-9-CM codes used by other researchers (S1 Table in S1 File) [30, 59, 60].

Other statistical analysis details

Dichotomous variables were compared using χ² and continuous variables were compared using t-test. When Kolmogorov-Smirnov test indicated unequal distribution, we used the Wilcoxon Mann-Whitney test. We performed a separate logistic regression model for each dichotomous outcome in secondary and sensitivity analyses where the outcome was the dependent variable and statin use was an independent variable adjusting for the propensity score. Statistical significance was defined as two-tailed p-values < 0.05. Statistical analyses were performed using STATA version 15 (College Station, TX). The study was approved by the VA North Texas Health Care System and Texas Tech University Health Sciences Center Institutional Review Boards, which waived informed consent since data were fully anonymized before being accessed by the investigators. The study followed Reporting of Observational Studies in Epidemiology (STROBE) guidelines.

Results

Cohort assembly is shown in S1 File. A total of 705,774 patients fulfilled the study criteria (595,579 statin users and 110,195 active comparators); Cohort baseline characteristics are described in S1 File. We successfully matched 81,146 pairs of statin users and active comparators (nonusers) on all baseline characteristics and duration of follow-up period (approximately 4.8 ± 3.0 years) with the exception of proportions of some racial minorities and ethnicity (Table 1). Although all the cohort had diabetes by the end of the study, at baseline period not all patients were diagnosed with diabetes yet. In the propensity score-matched cohort, statin users and nonusers had similar proportions of patients diagnosed with diabetes, all diabetes complications, and similar glycemic control. Additionally, statin users and nonusers had similar utilization of glucose lowering agents, and similar creatinine and eGFR. Baseline lipid levels were higher in statin users than nonusers (Table 1). Overall, 63% of the statin prescriptions were for simvastatin, 12% for atorvastatin, 11% for rosuvastatin, 10% for pravastatin. As expected, statin users had a greater decrease in LDL-cholesterol during follow-up compared to nonusers (mean [SD] -25.2 [31.5] mg/dL in statin users and -0.9 [23.6] mg/dL in nonusers, p<0.001)–(S1 File).

Table 1. Baseline characteristics of propensity score-matched statin users and active comparators.

