Published online Jan 24, 2025. doi: 10.5306/wjco.v16.i1.99240
Revised: September 9, 2024
Accepted: October 11, 2024
Published online: January 24, 2025
Processing time: 104 Days and 17.1 Hours
Proton pump inhibitors (PPIs) are widely used, including among cancer patients, to manage gastroesophageal reflux and other gastric acid-related disorders. Re
To investigate the association between PPI use and all-cause mortality among cancer patients by a comprehensive analysis after adjustment for various con
This retrospective cohort study used data from the TriNetX research network, with electronic health records from multiple healthcare organizations. The study employed a new-user, active comparator design, which compared newly treated PPI users with non-users and newly treated histamine2 receptor antagonists (H2RA) users among adult cancer patients. Newly prescribed PPIs (esomeprazole, lansoprazole, omeprazole, pantoprazole, or rabeprazole) users were compared to non-users or newly prescribed H2RAs (cimetidine, famotidine, nizatidine, or ranitidine) users. The primary outcome was all-cause mortality. Each patient in the main group was matched to a patient in the control group using 1:1 propen
During the follow-up period (median 5.4 ± 1.8 years for PPI users and 6.5 ± 1.0 years for non-users), PPI users demonstrated a higher all-cause mortality rate than non-users after 1 year, 2 years, and at the end of follow up (HRs: 2.34-2.72). Compared with H2RA users, PPI users demonstrated a higher rate of all-cause mortality HR: 1.51 (95%CI: 1.41-1.69). Similar results were observed across sensitivity analyses by excluding deaths from the first 9 months and 1-year post-exposure, confirming the robustness of these findings. In a sensitivity analysis, we analy
PPI use among cancer patients was associated with a higher risk of all-cause mortality compared to non-users or H2RA users. These findings emphasize the need for cautious use of PPIs in cancer patients and suggest that alternative treatments should be considered when clinically feasible. However, further studies are needed to corro
Core Tip: Proton pump inhibitors (PPIs) are commonly used medications. Recent studies have raised concerns regarding increased all-cause and cause-specific mortality with PPIs. However, limited studies have addressed this issue in cancer patients. In addition, an association between PPIs and the mortality risk in unselected cancer populations remains uncertain. We investigated the association between PPI use and all-cause mortality in patients diagnosed with cancer. PPI use among cancer patients was associated with a higher risk of all-cause mortality compared to non-users or histamine-2 receptor antagonist users. These results strongly suggest the need for cautious use of PPIs in cancer patients and indicate that alternative treatments should be considered when clinically feasible.
- Citation: Krishnan A, Schneider CV, Walsh D. Proton pump inhibitors and all-cause mortality risk among cancer patients. World J Clin Oncol 2025; 16(1): 99240
- URL: https://www.wjgnet.com/2218-4333/full/v16/i1/99240.htm
- DOI: https://dx.doi.org/10.5306/wjco.v16.i1.99240
Proton pump inhibitors (PPIs) are the most widely prescribed drug groups and are also available for sale over the counter without a prescription in several countries[1]. PPI use has increased rapidly over the past decade[2]. They are considered very safe in the general population, but there is growing concern regarding long-term safety. Noninterventional studies have shown associations between the use of PPIs and various outcomes, including alcoholic liver disease, cancer, cardiovascular disease, chronic kidney disease, dementia, and pneumonia[3]. Furthermore, recent studies have raised concerns regarding increased all-cause and cause-specific mortality with PPIs[3-5].
In a recent prospective study, more than 25% of cancer patients undergoing anticancer treatment used PPIs[6]. However, this study suggests that the use of PPIs is prevalent in cancer patients. Recent studies found associations between PPIs and excess cause-specific and all-cause mortality[7-9]. Concerns have also been raised about the increase in all-cause and cause-specific mortality associated with PPI use[10]. Limited studies have addressed this issue; despite the available literature, several knowledge gaps persist. Notably, most studies focused on specific cancer types or lacked a robust design to assess the diverse landscape of cancer patients. Furthermore, one study showed that after adjusting for confounders, such as overall health status and longstanding diseases, regular PPI use was not associated with a greater risk of all-cause mortality[11].