	Overall Cohort			Diabetes Prevalent Cohort
	Statin users (n = 81,146)	Nonusers (n = 81,146)	p-value	Statin users (n = 51,370)	Nonusers (n = 51,370)	p-value
Baseline characteristics included in propensity score
Age at index date (years): mean (SD)	60.2 (11.6)	60.2 (11.6)	0.82	61.5 (11.3)	61.5 (11.2)	0.80
Male Gender	77,067 (95.0)	77,022 (95.0)	0.61	49,268 (96.0)	49,280 (95.9)	0.85
Race
Caucasian	55,174 (68.0)	55,498 (68.4)	0.08	35,062 (68.3)	35,546 (69.2)	0.001
African American	17,367 (21.4)	17,352 (21.4)	0.93	10,626 (20.7)	10,416 (20.3)	0.10
American Indians/Alaskan, pacific/Hawaiian	1,626 (2.0)	1,807 (2.2)	0.002	1,084 (2.1)	1,164 (2.3)	0.09
Asian	702 (0.9)	464 (0.6)	<0.001	453 (0.9)	322 (0.6)	0.001
Unknown/missing	6,277 (7.7)	6,025 (7.4)	0.02	4,145 (8.1)	3,922 (7.6)	0.01
Ethnicity
Hispanic/Latino	5,179 (6.4)	5,549 (6.8)	<0.001	3,468 (6.8)	3,608 (7.0)	0.09
Non-Hispanic/Latino	71,899 (88.6)	71,645 (88.3)	0.05	45,233 (88.1)	45,168 (87.9)	0.53
Unknown/missing	4,068 (5.0)	3,952 (4.9)	0.18	2,669 (5.2)	2,594 (5.1)	0.29
Social and family history during baseline period
Family history of cardiovascular diseases¹	1,008 (1.2)	1,007 (1.2)	0.98	538 (1.1)	533 (1.0)	0.88
Smoking²	15,966 (19.7)	15,964 (19.7)	0.99	9,189 (17.9)	9,271 (18.0)	0.51
Alcohol-related disorders³	7,407 (9.1)	7,375 (9.1)	0.78	4,074 (7.9)	4,146 (8.1)	0.41
Substance-related disorders³	5,512 (6.8)	5,514 (6.8)	0.98	3,064 (6.0)	3,016 (5.9)	0.53
Vital data during baseline period
Mean systolic blood pressure (mmHg): mean (SD)	135 (15)	135 (15)	0.88	135 (15)	135 (15)	0.19
Mean diastolic blood pressure (mmHg): mean (SD)	78 (10)	78 (10)	0.39	77.5 (9.7)	77.5 (9.6)	0.94
Body mass index
< 25 kg/m²	9,584 (11.8)	9,599 (11.8)	0.91	5,598 (10.9)	5,650 (11.0)	0.60
25 to <30 kg/m²	22,509 (27.7)	22,286 (27.5)	0.22	13,666 (26.6)	13,681 (26.6)	0.92
30 to <35 kg/m²	20,781 (25.6)	20,925 (25.8)	0.41	13,365 (26.0)	13,295 (25.9)	0.62
35 to <40 kg/m²	10,902 (13.4)	10,819 (13.3)	0.55	7,236 (14.1)	7,283 (14.2)	0.67
40 to <45 kg/m²	4,104 (5.1)	4,191 (5.2)	0.32	2,845 (5.5)	2,935 (5.7)	0.22
≥ 45 kg/m²	2,371 (2.9)	2,365 (2.9)	0.93	1,751 (3.4)	1,699 (3.3)	0.37
Missing	10,895 (13.4)	10,961 (13.5)	0.63	6,909 (13.5)	6,827 (13.3)	0.45
Healthcare utilization during baseline period
Number of inpatient admissions:
mean (SD)	1.29 (3.76)	1.30 (3.76)	0.79	1.39 (3.90)	1.42 (3.96)	0.07
median (interquartile)	0 (0, 0)	0 (0, 0)	0.58	0 (0, 0)	0 (0, 0)	0.08
Number of outpatient encounters
mean (SD)	12.0 (19.5)	12.0 (19.7)	0.59	12.0 (18.3)	11.9 (17.8)	0.82
median (interquartile)	7 (3, 14)	7 (3, 14)	0.07	7 (3, 15)	7 (3, 14)	0.56
Received immunization and infectious disease screening	31,843 (39.2)	31,846 (39.3)	0.99	21,138 (41.2)	21,206 (41.3)	0.67
Received rehabilitation care; fitting of prostheses; and adjustment of devices	7,771 (9.6)	7,775 (9.6)	0.97	5,074 (9.9)	5,062 (9.9)	0.90
Diabetes and its complications during baseline period: ³
Diabetes mellitus	42,242 (52.1)	42,080 (51.9)	0.42
Diabetes with complications	9,712 (12.0)	9,792 (12.1)	0.54	10,187 (19.8)	10,177 (19.8)	0.94
Diabetes with ketoacidosis or uncontrolled diabetes	3,705 (4.6)	3,697 (4.6)	0.92	3,791 (7.4)	3,820 (7.4)	0.73
Diabetes with renal manifestations	748 (0.9)	786 (1.0)	0.33	815 (1.6)	808 (1.6)	0.86
Diabetes with ophthalmic manifestations	1,535 (1.9)	1,595 (2.0)	0.28	1,595 (3.1)	1,660 (3.2)	0.25
Diabetes with neurological manifestations	3,686 (4.5)	3,707 (4.6)	0.80	3,932 (7.7)	3,857 (7.5)	0.38
Diabetes with circulatory manifestations	361 (0.4)	330 (0.4)	0.24	352 (0.7)	352 (0.7)	>0.99
Diabetes with unspecified manifestations	687 (0.9)	713 (0.9)	0.49	719 (1.4)	753 (1.5)	0.38
Diabetic foot⁴	469 (0.6)	430 (0.5)	0.19	434 (0.8)	432 (0.8)	0.95
Peripheral ulcer⁴	1,399 (1.7)	1,409 (1.7)	0.85	1,154 (2.3)	1,131 (2.2)	0.63
Below knee amputations⁴	7 (0.01)	6 (0.01)	0.78	2 (0.0)	5 (0.01)	0.26
Above knee amputations⁴	0	0	n/a	0 (0.0)	0 (0.0)
Any retinopathy & its complications⁴	2,523 (3.1)	2,538 (3.1)	0.83	2,376 (4.6)	2,428 (4.7)	0.44
Glycemic control at baseline
Mean glucose in blood in mg/dL: mean (SD)	133 (49)	133 (51)	0.22	149 (56)	150 (57)	0.62
At least one blood glucose of 200mg/dL or more	16,230 (20.0)	16,090 (19.8)	0.38	16,689 (32.5)	16,853 (32.8)	0.28
More than 5 measurements with blood glucose of 200mg/dL or more	3,811 (4.7)	3,814 (4.7)	0.97	3,916 (7.6)	4,016 (7.8)	0.24
Glucose lowering medication classes at baseline
Metformin	15,397 (19.0)	15,237 (18.8)	0.31	15,777 (30.1)	15,598 (30.4)	0.26
Sulphonylurea	11,041 (13.6)	10,965 (13.5)	0.58	11,444 (22.3)	11,329 (22.1)	0.39
GLP1	24 (0.03)	14 (0.02)	0.11	14 (0.03)	17 (0.03)	0.59
DDP4	82 (0.1)	88 (0.1)	0.65	89 (0.2)	91 (0.2)	0.88
Thiazolidinediones	1,212 (1.5)	1,202 (1.5)	0.84	1,179 (2.3)	1,247 (2.4)	0.16
α-glucosidase inhibitors	1 (0.0)	1 (0.0)	>0.99	1 (0.0)	1 (0.0)	>0.99
Amylin analog	2 (0.0)	3 (0.0)	0.66	3 (0.0)	3 (0.0)	>0.99
SGLT2	1 (0.0)	0 (0.0)	0.32	0 (0.0)	0 (0.0)
Insulins	6,674 (8.2)	6,632 (8.2)	0.70	6,721 (13.1)	6,824 (13.3)	0.34
Total number of anti-diabetes medication groups:
mean (SD)	0.42 (0.74)	0.42 (0.74)	0.33	0.69 (0.85)	0.68 (0.84)	0.66
Median (interquartile)	0 (0, 1)	0 (0, 1)	0.10	0 (0, 1)	0 (0, 1)	0.75
Other comorbidities at baseline ³
Obesity as defined by ICD-9 codes⁵	18,621 (23.0)	18,512 (22.8)	0.52	12,801 (25.0)	12,869 (25.1)	0.62
Valvular heart disease	2,299 (2.8)	2,233 (2.8)	0.32	1,514 (3.0)	1,468 (2.9)	0.39
Peri-; endo-; and myocarditis; cardiomyopathy	1,060 (1.3)	1,037 (1.3)	0.61	703 (1.4)	727 (1.4)	0.52
Hypertension	52,468 (64.7)	52,309 (64.5)	0.41	35,713 (69.5)	35,723 (69.5)	0.95
Hypertension with complication or secondary hypertension	1,763 (2.2)	1,798 (2.2)	0.55	1,351 (2.6)	1,346 (2.6)	0.92
Acute myocardial infarction	273 (0.3)	246 (0.3)	0.24	182 (0.4)	183 (0.4)	0.96
Coronary atherosclerosis and other heart disease	9,947 (12.3)	9,916 (12.2)	0.81	7,235 (14.1)	7,336 (14.3)	0.37
Nonspecific chest pain	5,671 (7.0)	5,659 (7.0)	0.91	3,297 (6.4)	3,394 (6.6)	0.22
Pulmonary heart disease	686 (0.9)	714 (0.9)	0.45	482 (0.9)	495 (1.0)	0.68
Other and ill-defined heart disease	1,323 (1.6)	1,324 (1.6)	0.98	856 (1.7)	832 (1.6)	0.56
Conduction disorders	1,565 (1.9)	1,607 (2.0)	0.45	1,177 (2.3)	1,179 (2.3)	0.97
Cardiac dysrhythmias	6,842 (8.4)	6,704 (8.3)	0.22	4,631 (9.0)	4,614 (9.0)	0.85
Cardiac arrest and ventricular fibrillation	36 (0.04)	34 (0.05)	0.81	23 (0.04)	31 (0.04)	0.28
Congestive heart failure	3,399 (4.2)	3,306 (4.1)	0.25	2,485 (4.8)	2,497 (5.0)	0.86
Acute cerebrovascular disease	1,873 (2.3)	1,781 (2.2)	0.12	1,242 (2.4)	1,240 (2.4)	0.97
Occlusion or stenosis of precerebral arteries; ill-defined cerebrovascular disease; Transient cerebral ischemia	1,278 (1.6)	1,245 (1.5)	0.51	835 (1.6)	824 (1.6)	0.79
Peripheral and visceral atherosclerosis	2,606 (3.2)	2,620 (3.2)	0.84	1,859 (3.6)	1,869 (3.6)	0.87
Aortic; peripheral; and visceral artery aneurysms	725 (0.9)	691 (0.9)	0.36	456 (0.9)	474 (0.9)	0.55
Aortic and peripheral arterial embolism or thrombosis	118 (0.2)	127 (0.2)	0.57	78 (0.2)	84 (0.2)	0.64
Chronic obstructive pulmonary disease and bronchiectasis	9,854 (12.1)	9,815 (12.1)	0.77	5,998 (11.7)	5,959 (11.6)	0.70
Asthma	3,532 (4.4)	3,614 (4.5)	0.32	2,136 (4.2)	2,083 (4.1)	0.41
Respiratory failure; insufficiency; arrest	510 (0.6)	537 (0.7)	0.40	439 (0.9)	447 (0.9)	0.79
Nephritis; nephrosis; renal sclerosis; Chronic kidney disease	3,167 (3.9)	3,211 (4.0)	0.57	2,550 (5.0)	2,585 (5.0)	0.62
Acute and unspecified renal failure	1,725 (2.1)	1,686 (2.1)	0.50	1402 (2.7)	1,392 (2.7)	0.85
Renal replacement therapy	1,039 (1.3)	1,049 (1.3)	0.83	684 (1.3)	693 (1.4)	0.81
Rheumatoid arthritis; Systemic lupus erythematosus and connective tissue disorders	1,283 (1.6)	1,289 (1.6)	0.91	799 (1.6)	777 (1.5)	0.58
Pathological fracture	69 (0.1)	75 (0.1)	0.62	39 (0.1)	50 (0.1)	0.24
Schizophrenia and other psychotic disorders	2,766 (3.4)	2,847 (3.5)	0.27	1,563 (3.0)	1,532 (3.0)	0.57
Suicide and intentional self-inflicted injury	807 (1.0)	810 (1.0)	0.94	473 (0.9)	469 (0.9)	0.90
Severe liver disease⁶	425 (0.5)	464 (0.6)	0.19	353 (0.7)	431 (0.8)	0.005
Malignancy⁶	6,904 (8.5)	6,912 (8.5)	0.94	4,609 (9.0)	4,654 (9.1)	0.62
Metastatic neoplasm⁶	356 (0.4)	382 (0.5)	0.34	276 (0.5)	288 (0.6)	0.61
Acquired Immunodeficiency Syndrome⁶	476 (0.6)	508 (0.6)	0.31	254 (0.5)	252 (0.5)	0.93
Any neuropathy⁴	7,746 (9.6)	7,799 (9.6)	0.66	6,653 (13.0)	6,569 (12.8)	0.43
Comorbidity Scores
Charlson Comorbidity Total Score⁷:
mean (SD)	1.28 (1.42)	1.29 (1.43)	0.60	1.68 (1.42)	1.69 (1.43)	0.16
median (interquartile)	1 (0, 2)	1 (0, 2)	0.99	1 (1, 2)	1 (1, 2)	0.21
Cardiovascular risk⁸
< 5%	19,019 (23.4)	19,156 (23.6)	0.42	7,215 (14.1)	7,125 (13.9)	0.42
5 to <10%	15,343 (18.9)	15,379 (19.0)	0.82	8,721 (17.0)	8,692 (16.9)	0.81
10 to <15%	18,566 (22.9)	18,560 (22.9)	0.97	12,697 (24.7)	12,778 (24.9)	0.56
15 to <20%	15,748 (19.4)	15,647 (19.3)	0.53	12,494 (24.3)	12,609 (24.6)	0.40
20 to <25%	7,511 (9.3)	7,474 (9.2)	0.75	6,836 (13.3)	6,787 (13.2)	0.65
25 to <30%	1,753 (2.2)	1,722 (2.1)	0.60	1,646 (3.2)	1,651 (3.2)	0.93
≥30%	148 (0.2)	139 (0.2)	0.60	124 (0.2)	136 (0.3)	0.46
Missing	3,058 (3.8)	3,069 (3.8)	0.89	1,637 (3.2)	1,592 (3.1)	0.42
Renal Function at baseline
Mean serum creatinine in mg/dL: mean (SD)	1.11 (0.59)	1.11 (0.61)	0.30	1.12 (0.63)	1.12 (0.63)	0.98
Mean eGFR
>90 mL/min per 1.73 m²	21,416 (26.4)	21,528 (26.5)	0.53	14,029 (27.3)	14,105 (27.5)	0.60
60 to 89 mL/min per 1.73 m²	45,065 (55.5)	44,797 (55.2)	0.18	26,927 (52.4)	26,900 (52.4)	0.87
45 to 59 mL/min per 1.73 m²	10,012 (12.3)	10,135 (12.5)	0.35	6,823 (13.3)	6,743 (13.1)	0.46
30 to 44 mL/min per 1.73 m²	3,266 (4.0)	3,258 (4.0)	0.92	2,513 (4.9)	2,531 (4.9)	0.80
15 to 29 mL/min per 1.73 m²	944 (1.2)	935 (1.2)	0.84	718 (1.4)	726 (1.4)	0.83
<15 mL/min per 1.73 m²	443 (0.6)	493 (0.6)	0.10	360 (0.7)	365 (0.7)	0.85
Mean eGFR: mean (SD)	78 (22)	78 (23)	0.35	78 (24)	78 (24)	0.41
Other medications groups
ACEI	25,970 (32.0)	25,868 (31.9)	0.59	18,920 (36.8)	19,003 (37.0)	0.59
ARB	4,110 (5.1)	4,193 (5.2)	0.35	3,234 (6.3)	3,172 (6.2)	0.42
Beta-blockers	16,259 (20.0)	16,379 (20.2)	0.46	10,681 (20.8)	10,674 (20.8)	0.96
Non-loop diuretic	19,733 (24.3)	19,804 (24.4)	0.68	12,490 (24.3)	12,531 (24.4)	0.77
Loop diuretic	5,823 (7.2)	5,803 (7.2)	0.85	4,206 (8.2)	4,260 (8.3)	0.54
Other anti-hypertensive agents⁹	8,911 (11.0)	9,017 (11.1)	0.40	5,638 (11.0)	5,560 (10.8)	0.44
Anti-arrhythmic medications	2,830 (3.5)	2,854 (3.5)	0.75	1,829 (3.6)	1,854 (3.6)	0.68
Antithrombotic	2,702 (3.3)	2,663 (3.3)	0.59	1,774 (3.5)	1,762 (3.4)	0.84
Antipsychotic	2,754 (3.4)	2,786 (3.4)	0.66	1,588 (3.1)	1,552 (3.0)	0.51
Dopamine agonist	617 (0.8)	598 (0.7)	0.58	414 (0.8)	382 (0.7)	0.26
Peripheral vascular disease medications¹⁰	324 (0.4)	311 (0.4)	0.61	207 (0.4)	206 (0.4)	0.96
Anti-smoking medications	4,060 (5.0)	4,006 (4.9)	0.54	2,382 (4.6)	2,376 (4.6)	0.93
Non-statin lipid lowering medications	6,832 (8.4)	6,839 (8.4)	0.95	5,018 (9.8)	5,035 (9.8)	0.86
Cardiovascular procedures at baseline
Electrocardiography	14,468 (17.8)	14,483 (17.9)	0.92	9,264 (18.0)	9,343 (18.2)	0.52
Echocardiography	4,344 (5.4)	4,334 (5.3)	0.91	3,014 (5.9)	3,027 (5.9)	0.86
Stress test	1,898 (2.3)	1,961 (2.4)	0.31	1,198 (2.3)	1,257 (2.5)	0.23
Cardiac catheterization	118 (0.2)	108 (0.1)	0.51	88 (0.2)	88 (0.2)	>0.99
Percutaneous coronary intervention	54 (0.07)	41 (0.05)	0.18	39 (0.1)	36 (0.1)	0.73
Coronary artery bypass graft surgery	1 (0.0)	1 (0.0)	>0.99	1 (0.0)	1 (0.0)	>0.99
Pacemaker/defibrillator implantation	55 (0.1)	68 (0.1)	0.24	47 (0.1)	47 (0.1)	0.76
Peripheral arterial revascularization procedures	8 (0.01)	7 (0.01)	0.80	4 (0.0)	5 (0.0)	0.74
Duration of Follow-up in days	1761 (1101)	1770 (1101)	0.11	1437 (979)	1446 (992)	0.13
Baseline characteristics not included in the propensity score match
Mean total cholesterol: mean (SD)¹¹	195 (44)	174 (39)	<0.001	185 (43)	170 (40)	>0.001
Mean LDL-cholesterol: mean (SD)	119 (38)	101 (31)	<0.001	111 (35)	96 (31)	>0.001
Mean HDL-cholesterol: mean (SD)¹²	43 (12)	41 (13)	<0.001	42 (12)	41 (13)	>0.001

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Values expressed as numbers (%) unless stated otherwise

Abbreviations: ACEI: Angiotensin converting enzyme inhibitors; ARB: Angiotensin-receptor blockers; DPP-4: Dipeptidyl peptidase 4 inhibitors; eGFR: estimated glomerular filtration rate using the Modification of Diet in Renal Disease (MDRD) Study equation;[32] GLP-1: Glucagon-like peptide 1 agonists; SGLT2 = Sodium glucose cotransporter 2 inhibitors

1. Family history of cardiovascular disease was defined using ICD-9-CM codes (S1 File)

2. Smoking as defined using ICD-9-CM codes: 3051 and V1582.

3. Diagnoses & procedures as defined by the Agency for Health Research and Quality Clinical Classifications Software disease categories (AHRQ-CCS) [33].

4. Diagnosis using ICD-9 or CPT codes as defined in prior studies (S1 File).

5. Diagnosis is based on selected ICD-9-CM diagnosis codes from category 56 of AHRQ-CCS (S1 File).

6. Malignancy, metastatic neoplasm, and Acquired Immunodeficiency Syndrome were defined using Deyo et al method in calculating the Charlson comorbidity index [47].

7. The Charlson comorbidity total score was calculated using Deyo et al method [47].

8. Cardiovascular risk was calculated using D’ Agostino et al method for calculating the Framingham risk score [53].

9. Other anti-hypertensive agents include α-blocker medications, clonidine, α-methyldopa, hydralazine, minoxidil, and reserpine

10. Peripheral vascular disease medications include pentoxiphylline, cilostazole, papaverine, tolazoline, cyclandelate, and ethaverine

11. Results for total cholesterol were available for only 80,718 statin users and 80,821 control subjects in the overall cohort and 51,085 statin users and 51,163 control subjects in the diabetes prevalent cohort

12. Results for HDL-cholesterol were available for only 78,111 statin users and 78,105 control subjects in the overall cohort and 49,742 statin users and 49,792 control subjects in the diabetes prevalent cohort

Primary analysis

Statin use was associated with increased odds of renal disease progression (OR: 1.16, 95%CI: 1.12–1.20), ophthalmic manifestations (OR: 1.35, 95%CI: 1.27–1.44), and neurological manifestations (OR: 1.19, 95%CI: 1.15–1.25); (Table 2).

Table 2. Risk of outcomes during follow up period in propensity score matched cohort of statin users in comparison to active comparators.

	PS-Overall Cohort (Primary analysis)				PS-Diabetes Prevalent Cohort
	Statin users N (%) N = 81,146	Active comparators N (%) N = 81,146	OR (95%CI)	P-value	Statin users N (%) N = 51,370	Active comparators N (%) N = 51,370	OR (95%CI)	P-value
Primary outcomes
Renal disease progression composite outcome	7,692 (9.5)	6,724 (8.3)	1.16 (1.12–1.20)	<0.001	4,980 (9.7)	4,479 (8.7)	1.12 (1.08–1.17)	<0.001
Incident Diabetes with ophthalmic manifestations	2,149 (2.7)	1,602 (2.0)	1.35 (1.27–1.44)	<0.001	1,931 (3.8)	1,485 (2.9)	1.31 (1.22–1.41)	<0.001
Incident Diabetes with neurological manifestations	5,422 (6.7)	4,582 (5.7)	1.19 (1.15–1.25)	<0.001	3,766 (7.3)	3,593 (7.0)	1.05 (1.00–1.10)	0.04
Secondary outcomes
Components of the composite renal disease progression outcome
Doubling mean serum creatinine	1,580 (2.0)	1,520 (1.9)	1.04 (0.97–1.12)	0.28	1,143 (2.2)	1,083 (2.1)	1.06 (0.97–1.15)	0.20
Incident Stage 5 CKD	729 (0.9)	636 (0.8)	1.14 (1.03–1.28)	0.01	542 (1.1)	464 (0.9)	1.17 (1.03–1.33)	0.01
Incident renal replacement therapy	805 (1.0)	728 (0.9)	1.11 (1.0–1.22)	<0.05	547 (1.1)	473 (0.9)	1.16 (1.02–1.31)	0.02
Incident diabetic nephropathy	1,209 (1.5)	967 (1.2)	1.25 (1.15–1.37)	<0.001	1,018 (2.0)	800 (1.6)	1.28 (1.16–1.40)	<0.001
Incident CKD	6,011 (7.4)	5,053 (6.2)	1.20 (1.16–1.25)	<0.001	3,795 (7.4)	3,248 (6.3)	1.18 (1.13–1.24)	<0.001
Change in mean creatinine (mg/dL) from the baseline period to the last year of follow up:
Mean (SD)	0.069 (0.612)	0.063 (0.602)	-	0.05	0.092 (0.614)	0.081 (0.606)		0.004
Median (interquartile) ^*	0.00 (-0.1, 0.12)	0.00 (-0.1, 0.13)	-	0.007	0.01 (-0.1, 0.13)	0.01 (-0.1, 0.15)		0.02
Median (interquartile) ^*	0.00 (-0.1, 0.12)	0.00 (-0.1, 0.13)	-	0.007	0.01 (-0.1, 0.13)	0.01 (-0.1, 0.15)		0.02
Negative control outcome
Chronic obstructive pulmonary diseases	23,544 (29.0)	23,604 (29.1)	1.0 (0.98–1.02)	0.77	12,732 (24.8)	12,754 (24.8)	1.00 (0.97–1.03)	0.87
Suicide and intentional self-inflicted injury	2,796 (3.5)	2,838 (3.5)	0.98 (0.93–1.04)	0.57	1,265 (2.5)	1,283 (2.5)	1.01 (0.94–1.10)	0.72
Post-hoc outcome
Any retinopathy & its complications	5,079 (6.3)	4,264 (5.3)	1.20 (1.15–1.26)	<0.001	3,613 (7.0)	4,219 (8.2)	1.18 (1.13–1.24)	<0.001

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CKD = Chronic kidney diseases; PS = Propensity score

* Using Wilcoxon rank-sum test

Statin users also had higher odds of incident Stage 5 CKD (OR: 1.14, 95%CI: 1.03–1.28); incident renal replacement therapy (OR: 1.11, 95%CI: 1.0–1.22); incident diabetic nephropathy (OR: 1.25, 95%CI: 1.15–1.37); and incident CKD (OR: 1.20, 95%CI 1.16–1.25). There was no difference in odds of doubling mean serum creatinine.