An association between PPIs and the mortality risk in unselected cancer populations remains uncertain. Additionally, pharmacoepidemiologic studies are susceptible to protopathic bias. First, methodological limitations and heterogeneity across individual studies are a challenge. Second, the potential influence of confounding factors, such as cancer stage, comorbidities, and concomitant medications, has been inconsistently addressed[8,9]. Third, the duration and cumulative effect of PPI use on mortality outcomes require further exploration. These discrepancies highlighted the need for a comprehensive and well-designed study to clarify the relationship of PPIs to all-cause mortality in cancer.
Studies are required to bridge this gap by providing a broad analysis of the association between chronic PPI use and all-cause mortality in cancer patients. Hence, addressing the link between PPIs and all-cause mortality in cancer patients is essential for optimizing treatment strategies. In addition, understanding the potential risks or benefits of PPIs in cancer is necessary for adjusting patient care. Therefore, this study aimed to investigate the association between PPI use and all-cause mortality in patients diagnosed with cancer.
This large, population-based, retrospective cohort study was conducted using the TriNetX research network (Cambridge, MA, United States). TriNetX is a federated multicenter research network that provides real-time access to an anonymized dataset from participating healthcare organizations' electronic health records (EHR). Details of the data source, quality checks, and diagnosis codes used for selection [according to a predefined international classification of diseases (ICD)-9 and ICD-10 codes] are described in the Supplementary Material. Details of the TriNetX network are described in previous studies[12,13]. We followed the Strengthening the Reporting of Observational Studies in Epidemiology reporting guideline.
We identified all adult (aged ≥ 18 years) patients with a cancer diagnosis between January 1, 2010 and December 31, 2022. We adopted a new-user, active comparator design for our study, comparing patients who were newly treated with PPIs (esomeprazole, lansoprazole, omeprazole, pantoprazole, or rabeprazole) with non-users. We used non-users as primary analysis controls, defined as either histamine-2 receptor antagonists (H2RAs) or PPIs. We matched new PPI users to non-users by propensity scores. If we were to consider individuals on PPIs as exposed at the time of cancer diagnosis, it could introduce an immortal time bias because mortality cannot occur before the first use of PPI after diagnosis. At cohort entry, all patients were required to have at least 1 year follow-up. Finally, as recommended, we used a lag time of 6 months to allow for a sufficient latency period and to minimize reverse causality (protopathic bias)[14,15].
The primary outcome was all-cause mortality.
The propensity score matching (PSM) was performed using 1:1 to reduce the confounding effects. The covariates were adjusted in the PSM model for priori-identified potential confounders, such as age, sex, race/ethnicity, nicotine dependence, alcohol dependence, body mass index, cancer type, comorbidities, cancer treatment, and medications (Table 1). Logistic regression was used to obtain the propensity scores, and a greedy nearest-neighbor matching algorithm performed the matching with a caliper of 0.1 pooled SD. The balance of potential confounding variables was evaluated using standardized mean differences (SMD) with a threshold set a priori at 0.10. We used SMD to measure the magnitude of differences between the groups (rather than the P value) due to their insensitivity to sample size. Logistic regression using both Python (Python Software Foundation, Wilmington, Delaware, United States) and R 3.4.4 software (R Foundation for Statistical Computing, Vienna, Austria) to ensure the outputs matched and the order of the rows in the covariate matrix was randomized to eliminate this bias.