Negative control outcomes were similar between statin users and nonusers (Table 2); OR of chronic obstructive pulmonary diseases was 1.0 (95%CI: 0.98–1.02) and OR of suicide was 0.98 (95%CI: 0.93–1.04).

Secondary analysis

Statin users had higher ORs of all primary outcomes that were consistent throughout all cohorts (Table 3). The propensity score matched prevalent diabetes cohort showed overall results consistent with the primary analysis. The healthy cohort had the highest OR for all complications. Similarly, intensive cholesterol lowering statin users relative to nonusers also had the highest numerical OR of all diabetes complications than less intense cholesterol lowering cohorts. Sensitivity and survival analysis supported our main analysis for all outcomes (Table 4).

Table 3. Secondary analysis and sensitivity analysis comparing outcomes during follow between statin users vs active comparators.

	Statin users N (%)	Active comparator N (%)	Adjusted OR^* (95%CI)	p-value
Overall Cohort (595,579 statin users and 110,195 active comparators)
Renal disease progression composite outcome	78,966 (13.3)	7,839 (7.1)	1.17 (1.14–1.20)	<0.001
Incident Diabetes with ophthalmic manifestations	30,202 (5.1)	1,713 (1.6)	1.33 (1.26–1.40)	<0.001
Incident Diabetes with neurological manifestations	61,845 (10.4)	4,969 (4.5)	1.17 (1.13–1.20)	<0.001
Any retinopathy & its complications (post-hoc outcome)	61,160 (10.3)	4,691 (4.3)	1.20 (1.16–1.24)	<0.001
Healthy Cohort (148, 509 statin users and 39,009 active comparators)
Renal disease progression composite outcome	15,543 (10.5)	1,944 (5.0)	1.31 (1. 24–1.38)	<0.001
Incident Diabetes with ophthalmic manifestations	3,294 (2.2)	183 (0.5)	2.09 (1.79–2.44)	<0.001
Incident Diabetes with neurological manifestations	10,803 (7.3)	1,024 (2.6)	1.48 (1.38–1.58)	<0.001
Any retinopathy & its complications (post-hoc outcome)	7,226 (4.9)	713 (1.8)	1.45 (1.33–1.57)	<0.001
Intensive cholesterol lowering statin users in comparison to nonusers in the overall cohort (38,823 statin users and 110,195 active comparators)
Renal disease progression composite outcome	6,534 (16.8)	7,839 (7.1)	1.66 (1.60–1.73)	<0.001
Incident Diabetes with ophthalmic manifestations	2,358 (6.1)	1,713 (1.6)	1.76 (1.64–1.89)	<0.001
Incident Diabetes with neurological manifestations	4,476 (11.5)	4,969 (4.5)	1.34 (1.28–1.41)	<0.001
Any retinopathy & its complications (post-hoc outcome)	4,760 (12.3)	4,691 (4.3)	1.63 (1.55–1.70)	<0.001
Medium-intensity cholesterol lowering statin users in the overall cohort (180,884 statin users and 110,195 active comparators)
Renal disease progression composite outcome	25,621 (14.1)	7,839 (7.1)	1.30 (1.26–1.34)	<0.001
Incident Diabetes with ophthalmic manifestations	8,945 (5.0)	1,713 (1.6)	1.25 (1.19–1.33)	<0.001
Incident Diabetes with neurological manifestations	20,027 (11.1)	4,969 (4.5)	1.23 (1.19–1.28)	<0.001
Any retinopathy & its complications (post-hoc outcome)	18,673 (10.3)	4,691 (4.3)	1.23 (1.18–1.27)	<0.001
Low-intensity cholesterol lowering statin users in comparison to nonusers in the overall cohort (375,872 statin users and 110,195 active comparators)
Renal disease progression composite outcome	46,811 (12.5)	7,839 (7.1)	1.13 (1.09–1.16)	<0.001
Incident Diabetes with ophthalmic manifestations	18,899 (5.0)	1,713 (1.6)	1.43(1.36–1.51)	<0.001
Incident Diabetes with neurological manifestations	37,342 (9.9)	4,969 (4.5)	1.17 (1.13–1.21)	<0.001
Any retinopathy & its complications (post-hoc outcome)	37,727 (10.0)	4,691 (4.3)	1.26 (1.21–1.30)	<0.001
Sensitivity Analysis
Overall Cohort after excluding patients with incident diabetes, diabetic complications, or cardiovascular disease within less than 60 days from index date (353,065 statin users and 77,657 active comparators)
Renal disease progression composite outcome	40,115 (11.4)	4,595 (5.9)	1.15 (1.11–1.19)	<0.001
Incident Diabetes with ophthalmic manifestations	11,543(3.3)	713 (0.9)	1.28 (1.18–1.38)	<0.001
Incident Diabetes with neurological manifestations	29,237 (8.3)	2,553 (3.3)	1.22 (1.17–1.27)	<0.001
Any retinopathy & its complications (post-hoc outcome)	25,147 (7.1)	2,201 (2.83)	1.16 (1.11–1.22)	<0.001
Post-Hoc analysis
Ever user vs never user cohort (543,403 statin users and 58,019 active comparators)
Renal disease progression composite outcome	73,476 (13.5)	5,787 (10.0)	1.05 (1.01–1.08)	0.003
Incident Diabetes with ophthalmic manifestations	28,682 (5.3)	1,176 (2.0)	1.48 (1.39–1.57)	<0.001
Incident Diabetes with neurological manifestations	57,057 (10.5)	3,492 (6.0)	1.15 (1.11–1.19)	<0.001
Any retinopathy & its complications (post-hoc outcome)	57,261 (10.5)	3,174 (5.5)	1.26 (1.21–1.31)	<0.001
Incident diabetes complications cohort (513,125 statin users and 98,231 active comparators)
Renal disease progression composite outcome	62,994 (12.3)	6,447 (6.6)	1.18 (1.14–1.21)	<0.001
Incident Diabetes with ophthalmic manifestations	22,236 (4.3)	1,205 (1.2)	1.36 (1.28–1.46)	<0.001
Incident Diabetes with neurological manifestations	51,931 (10.1)	4,130 (4.2)	1.19 (1.15–1.24)	<0.001
Any retinopathy & its complications (post-hoc outcome)	41,149 (8.0)	2,965 (3.0)	1.24 (1.20–1.30)	<0.001
Statin users for < 3 years of statin use vs nonusers (172,123 statin users and110,195 active comparators)
Renal disease progression composite outcome	15,101 (8.8)	7,839 (7.1)	1.02 (0.99–1.05)^**	0.17
Incident Diabetes with ophthalmic manifestations	4,469 (2.6)	1,713 (1.6)	1.04 (0.98–0.10)^**	0.16
Incident Diabetes with neurological manifestations	9,163 (5.3)	4,969 (4.5)	0.84 (0.81–0.88)^**	<0.001
Any retinopathy & its complications (post-hoc outcome)	11,273 (6.6)	4,691 (4.3)	1.05 (1.00–1.08)^**	0.02
Statin users for > 3 years of statin use vs nonusers (423,456 statin users and 110,195 active comparators)
Renal disease progression composite outcome	63,865 (15.1)	7,839 (7.1)	1.19 (1.16–1.22)^**	<0.001
Incident Diabetes with ophthalmic manifestations	25,733 (6.1)	1,713 (1.6)	1.34 (0.27–1.41)^**	<0.001
Incident Diabetes with neurological manifestations	52,682 (12.4)	4,969 (4.5)	1.25 (1.20–1.29)^**	<0.001
Any retinopathy & its complications (post-hoc outcome)	49,887 (11.8)	4,691 (4.3)	1.19 (1.15–1.23)^**	<0.001

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* Odds ratio adjusted for propensity score except when indicated differently

** Odds ratio adjusted for propensity score and duration of follow up

Table 4. Hazard/Subhazard ratio of outcomes in statin users in comparison to nonusers.

Outcome	Hazard ratio	95% confidence interval	p-value
Secondary analysis
Propensity score matched cohort (81,146 statin users and 81,146 nonusers)
Incident CKD	1.20	1.16–1.25	<0.001
Incident Diabetes with ophthalmic manifestations	1.35	1.26–1.44	<0.001
Incident Diabetes with neurological manifestations	1.19	1.15–1.24	<0.001
Propensity score matched cohort with death as a competing risk factor (81,146 statin users and 81,146 nonusers)
Incident CKD	1.13^*	1.09–1.17	<0.001
Incident Diabetes with ophthalmic manifestations	1.28^*	1.20–1.37	<0.001
Incident Diabetes with neurological manifestations	1.19^*	1.15–1.24	<0.001
Post-Hoc analysis
Intensive cholesterol lowering statin users in comparison to nonusers in the overall cohort with death as a competing risk factor (38,823 statin users and 110,195 active comparators)
Incident CKD	1.57^*	1.51–1.64	<0.001
Incident Diabetes with ophthalmic manifestations	1.71^*	1.59–1.83	<0.001
Incident Diabetes with neurological manifestations	1.30^*	1.24–1.36	<0.001

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*Subhazard ratio

Post-hoc analysis

All post-Hoc analyses had OR that were generally consistent in direction and magnitude with primary and secondary analyses (Tables 2–4). However, renal disease progression composite outcome in the ever user vs never user design had OR of 1.05, which was lower than other analyses (Table 3).

Statin duration analysis showed that statin users for < 3 years have no increased risk of the primary outcomes and may be decreased risk of incident diabetes with neurological manifestation. However, statin users for 3 years or more had increased risks of all outcomes.

Discussion

In this study of a national cohort of veterans with diabetes, statin users compared to nonusers had modest, but significantly higher risks of incident renal, ophthalmic and neurologic complications. The results were consistent across all analyses. Moreover, there was a dose-response relation to intensity of LDL-cholesterol lowering: statin users with intensive cholesterol lowering having the highest risk for all outcomes, which strengthens our confidence in these associations. The lack of associations with the negative control outcomes (COPD, suicide) adds to specificity of these findings.

Of specific interest is that patients without comorbidities (healthy cohort) had the highest increase in odd of adverse outcomes associated with statin use. For instance, OR of renal disease progression was 1.31 (vs. 1.17 in the overall cohort), that of ophthalmic manifestations was 2.09 (vs. OR = 1.33 in the overall cohort), and that of neurological manifestations was 1.48 (vs OR = 1.17 in the overall cohort). Our findings are consistent with those from a propensity score matched cohort of a healthy Tricare population (which contains both active duty soldiers and their families) who used statins as their only prescription medication [16]. In this study, OR of diabetes with complications was 2.15 in statin users compared to nonusers, but when the analysis was restricted to healthy active duty soldiers who are expected to be healthier and more physically active, the odds was even higher at 2.47 [17].

There is biological plausibility for these associations. Statins may increase the risk of diabetes microvascular complications through increasing insulin resistance [6] and inducing mitochondrial dysfunction resulting in more toxic effects of oxygen radicals [61]. Evidence from in-vitro studies, a Mendelian randomization study, and observational studies have demonstrated that statin therapy is associated with insulin resistance [6–8]. Insulin resistance is associated with increased risk of diabetic complications [9, 10], endothelial dysfunction, inflammation, hypercoagulability, and increased platelet reactivity [11–13]. In presence of hyperglycemia, the availability of excessive intracellular glucose for oxidization in the tricarboxylic cycle results in production of larger amounts of electrons [62, 63]. Excessive electron burden generating superoxide may lead to diabetic complications [62, 63]. Statin therapy was associated with mitochondrial dysfunction [61, 64], which may compound the effects of superoxide. Beyond these basic science findings, we recently reported, using the same population, that statin initiation was associated with increased risk of diabetes treatment escalation and hyperglycemic events [27].

Our findings are also concordant with a recent metaanalysis of RCTs reporting that statins were associated with increased risk of renal insufficiency (OR: 1.14, 95%CI: 1.01–1.28) [65]. Yet, our study findings contrast with some of the scarce studies that examined this topic. A recent study reported that diabetic polyneuropathy in patients with newly diagnosed diabetes was similar in statin users compared to nonusers [20]. However, in that cohort 39% of new statin users discontinued their statin and 45% of statin nonusers initiated statins during the follow-up period. When the investigators censored patients at time of either initiating or discontinuing statins, there was an increased risk of diabetic polyneuropathy (HR = 1.17) [20]. Another nested matched study (with a median follow-up of 2.7 years) compared the risk of diabetic microvascular complications between patients who received statins prior to being diagnosed with diabetes and statin nonusers. Statin users had lower incidence of diabetic retinopathy (HR: 0.60) and diabetic neuropathy (HR: 0.66), but not diabetic nephropathy [18]. However, this study lacked several critical baseline characteristics such as body weight, obesity, a measure for comorbidity, or critical laboratory values, which along with the short duration of follow-up raise concerns for presence of confounders. In another retrospective cohort study, statin users had a lower rate of diabetic retinopathy (HR: 0.86) [60], however, the study excluded patients with LDL cholesterol <100 mg/dL. The study also lacked several important baseline characteristics including predictors of diabetic retinopathy such as diastolic blood pressure and glycemic control [66]. Additionally, our duration-based analysis may offer an insight into some aspects of the conflicting results in the literature since it suggests that statin use in our study was associated with risk of outcomes in those who used statins for longer duration (≥ 3 years) but not shorter duration (< 3 years). However, since our duration-based analysis was secondary post-hoc analysis, interpreting its findings should be considered exploratory indicating necessity of prospectively designed further research with this analysis defined a priori.

Any adverse effects of statins should be put in context of their well-demonstrated cardiovascular benefits. Table 5 compares the calculated number needed to be exposed for one additional harm (NNEH) based on the data from this study using previously published formula [67] and number needed to treat (NNT) for cardiovascular benefit from other studies [68, 69]. We recognize that not all events are clinically equivalent, so comparing the absolute NNEH v. NNT needs to be interpreted in a larger context. For example, a disabling stroke is clearly more morbid than doubling serum creatinine. However, a retinopathy resulting in blindness can be more devastating than revascularization following angina.

Table 5. Number needed to be exposed for one additional harm (NNEH) from this study and number needed to treat (NNT) for cardiovascular benefit from other studies.

	NNEH or NNT
Overall cohort
Adverse events as projected from our propensity score matched cohort
Renal disease progression composite outcome	83
Incident Diabetes with ophthalmic manifestations	147
Incident Diabetes with neurological manifestations	99
Cardiovascular benefits for patients with diabetes as projected form a metanalysis¹
Primary prevention of MACE	35
Secondary prevention of MACE	14
Healthy cohort
Adverse events as projected from healthy Cohort
Renal disease progression composite outcome	69
Incident Diabetes with ophthalmic manifestations	185
Incident Diabetes with neurological manifestations	83
Cardiovascular benefits for patients at low cardiovascular risk as projected form a metanalysis²
Death from any cause	239
Myocardial infarction	216
Stroke	291
Revascularization	131
Intensive lowering of choesterol
Adverse events as projected from intensive cholesterol lowering statin users in comparison to nonusers in the overall cohort
Renal disease progression composite outcome	24
Incident Diabetes with ophthalmic manifestations	85
Incident Diabetes with neurological manifestations	69

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MACE = Major cardiovascular event; NNEH = Number needed to be exposed to cause one additional harm as calculated in previously published formula;[67] NNT = number needed to treat

Numbers in green color indicate NNT for cardiovascular benefit and numbers in red indicate NNEH for harm from adverse events.

1. Data from Background Paper for the American College of Physicians; for primary prevention, NNT for benefit is 4.3 years; for secondary prevention, NNT for benefit is 4.9 years [68]

2. Data from a metanalysis of randomized controlled trials; low cardiovascular risk was defined as an observed 10-year Framingham risk score less than 20% for cardiovascular-realted death or nonfatal myocardial infarction in the control arm [69].

Weighing the balance of risks to benefits of statins would seem to be most important in the case of primary prevention where the absolute cardiovascular benefits are more modest, so higher risks of impactful non-cardiovascular outcomes might change decision making. Unfortunately, placebo -controlled RCTs of statins for primary prevention in the general population, which exclusively enrolled patients with diabetes or intended to specifically enroll more patients with diabetes, are limited to four RCTs (S1 File) [70].

Overall, these studies were of relatively modest size (<3000 patients in any study), were of relatively short duration (2.4–4.8 years), enrolled patients with multiple risk factors (other than diabetes), minimally (if any) assessed diabetic microvascular complications, and none of them showed a benefit (or did not report) on total mortality [71–74]. Additionally, most of these studies were done in the past century where pharmacologic agents for diabetes control, blood pressure control, and smoking were different from the present era. Recently, the incidence of acute coronary events has been declining in developed countries [75] whereas the incidence of diabetes-related complications resurged [76]. As such, it is important to incorporate all available information and critically reassess the overall harm/benefit balance of statins on all outcomes. It might be possible that, especially in the lowest risk group where the absolute cardiovascular benefits are small, the subtle adverse metabolic effects associated with statin use might tip the net balance differently than currently assumed.

This study, to our knowledge, is the largest study to date that examined the association of statin use with risk of renal diseases progression, ophthalmologic, and neurological manifestations of diabetes. Several limitations are worth noting. Although we used several methodological techniques to mitigate immortal time bias, confounding by indication, and extensively described relevant baseline characteristics, residual confounding is always a concern in observational studies. This study may have underestimated the magnitude of the outcomes since a significant proportion of its population did not have diabetes at baseline, hence, their follow up may not be long enough to manifest diabetes complications. Additionally, some studies have associated use of PPI, which we used as a control group in our study, with modest increase in renal diseases, [77, 78] some neurological conditions [79], or ophthalmic conditions [80]. Though we had detailed longitudinal data on patients within the VA healthcare system, we did not have information on potential care outside the VA system. However, it is unlikely that care outside the VA would differentially affect statin users and nonusers. Finally, VA patients are predominantly males, which may limit generalization of our data; however, research shows that male VA patients have similar health characteristics as individuals with other insurance coverage suggesting greater generalizability [81].

In conclusion, we found that among patients with diabetes, statin use was associated with a modest but significant increased risk of renal, ophthalmic and neurologic manifestations. This risk was more pronounced with intensive LDL-cholesterol lowering and in healthier populations. Further research in the use of statins for primary prevention of CVD in patients with diabetes, in which renal, ophthalmic and neurologic outcomes are specifically evaluated as primary outcomes is needed to reliably assess the overall risk benefit ratio of statins in this large segment of the population. The ethos of primary prevention should be “first do no harm”.