| Variables | Before the propensity score match | After the propensity score match | ||||
| PPI users (n = 48554) | Non-users (n = 2949116) | SMD | PPI users (n = 48452) | Non-users (n = 48452) | SMD | |
| Age (years) | 64.9 ± 12.2 | 62.4 ± 15.6 | 0.1803 | 64.9 ± 12.2 | 64.7 ± 12.8 | 0.0120 |
| Sex (female) | 20773 (428) | 1494930 (50.67) | 0.1590 | 20738 (42.8) | 20146 (41.6) | 0.0247 |
| Ethnicity, Hispanic or Latino | 2790 (5.7) | 147470 (5.0) | 0.0331 | 2785 (5.7) | 2776 (5.7) | 0.0008 |
| Race | ||||||
| White | 32556 (67.05) | 1930606 (65.4) | 0.0336 | 32507 (67.1) | 32345 (66.7) | 0.0071 |
| Black or African American | 7694 (15.8) | 227813 (7.7) | 0.2539 | 7643 (15.8) | 7491 (15.5) | 0.0086 |
| Asian | 737 (1.5) | 88263 (2.9) | 0.0995 | 737 (1.5) | 442 (0.9) | 0.0556 |
| Others | 6502 (13.4) | 586750 (19.9) | 0.1753 | 6500 (13.4) | 7517 (15.5) | 0.0597 |
| Nicotine dependence | 9974 (20.5) | 129401 (4.4) | 0.5044 | 9872 (20.4) | 9991 (20.6) | 0.0061 |
| Alcohol dependence | 2220 (4.6) | 19796 (0.7) | 0.2460 | 2144 (4.4) | 1866 (3.8) | 0.0288 |
| BMI (kg/m2) | 29 ± 6.64 | 28.1 ± 6.27 | 0.1473 | 29 ± 6.64 | 29.2 ± 6.73 | 0.0198 |
| Cancer type | ||||||
| Digestive organs | 3890 (8.0) | 1852 (0.64) | 0.3683 | 3855 (7.9) | 436 (0.9) | 0.3482 |
| Thyroid and other endocrine glands | 511 (1.0) | 11107 (0.4) | 0.0803 | 506 (1.0) | 156 (0.3) | 0.0878 |
| Neuroendocrine tumors | 157 (0.3) | 3812 (0.1) | 0.0409 | 156 (0.3) | 111 (0.2) | 0.0177 |
| Ovary | 176 (0.4) | 3878 (0.1) | 0.0465 | 176 (0.3) | 52 (0.1) | 0.0528 |
| Cervix uteri | 206 (0.42) | 3150 (0.1) | 0.0617 | 204 (0.4) | 250 (0.1) | 0.0622 |
| Corpus uteri | 298 (0.6) | 6055 (0.2) | 0.0640 | 297 (0.6) | 113 (0.2) | 0.0585 |
| Breast | 2561 (5.3) | 56312 (1.9) | 0.1816 | 2541 (5.2) | 887 (1.8) | 0.1856 |
| Urinary tract | 1725 (3.5) | 13303 (0.4) | 0.2228 | 1719 (3.5) | 296 (0.6) | 0.2069 |
| Kidney | 3 816 (7.85) | 95657 (3.2) | 0.2026 | 3767 (7.8) | 3117 (6.4) | 0.0522 |
| Malignant neoplasm of bronchus and lung | 4034 (8.3) | 67074 (2.3) | 0.2720 | 3988 (8.2) | 3369 (6.9) | 0.0482 |
| Malignant melanoma | 3507 (7.2) | 50881 (1.7) | 0.2683 | 3473 (7.2) | 1018 (2.1) | 0.2428 |
| Prostate | 1969 (4.0) | 30803 (1.0) | 0.1919 | 1946 (4.0) | 548 (1.1) | 0.1830 |
| Others | 24704 (50.8) | 2567897 (86.1) | 0.4367 | 26679 (55.1) | 26899 (55.5) | 0.0134 |
| Comorbidities | ||||||
| Hypertension | 21340 (43.9) | 546208 (18.5) | 0.5706 | 21238 (43.8) | 21270 (43.9) | 0.0013 |
| Diabetes mellitus | 10626 (219) | 199682 (6.8) | 0.4418 | 10529 (21.7) | 10418 (21.5) | 0.0056 |
| Gastroesophageal reflux diseases | 13540 (27.9) | 126033 (4.3) | 0.6788 | 13454 (27.8) | 5132 (10.6) | 0.4470 |
| Peptic ulcers | 1102 (2.3) | 5925 (0.2) | 0.1881 | 1051 (2.2) | 374 (0.8) | 0.1163 |
| Gastroduodenitis | 867 (1.8) | 7790 (0.3) | 0.1515 | 858 (1.8) | 302 (0.6) | 0.1057 |
| Hyperlipidemia | 14567 (30.0) | 342093 (11.6) | 0.4655 | 14480 (29.9) | 13716 (28.3) | 0.0347 |
| Atrial fibrillation | 4260 (8.8) | 90521 (3.1) | 0.2435 | 4228 (8.7) | 3771 (7.8) | 0.0343 |
| Chronic lower respiratory diseases | 11122 (22.9) | 199314 (6.7) | 0.4665 | 11021 (22.7) | 10977 (22.6) | 0.0022 |
| Hypercholesterolemia | 7075 (14.6) | 174159 (5.9) | 0.2888 | 7021 (14.5) | 6663 (13.7) | 0.0212 |
| Cardiac arrhythmias | 6421 (13.2) | 107325 (3.6) | 0.3502 | 6337 (13.1) | 4982 (10.2) | 0.0872 |