Supporting information

S1 File

(DOCX)

Click here for additional data file.^{(3.3MB, docx)}

Acknowledgments

Disclaimer

The views expressed herein are those of the authors and do not reflect the official policy or position of the Department of the Army, Department of Defense, VA Administration, or the US Government. The VA Health Care System, the University of Texas Southwestern and NIDDK had no role in the design and conduct of the study; collection, management, analysis, and interpretation of the data; preparation, review, or approval of the manuscript; and decision to submit the manuscript for publication. One of the authors (IM) is an employee of the US government. This work was prepared as part of his official duties and, as such, there is no copyright to be transferred.

Data Availability

Data cannot be shared publicly because of VA confidentiality and patients protections rules. Data are available from the VINCI Institutional Data Access for researchers who meet the criteria for access to confidential data (www.VINCI.va.gov).

Funding Statement

The author(s) received no specific funding for this work.

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PLoS One. doi: 10.1371/journal.pone.0269982.r001

Decision Letter 0

James M Wright

Transfer Alert

This paper was transferred from another journal. As a result, its full editorial history (including decision letters, peer reviews and author responses) may not be present.

22 Feb 2022

PONE-D-21-36306Statins and renal disease progression, ophthalmic manifestations, and neurological manifestations in Veterans with diabetes: A retrospective cohort studyPLOS ONE

Dear Dr. Mansi:

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Additional Editor Comments

This is a well-conducted analysis with important findings. When describing the balance between adverse and positive outcomes it is better to use the term harm/benefit balance rather than risk/benefit balance.

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Reviewers' comments:

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Reviewer #1: Yes

Reviewer #2: Yes

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2. Has the statistical analysis been performed appropriately and rigorously?

Reviewer #1: Yes

Reviewer #2: Yes

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Reviewer #1: No

Reviewer #2: No

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Reviewer #1: Yes

Reviewer #2: Yes

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5. Review Comments to the Author

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Reviewer #1: In this impressive study, much attention was paid to controlling for confounding and selection bias. Table 1 shows remarkably good balance over a very large number of variables, thanks to exposure propensity score matching. Therefore, I am inclined to interpret the data in Table 2 as I would from a hypothetical randomized trial.

As a pre-caution, I imagined a hypothetical trial…

If I imagine such a trial, patients would be randomly assigned to either statins or the control group comprising H2-blockers or proton pump-inhibitors. The cohort might be stratified into those with and without a diagnosis of diabetes at baseline.

In the subgroup without diabetes at baseline, some would develop diabetes during the follow-up period. Statins are known to increase the incidence of diabetes onset, so there would be an imbalance of diabetes between the intervention and control groups in the subgroup of people free of diabetes at baseline.

Key question: Should the analysis of the subgroup without diabetes at baseline be stratified by whether or not they developed diabetes after baseline? And after such stratification, can those who never develop diabetes in the study period be dropped from the trial analysis?

End of my hypothetical trial.

Now, turning to the cohort study, lines 144 to 147 state:

“Index date was the date of the first prescription of statins or H2- PPI in their perspective groups.

Since the study data included all available encounters from FY 2003 to FY 2015 regardless when

patients were diagnosed with diabetes, the index date could have preceded [my italics] coincided, or followed their diagnosis of diabetes.”

The fact that the cohort data source is restricted to patients who eventually are diagnosed with diabetes is analogous to dropping from the hypothetical trial (after randomization) anyone who did not later develop diabetes. Does that introduce a form of confounding like stratification on an intermediate or like M-bias (controlling for an antecedent associated with both exposure and outcome)? And if it does, what is the direction of the bias? Will propensity score matching at baseline eliminate that confounding?

I’m not sufficiently familiar with the methodology literature on directed acyclic graphs to make a judgement myself whether it is OK to restrict a cohort on its outcomes. My intuition is it is more like stratification on an intermediate than M-bias, and the bias would be towards the null. My intuition is also that such a negative bias would be eliminated by propensity score matching.

I would be convinced by reference to a methodology paper showing that restricting a cohort study to those with a certain outcome only causes underestimation of a causal effect.

Alternatively, I would be convinced by a sensitivity analysis. So, I looked in the paper for results from an analysis where the cohort was stratified by baseline diabetes, or a sensitivity analysis where the cohort was restricted to those with diabetes at baseline, before starting a statin (n =42,242) or active comparator (n =42,080)

The results of the sensitivity analysis on page 23 are a step in that direction: “Overall Cohort after excluding patients with incident diabetes, diabetic complications, or cardiovascular disease within less than 60 days from index date (353,065 statin users and 77,657 active comparators)”

But I would go further and show results excluding any whose first manifestation of diabetes was after the baseline period (i.e. analyses restricted to those who would have qualified to be in the database before follow-up). I appreciate that it would reduce the analysis to testing hypotheses concerning risk factors for further manifestations of diabetes beyond the initial manifestation. (I would also want to see an additional Table 1a showing excellent balance when restricted to patients who qualified to be in the database at baseline.)

The secondary analysis of the Healthy Cohort is restricted to a portion of those excluded from the above analysis. If there is a problem with stratifying or restricting a cohort to people who have a future outcome, then it should be manifest in this subgroup analysis. If the odds ratios were lower in this subgroup, that could be explicable as biased towards the null due to the requirement that people in the control group would have diabetes in future. On the contrary, the odds ratios are a little higher than in the overall cohort, which is to be expected if the risk difference is similar (between healthy and less healthy groups) but the baseline rate of outcomes is lower (as it would be in a healthy subgroup.) (Again, a Table 1b showing excellent balance of covariates in this group would be reassuring.)

Therefore, on the reviewer form, I checked "No" in the box referring to data transparency, which might be a bit unfair. But I wanted to flag the fact that it would be more transparent to include in the Supplementary materials, Table 1a and 1b, and the sensitivity analysis I described.

In conclusion, my judgement is that the study design and analysis were very well executed, but that the paper could briefly discuss the potential for selection bias/confounding towards the null due to the minimum requirement to be in the database was one manifestation of diabetes, and that this would be expected to be eliminated by propensity score matching.

Reviewer #2: This is an interesting article that provides valuable information on potential adverse events of statin use in diabetic patients. Authors conclude that among patients with diabetes, statin use is associated with a modest but significant increased risk of renal, ophthalmic and neurologic manifestations.

It is possible that authors underestimate the real magnitude of the association due to a number of reasons, namely,

- Not all patients had diabetes at index date. In fact, only 52% of patients were diabetic at baseline. This may have contributed to underestimation of the statin effects due to lower exposure time. Probably it would have been more informative if all patients had been diagnosed with diabetes at study entry.

- Authors state that different bias may be present in this type of study. On one hand, statin use may be falsely associated with better outcomes because of healthy-user bias, and being a surrogate for higher quality of care, or better access to healthcare. Alternatively, statin use may be falsely associated with worse outcomes because of more exposure to healthcare resulting in ascertainment bias or confounding by indication. In order to address these methodological concerns, authors employed a new user design with active comparators (H2 blockers or PPIs).

However, PPIs are associated with increased risk of renal disease (1)(2)(3)(4)(5), neurological (6)(7)(8) or ophthalmic manifestations (9)(10). This means that if statins had been compared to a drug unrelated to these adverse events, observed differences would have probably been higher than reported.

- At study entry, some 8% of patients had already developed the primary endpoint. The baseline characteristics table shows that at inclusion in the study, some patients with diabetes had also renal disease (1%), ophthalmic (2%) or neurological manifestations (4.5%). For the evaluation of incident events, these patients should have been excluded since that had already developed the study outcome. Authors showed results comparing both groups in a “Healthy Cohort” as a sensitivity analysis. A higher association between statin use and renal, ophthalmic and neurological manifestations was observed.

Interestingly, there is a dose-dependent association being the incidence of adverse events much higher if intensive cholesterol lowering compared to low-moderate lowering. The article provides no information about exposure time to statins. It would have been very informative to stratify results according to statin duration.

This article offers valuable information that suggests further research on renal, ophthalmic and neurologic manifestations of statin use is warranted.

References:

1. Al-Aly Z, Maddukuri G, Xie Y. Proton Pump Inhibitors and the Kidney: Implications of Current Evidence for Clinical Practice and When and How to Deprescribe. Am J Kidney Dis [Internet]. 2020;75(4):497–507. Available from: https://doi.org/10.1053/j.ajkd.2019.07.012

2. Fontecha-Barriuso M, Martín-Sanchez D, Martinez-Moreno JM, Cardenas-Villacres D, Carrasco S, Sanchez-Niño MD, et al. Molecular pathways driving omeprazole nephrotoxicity. Redox Biol [Internet]. 2020;32(December 2019):101464. Available from: https://doi.org/10.1016/j.redox.2020.101464

3. Guedes JVM, Aquino JA, Castro TLB, De Morais FA, Baldoni AO, Belo VS, et al. Omeprazole use and risk of chronic kidney disease evolution. PLoS One. 2020;15(3):1–16.

4. Ness-Jensen E, Fossmark R. Adverse Effects of Proton Pump Inhibitors in Chronic Kidney Disease. JAMA Intern Med. 2016;176(6):868.

5. Wu B, Li D, Xu T, Luo M, He Z, Li Y. Proton pump inhibitors associated acute kidney injury and chronic kidney disease: data mining of US FDA adverse event reporting system. Sci Rep [Internet]. 2021;11(1):1–8. Available from: https://doi.org/10.1038/s41598-021-83099-y

6. Makunts T, Abagyan R. How can proton pump inhibitors damage central and peripheral nervous systems? Neural Regen Res. 2020;15(11):2041–2.