| Coronary heart disease | 3575 (7.4) | 41413 (1.4) | 0.2942 | 3513 (7.2) | 2718 (5.6) | 0.0669 |
| Congestive heart failure | 5089 (10.5) | 63052 (2.1) | 0.3483 | 5001 (10.3) | 4704 (9.7) | 0.0204 |
| Cerebrovascular disease | 6662 (13.7) | 103190 (3.5) | 0.3706 | 6570 (13.6) | 6266 (12.9) | 0.0185 |
| Diabetic polyneuropathy | 1983 (4.1) | 26801 (1.0) | 0.2046 | 1945 (4.0) | 2082 (4.3) | 0.0142 |
| Glomerular diseases | 770 (1.6) | 8865 (0.3) | 0.1333 | 752 (1.5) | 564 (1.2) | 0.0335 |
| Chronic kidney disease | 6790 (13.9) | 114526 (3.9) | 0.3598 | 6708 (13.8) | 6350 (13.1) | 0.0216 |
| Peripheral vascular diseases | 4220 (8.7) | 53718 (1.8) | 0.3116 | 4149 (8.6) | 3444 (7.1) | 0.0542 |
| Diabetic retinopathy | 981 (2.0) | 16162 (0.5) | 0.1311 | 958 (1.9) | 1232 (2.5) | 0.0381 |
| Diabetic nephropathy | 1789 (3.7) | 25585 (0.868) | 0.1897 | 1754 (3.6) | 2040 (4.2) | 0.0304 |
| Diseases of pancreas | 1761 (3.6) | 15,072 (0.5) | 0.2202 | 1740 (3.6) | 673 (1.38) | 0.1417 |
| Diseases of gallbladder | 928 (1.9) | 9746 (0.3) | 0.1506 | 915 (1.9) | 545 (1.1) | 0.0627 |
| Diseases of biliary tract | 1371 (2.8) | 9373 (0.3) | 0.2026 | 1349 (2.8) | 535 (1.1) | 0.1219 |
| Cirrhosis of liver | 2259 (4.6) | 15246 (0.5) | 0.2629 | 2224 (4.6) | 1047 (2.2) | 0.1348 |
| Osteoporosis | 3338 (6.9) | 77419 (2.6) | 0.2008 | 3318 (6.8) | 2465 (5.1) | 0.0744 |
| Obstructive sleep apnea | 4034 (8.3) | 67074 (2.3) | 0.2720 | 3988 (8.2) | 3369 (6.9) | 0.0482 |
| Liver diseases | 5502 (11.3) | 58923 (2.0) | 0.3810 | 5403 (11.1) | 5334 (11.0) | 0.0045 |
| Cancer treatment | ||||||
| Chemotherapy | 3922 (8.1) | 112502 (3.8) | 0.1810 | 3887 (8.0) | 2419 (5.1) | 0.1231 |
| Antineoplastic and immunomodulating agents | 7450 (15.3) | 208407 (7.1) | 0.2647 | 7400 (15.3) | 4765 (9.8) | 0.1647 |
| Immunological agents | 3816 (7.9) | 95657 (3.2) | 0.2026 | 3767 (7.8) | 3117 (6.4) | 0.0522 |
| Radiotherapy | 872 (1.8) | 16379 (0.5) | 0.1153 | 870 (1.8) | 413 (0.8) | 0.0826 |
| Surgery | 5480 (52.5) | 769018 (26.1) | 0.5615 | 25381 (52.4) | 21120 (43.6) | 0.1767 |
| Targeted therapy | 2092 (4.3) | 9939 (0.3) | 0.2660 | 2057 (4.2) | 500 (1.0) | 0.2015 |
| Medications | ||||||
| Beta-blockers | 14581 (30.0) | 285348 (9.7) | 0.5277 | 14490 (29.9) | 10814 (22.3) | 0.1734 |
| Aspirin | 13275 (27.3) | 240151 (8.1) | 0.5192 | 13179 (27.2) | 10192 (21.0) | 0.1445 |
| NSAIDs usage | 20915 (43.1) | 464565 (15.7) | 0.6286 | 20813 (42.9) | 14519 (29.9) | 0.2724 |
| Hypoglycemic drugs | 6495 (13.4) | 123497 (4.2) | 0.3290 | 6424 (13.2) | 6558 (13.5) | 0.0081 |
| Insulin | 6951 (14.3) | 89333 (3.0) | 0.4094 | 6849 (14.1) | 6551 (13.5) | 0.0178 |
| Antiarrhythmics | 6274 (33.5) | 329864 (11.2) | 0.5564 | 16179 (33.4) | 11097 (22.9) | 0.2348 |
| Antilipemic agents | 16154 (33.3) | 358588 (12.1) | 0.5206 | 16064 (33.1) | 13083 (27.0) | 0.1345 |
| ACE inhibitors | 10817 (22.3) | 218846 (7.42) | 0.4273 | 10744 (22.2) | 8770 (18.1) | 0.1017 |
| Angiotensin II inhibitors | 6268 (12.9) | 137747 (4.7) | 0.2941 | 6232 (12.8) | 5092 (10.5) | 0.0733 |
| Diuretics | 4023 (28.9) | 269083 (9.1) | 0.5204 | 13928 (28.7) | 10575 (21.8) | 0.1597 |
| Vitamin D supplement | 8317 (17.1) | 150002 (5.1) | 0.3905 | 8261 (17.0) | 5233 (10.8) | 0.1813 |
| Vitamin E supplement | 1318 (2.7) | 30518 (1.0) | 0.1241 | 1309 (2.7) | 1033 (2.1) | 0.0371 |
| Calcium channel blockers | 0519 (21.7) | 190886 (6.4) | 0.4477 | 10437 (21.5) | 7842 (16.1) | 0.1372 |
| Antihypertensive combinations | 171 (0.3) | 2229 (0.1) | 0.0599 | 168 (0.3) | 197 (0.4) | 0.0098 |
| Opioids | 1369 (2.8) | 23224 (0.8) | 0.1531 | 1359 (2.8) | 678 (1.4) | 0.0981 |
| Immunosuppressants | 1958 (4.0) | 36586 (1.2) | 0.1749 | 1945 (4.0) | 1056 (2.2) | 0.1061 |
| Antiemetics | 16473 (33.9) | 320517 (10.9) | 0.5755 | 16382 (33.8) | 9934 (20.5) | 0.3026 |
| Antidepressants | 11404 (23.5) | 230648 (7.8) | 0.4415 | 11331 (23.4) | 7563 (15.6) | 0.1972 |
| Anticonvulsants | 8945 (18.4) | 139173 (4.7) | 0.4386 | 8875 (18.3) | 5306 (10.9) | 0.2095 |
| Laxatives | 17542 (36.1) | 295981 (10.0) | 0.6512 | 17440 (35.9) | 10634 (21.9) | 0.3134 |
We used new users of an alternative acid suppression drug, H2RAs (cimetidine, famotidine, nizatidine, or ranitidine), as a control in the secondary analysis. We deliberately chose H2RAs as the comparator because H2RAs are a clinically relevant cohort used for indications similar to PPIs; hence, H2RAs were chosen as it was aimed to minimize confounding by therapeutic indication. Patients with a history of concurrent prescription of PPIs and H2RAs at cohort entry were excluded to ensure a clear distinction between exposure groups. Furthermore, the study cohort included individuals who switched to or added on treatment between the study drug classes (PPI to H2RA or vice versa).
We conducted three sensitivity analyses to ensure robustness due to the heterogeneous nature of the study outcomes. In the first sensitivity analysis, we estimated study outcomes by excluding patients with outcomes 6 months and 1 year after the index event. This analysis was performed using the same methods as the primary analysis. The second analysis evaluated the influence of PPI on mortality using Cox proportional hazards models with a lag time of 9 and 12 months. In the third analysis, we compared former users based on whether they had a history of PPIs before cancer diagnosis.
All analyses were performed using the TriNetX real-time analytics platform. This approach involves dynamic and immediate data analysis, enabling continuous processing and interpretation of data as it is generated. Categorical variables were compared using the Pearson χ2 test and continuous variables by an independent-sample t-test. Continuous variables were expressed as mean ± SD and categorical variables as frequency and percentage. Analyses examined the outcome using Cox proportional hazards models. HRs and CIs, along with proportionality tests, were calculated using the R Survival package 3.2-3. The results were validated by comparing them with the output from SAS version 9.4. Patients were censored when the time window ended or the day after the last fact in their record. We utilized a 1:1 propensity matching strategy to establish comparable groups. In addition, we used this strategy to balance the covariates between the groups effectively. We incorporated a robust variance estimator in the Cox regression model to account for clustering within the 1:1 propensity-matched sample and address the loss of independence among individuals due to the matching procedure[16]. The robust variance estimator was essential to enhance the accuracy of our analytical approach and ensure the validity of the study's findings. A priori-defined two-sided alpha of < 0.05 was used for statistical significance.