7. Makunts T, Alpatty S, Lee KC, Atayee RS, Abagyan R. Proton-pump inhibitor use is associated with a broad spectrum of neurological adverse events including impaired hearing, vision, and memory. Sci Rep [Internet]. 2019;9(1):1–10. Available from: http://dx.doi.org/10.1038/s41598-019-53622-3

8. Novotny M, Klimova B, Valis M. PPI long term use: Risk of neurological adverse events? Front Neurol. 2019;10(JAN).

9. Hanneken AM, Babai N, Thoreson WB. Oral proton pump inhibitors disrupt horizontal cell-cone feedback and enhance visual hallucinations in macular degeneration patients. Investig Ophthalmol Vis Sci. 2013;54(2):1485–9.

10. Schönhöfer PS. Wernera B, and Tröger U. Ocular damage associated with proton pump inhibitors. BMJ 1997;314:1805

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Reviewer #1: No

Reviewer #2: No

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PLoS One. 2022 Jul 21;17(7):e0269982. doi: 10.1371/journal.pone.0269982.r002

Author response to Decision Letter 0

26 May 2022

James M Wright

Academic Editor

PLOS ONE

Re: Statins and renal disease progression, ophthalmic manifestations, and neurological manifestations in Veterans with diabetes: A retrospective cohort study (PONE-D-21-36306)

Dear Dr. Wright:

We would like to thank you and the reviewers for your time and effort in reviewing our manuscript and for your encouraging comments. We have responded to the Editor’s and reviewers’ comments as detailed below. To facilitate the review, we included the Editor’s/reviewers’ comment in italics indented paragraph, followed by our response in regular font.

We have updated our conflict-of-interest statements, which remained basically unchanged. We look forward to hearing from you.

Ishak Mansi, MD

Response to Reviewers

Journal Requirements:

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Response: We followed all instructions according to the journal requirements posted online.

Response: The data used in this research is extracted from and hosted remotely in the VA Informatics and Computing Infrastructure (VINCI). VINCI is a Health Services Research & Development (HSR&D) Resource Center that provides researchers a nationwide view of high value VA patient data, where research projects are granted access to data in VINCI (VA HSR RES 13-457, U.S. Department of Veterans Affairs – 2008; https://vincicentral.vinci.med.va.gov). In addition to data storage, VINCI includes a cluster of servers set aside for tasks like analysis and data processing. VINCI is only accessible from the VA intranet after obtaining appropriate authorization. This means that VA researchers will have access to data and the applications necessary to data management and analysis in a secure location only accessible from the VA intranet. Data in VINCI cannot be copied, transported, or printed; several safeguards are in place to prevent any data transfer outside VINCI. Additionally, both VINCI and Privacy Officers approving IRB protocols demand investigators to attest that they will not attempt to copy or transfer data outside of VINCI. However, we will be glad to share our data with investigators who obtain appropriate authorization from VINCI to access the data.

Response: We have added the ORCID ID for the corresponding author.

Response: The ethics statement in mentioned in page 12, lines 253-255, which read: “The study was approved by the VA North Texas Health Care System and Texas Tech University Health Sciences Center Institutional Review Boards, which waived informed consent since data were fully anonymized before being accessed by the investigators.”

Response: We have modified the names of the Supporting Information files to follow the Journal guidelines and we have included a caption in the last page of the manuscript to read:

Supporting Information Captions:

- S-Methods: ……………………………………………………………………….. Page 2

o CDW

o Protocol for laboratory tests and vital signs handling

o Propensity score matching details

- S1 Table. Definition of administrative codes used in the study outcomes ……… Page 4

- S2 Table. Administrative codes used in definitions of baseline characteristics … Page 6

- S3 Table. Secondary Analysis Definitions ……………………………………… Page 10

- S-Figure. Study design and cohort assembly………………………………….... Page 11

- S4 Table. Baseline characteristics of statin users and active comparators in the

overall cohort before propensity score matching ………………………………. Page 12

- S5 Table. Comparisons of changes in vital signs and laboratory values

in propensity score matched cohort of statin users and nonusers ……………… Page 18

- S6 Table. Summary of the major placebo controlled randomized cardiovascular

outcome trials evaluating statins in a primary prevention in patients with diabetes Page 19

Additional Editor Comments

Response: We have replaced the term “risk/benefit” with “harm/benefit” throughout the manuscript.

Comments to the Author

1. Is the manuscript technically sound, and do the data support the conclusions?

Reviewer #1: Yes

Reviewer #2: Yes

________________________________________

2. Has the statistical analysis been performed appropriately and rigorously?

Reviewer #1: Yes

Reviewer #2: Yes

________________________________________

3. Have the authors made all data underlying the findings in their manuscript fully available?

Reviewer #1: No

Reviewer #2: No

4. Is the manuscript presented in an intelligible fashion and written in standard English?

Reviewer #1: Yes

Reviewer #2: Yes

Response: We thank the reviewers for their assessment to our study. We have detailed earlier the restriction by VINCI and IRB of the VA healthcare system in sharing/transferring any data outside VINCI. As we detailed earlier, we are glad to facilitate data access by other researchers who are granted VINCI access, as per VA and VINCI policies.

As a pre-caution, I imagined a hypothetical trial…

End of my hypothetical trial.

Now, turning to the cohort study, lines 144 to 147 state:

“Index date was the date of the first prescription of statins or H2- PPI in their perspective groups. Since the study data included all available encounters from FY 2003 to FY 2015 regardless when patients were diagnosed with diabetes, the index date could have preceded [my italics] coincided, or followed their diagnosis of diabetes.”

Response: We appreciate the reviewer’s thoughtfulness in contemplating a hypothetical scenario of a clinical trial simulating our study. First, we appreciate the specific interest in a sub-cohort of patients who had diabetes at the index date (rather than developed it during the follow-up period). As such, we have added an additional propensity score-matched analysis restricted to the population who was diagnosed with diabetes prior to starting the medication of interest (statin or comparator). As you will appreciate form the revised manuscript, the results were the same. Second, the outcome in our study was diabetes complications (not development of diabetes). As such, restricting the cohort to only those with diabetes is appropriate, as that is the population of interest who has the potential to develop the outcome (diabetes-related complication). Our goal was to evaluate the effect of statin use (whether was prescribed before the diagnosis of diabetes or after the diagnosis) on occurrence or progression of diabetes-related complications.

I would be convinced by reference to a methodology paper showing that restricting a cohort study to those with a certain outcome only causes underestimation of a causal effect.

Response: We agree with the reviewer that adding an analysis restricting data to those who have diabetes at baseline will strengthen the study. Therefore, we added another propensity score-matched analysis to patients with diabetes at baseline (prevalent diabetes cohort). Overall, there was very good balance of all baseline characteristics between statin users and nonusers in the propensity score-matched prevalent diabetes cohort. Overall, the OR of outcomes were generally in line with the propensity score-matched overall cohort. However, direct comparison between OR of both cohorts is difficult since the diabetes prevalent cohort had shorter mean (SD) duration of follow up than the overall cohort: 1761 (1101) vs 1437 (979) days, respectively.

In the method section (page 2, lines 238-242), we added:

“Post-Hoc analysis: We performed several post-hoc analyses:

1. Propensity score-matched prevalent diabetes cohort: In this analysis, we restricted analysis to subjects with prevalent diabetes at index date. We, thereafter, created a propensity score to match statin-users and nonusers in this restricted cohort at a ratio of 1:1 using the same technique used earlier. We achieved balance in between comparison groups using a caliper of 0.00002 with no replacement.”

In the result section, we added

We also added the baseline characteristics to table 1 in parallel with the original propensity score matched cohort. Hence, table 1 now depicts baseline characteristics of both the propensity score-matched cohorts from the overall cohort and the diabetes prevalent cohort.

We also added the outcome results of this new analysis in table 2 as below (highlighted in light blue):

Table 2. Risk of outcomes during follow up period in propensity score matched cohort of statin users in comparison to active comparators

PS-Overall Cohort (Primary analysis) PS-Diabetes Prevalent Cohort

Statin users

N (%)

N=81,146 Active comparators

N (%)

N=81,146 OR

(95%CI) P-value Statin users

N (%)

N= 51,370 Active comparators

N (%)

N= 51,370 OR

(95%CI) P-value

Primary outcomes

Renal disease progression composite outcome 7,692 (9.5) 6,724 (8.3) 1.16 (1.12-1.20) <0.001 4,980 (9.7) 4,479 (8.7) 1.12 (1.08-1.17) <0.001

Incident Diabetes with ophthalmic manifestations 2,149 (2.7) 1,602 (2.0) 1.35 (1.27-1.44) <0.001 1,931 (3.8) 1,485 (2.9) 1.31 (1.22-1.41) <0.001

Incident Diabetes with neurological manifestations 5,422 (6.7) 4,582 (5.7) 1.19 (1.15-1.25) <0.001 3,766 (7.3) 3,593 (7.0) 1.05 (1.00-1.10) 0.04

Secondary outcomes

Components of the composite renal disease progression outcome

Doubling mean serum creatinine 1,580 (2.0) 1,520 (1.9) 1.04 (0.97-1.12) 0.28 1,143 (2.2) 1,083 (2.1) 1.06 (0.97-1.15) 0.20

Incident Stage 5 CKD 729 (0.9) 636 (0.8) 1.14 (1.03-1.28) 0.01 542 (1.1) 464 (0.9) 1.17 (1.03-1.33) 0.01

Incident renal replacement therapy 805 (1.0) 728 (0.9) 1.11 (1.0-1.22) <0.05 547 (1.1) 473 (0.9) 1.16 (1.02-1.31) 0.02

Incident diabetic nephropathy 1,209 (1.5) 967 (1.2) 1.25 (1.15-1.37) <0.001 1,018 (2.0) 800 (1.6) 1.28 (1.16-1.40) <0.001

Incident CKD 6,011 (7.4) 5,053 (6.2) 1.20 (1.16-1.25) <0.001 3,795 (7.4) 3,248 (6.3) 1.18 (1.13-1.24) <0.001

Change in mean creatinine (mg/dL) from the baseline period to the last year of follow up:

Mean (SD) 0.069 (0.612) 0.063 (0.602) - 0.05 0.092 (0.614) 0.081 (0.606) 0.004

Median (interquartile) * 0.00

(-0.1, 0.12) 0.00

(-0.1, 0.13) -

- 0.007 0.01 (-0.1, 0.13) 0.01 (-0.1, 0.15) 0.02

Negative control outcome

Chronic obstructive pulmonary diseases 23,544 (29.0) 23,604 (29.1) 1.0 (0.98-1.02) 0.77 12,732 (24.8) 12,754 (24.8) 1.00 (0.97-1.03) 0.87

Suicide and intentional self-inflicted injury 2,796 (3.5) 2,838 (3.5) 0.98 (0.93-1.04) 0.57 1,265 (2.5) 1,283 (2.5) 1.01 (0.94-1.10) 0.72

Post-hoc outcome

Any retinopathy & its complications 5,079 (6.3) 4,264 (5.3) 1.20 (1.15-1.26) <0.001 3,613 (7.0) 4,219 (8.2) 1.18 (1.13-1.24) <0.001

CKD = Chronic kidney diseases; PS = Propensity score

* Using Wilcoxon rank-sum test

It is possible that authors underestimate the real magnitude of the association due to a number of reasons, namely,

Response: We appreciate the reviewer’s input. We have created an additional propensity score-matched analysis that included only patients with diabetes at baseline, as detailed earlier (diabetes prevalent cohort). Additionally, we included the reviewer’s comment in our study limitations section. Page 34, lines2-5 now reads:

“This study may have underestimated the magnitude of the outcomes since a significant proportion of its population did not have diabetes at baseline, hence, their follow up may not be long enough to manifest diabetes complications. Additionally, some studies have associated use of PPI, which we used as a control group in our study, with modest increase in renal diseases , [78, 79] some neurological conditions,[80] or ophthalmic conditions.[81] …….

Response: Although some patients may have experienced kidney diseases at baseline, these same patients may not have neurological or ophthalmologic manifestations of diabetes. Hence, these patients may still experience some of our outcomes. The reviewer point of view is well taken, and we could have designed the study as suggested by the reviewer. We opted to keep those patients in the study so as we have the full spectrum of patients with diabetes. We also agree with the reviewer that our sensitivity analysis that excluded patients with any diabetes complications have addressed this concern. However, to further address this concern, we have added a post-hoc analysis that excluded patients with any diabetes complications at baseline. Overall, regardless how much we divided the data or created subgroups, our results remained consistent.

In the Methods section (page 12, lines 245-246), we added:

“ 3. Incident diabetes complications cohort: Excluded patients who had any component of diabetes complications at baseline.”

The results were presented in table 3 as the followings:

Table 3. Secondary analysis and sensitivity analysis comparing outcomes during follow between statin users vs active comparators

Statin users

N (%) Active comparator

N (%) Adjusted

OR*

(95%CI) p-value

Incident diabetes complications cohort (513,125 statin users and 98,231 active comparators)

Renal disease progression composite outcome 62,994 (12.3) 6,447 (6.6) 1.18 (1.14-1.21) <0.001

Incident Diabetes with ophthalmic manifestations 22,236 (4.3) 1,205 (1.2) 1.36 (1.28-1.46) <0.001

Incident Diabetes with neurological manifestations 51,931 (10.1) 4,130 (4.2) 1.19 (1.15-1.24) <0.001

Any retinopathy & its complications (post-hoc outcome) 41,149 (8.0) 2,965 (3.0) 1.24 (1.20-1.30) <0.001

This article offers valuable information that suggests further research on renal, ophthalmic and neurologic manifestations of statin use is warranted.

Response: We thank the reviewer for these comments. We have added statin duration-based analysis stratifying patients with statin use duration, which was informative and open the door for further research that is designed a priori to examine effects of statin duration on diabetes compilations.

The methods section now states in Page 12, lines 247-250:

“ 4. Statin duration-based analysis: We stratified statin users by duration of statin use as < 3 year of statin use, or > 3 years of statin use. Each stratum of statin users was compared to nonusers for risk of each outcome in a separate logistic regression model adjusting for the propensity score and duration of follow up.”

The results of these additional subgroup analyses were added to table 3

Table 3. Secondary analysis and sensitivity analysis comparing outcomes during follow between statin users vs active comparators

Statin users

N (%) Active comparator

N (%) Adjusted

OR*

(95%CI) p-value

Statin users for < 3 years of statin use vs nonusers (172,123 statin users and110,195 active comparators)

Renal disease progression composite outcome 15,101 (8.8) 7,839 (7.1) 1.02 (0.99-1.05)** 0.17

Incident Diabetes with ophthalmic manifestations 4,469 (2.6) 1,713 (1.6) 1.04 (0.98-0.10)** 0.16

Incident Diabetes with neurological manifestations 9,163 (5.3) 4,969 (4.5) 0.84 (0.81-0.88)** <0.001

Any retinopathy & its complications (post-hoc outcome) 11,273 (6.6) 4,691 (4.3) 1.05 (1.00-1.08)** 0.02

Statin users for > 3 years of statin use vs nonusers (423,456 statin users and 110,195 active comparators)

Renal disease progression composite outcome 63,865 (15.1) 7,839 (7.1) 1.19 (1.16-1.22)** <0.001

Incident Diabetes with ophthalmic manifestations 25,733 (6.1) 1,713 (1.6) 1.34 (0.27-1.41)** <0.001

Incident Diabetes with neurological manifestations 52,682 (12.4) 4,969 (4.5) 1.25 (1.20-1.29)** <0.001

Any retinopathy & its complications (post-hoc outcome) 49,887 (11.8) 4,691 (4.3) 1.19 (1.15-1.23)** <0.001

* Odds ratio adjusted for propensity score except when indicated differently

** Odds ratio adjusted for propensity score and duration of follow up

We also added in the result section the following texts (page 29, last paragraph):

“Statin duration analysis showed that statin users for < 3 years have no increased risk of the primary outcomes and may be decreased risk of incident diabetes with neurological manifestation. However, statin users for 3 years or more had increased risks of all outcomes.”

In the discussion section, we added the followings in page 32, lines 369-374, we added:

“Additionally, our duration-based analysis may offer an insight into some aspects of the conflicting results in the literature since it suggests that statin use in our study was associated with risk of outcomes in those who used statins for longer duration (≥ 3 years) but not shorter duration (< 3 years). However, since our duration-based analysis was secondary post-hoc analysis, interpreting its findings should be considered exploratory indicating necessity of prospectively designed further research with this analysis defined a priori.”

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PLoS One. doi: 10.1371/journal.pone.0269982.r003

Decision Letter 1

James M Wright

2 Jun 2022

Statins and renal disease progression, ophthalmic manifestations, and neurological manifestations in Veterans with diabetes: A retrospective cohort study

PONE-D-21-36306R1

Dear Dr. Mansi,

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PLoS One. doi: 10.1371/journal.pone.0269982.r004

Acceptance letter

James M Wright

13 Jul 2022

PONE-D-21-36306R1

Statins and renal disease progression, ophthalmic manifestations, and neurological manifestations in Veterans with diabetes: A retrospective cohort study

Dear Dr. Mansi:

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Data Availability Statement

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PERMALINK

Statins and renal disease progression, ophthalmic manifestations, and neurological manifestations in veterans with diabetes: A retrospective cohort study

Ishak A Mansi

Matheu Chansard

Ildiko Lingvay

Song Zhang

Ethan A Halm

Carlos A Alvarez

Roles

Abstract

Background

Methods

Results

Conclusions

Introduction

Methods

Study design

Study intervals

Outcomes

Primary outcomes

Secondary outcomes

Negative control outcomes

Cohort characterization

Primary analysis

Secondary analyses

Sensitivity analysis

Post-hoc analysis

Other statistical analysis details

Results

Table 1. Baseline characteristics of propensity score-matched statin users and active comparators.

Primary analysis

Table 2. Risk of outcomes during follow up period in propensity score matched cohort of statin users in comparison to active comparators.

Secondary analysis

Table 3. Secondary analysis and sensitivity analysis comparing outcomes during follow between statin users vs active comparators.

Table 4. Hazard/Subhazard ratio of outcomes in statin users in comparison to nonusers.

Post-hoc analysis

Discussion

Table 5. Number needed to be exposed for one additional harm (NNEH) from this study and number needed to treat (NNT) for cardiovascular benefit from other studies.

Supporting information

Acknowledgments

Disclaimer

Data Availability

Funding Statement

References

Decision Letter 0

James M Wright

Roles

Transfer Alert

Author response to Decision Letter 0

Decision Letter 1

James M Wright

Roles

Acceptance letter

James M Wright

Roles

Associated Data

Supplementary Materials

Data Availability Statement

ACTIONS

PERMALINK

RESOURCES

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