Following PSM, the PPI and non-user characteristics were well-balanced (Supplementary Figure 1). Age was comparable between PPI users and non-users after matching (64.9 ± 12.2 years vs 64.7 ± 12.8 years; SMD = 0.012, Table 1). Post-matching, racial distribution showed minimal differences, with White individuals comprising 67.1% of PPI users and 66.7% of non-users (SMD = 0.0071). The prevalence of nicotine and alcohol dependence was effectively matched (20.4% vs 20.6%, SMD = 0.0061 for nicotine; 4.4% vs 3.8%, SMD = 0.0288 for alcohol, Table 1). Significant baseline disease medication intake and chronic conditions were closely matched. The mean follow-up was 5.4 ± 1.8 years for the PPI group and 6.5 ± 1.0 years for non-users.
The propensity score-matched analysis showed that PPI users had a higher mortality rate at all assessed time points compared to non-users. At 1 year, PPI users had a substantially higher mortality rate than non-users, with 8888 events in the PPI vs 3272 in the non-PPI group (HR = 2.72, 95%CI: 2.61-2.83, Table 2). After 2 years, there were higher than 13719 events in the PPI users vs 5276 in the non-users (HR = 2.66, 95%CI: 2.58-2.74, Table 2). Over the entire follow-up period, which averaged 5.4 ± 1.8 years for PPI users and 6.5 ± 1.0 years for non-users, the cumulative incidence of death was 23421 for PPI users and 11656 for non-users (HR = 2.34, 95%CI: 2.29-2.42, Table 2). The analysis revealed consistently elevated mortality risks across different time intervals in examining all-cause mortality concerning varying lag exposures for PPI compared to non-users.
| Outcome | PPI-users (n = 48452) | Non-users (n = 48452) | HR (95%CI) |
| At 1 year | 8888 | 3272 | 2.72 (2.61-2.83) |
| At 2 years | 13719 | 5276 | 2.66 (2.58-2.74) |
| Overall outcome during follow-up | 23421 | 11656 | 2.34 (2.29-2.42) |
A well-matched population was found in the PPI vs H2RA groups (n = 44, 834 each) after PSM (Supplementary Figure 2). The mean follow-up was 4.6 ± 1.3 years for PPIs and 3.8 ± 1.6 years for H2RAs. After 1 year, mortality was notably higher among PPI users (8393) than H2RA users (7980), HR 1.51 (95%CI: 1.41-1.69, Table 3). The difference in mortality rates between the two groups persisted for two years, with 12950 events for PPI users and 11989 for H2RA users (HR = 1.16, 95%CI: 1.04-1.39, Table 3). Over the entire follow-up, the cumulative mortality was 18304 for PPI users vs 17146 for H2RA users (HR = 1.17, 95%CI: 1.05-2.16).
| Outcome | PPI-users (n = 44834) | H2RA-users (n = 44834) | HR (95%CI) |
| At 1-year | 8393 | 7980 | 1.51 (1.41-1.69) |
| At 2-years | 12950 | 11989 | 1.16 (1.04-1.39) |
| Overall outcome during follow-up | 18304 | 17146 | 1.17 (1.05-2.16) |
Supplementary Tables 1-3 show the results of the sensitivity analyses. When extending the lag exposure to 9 months, the mortality risk remained significantly elevated, with HR = 2.45 (95%CI: 2.39-2.52). Further increasing the lag to 12 months resulted in 13898 mortality events for PPI users and 7009 for non-users, HR = 2.41 (95%CI: 2.34-2.48, Supplementary Table 1). The second analysis evaluated the impact of PPI use on all-cause mortality, excluding early outcomes. After excluding early events in the first six months, a similar pattern emerged when extending the exclusion to the first 6 months. The analysis included 44453 PPI and 48805 non-users, 17166 deaths in the PPI vs 8249 non-users during the follow-up. The HR remained consistent at 2.54 (95%CI: 2.43-2.61). We extended these sensitivity analyses by excluding the first 12 months from the index period. The mortality count was 12433 for PPI users and 5759 for non-users, HR = 2.48 (95%CI: 2.39-2.62, Supplementary Table 2). In the third analysis, we examined all-cause mortality between former PPI users and individuals who never used PPIs for insights into the long-term effects of past PPI use. At 1-year follow-up, a significant difference in mortality rates between former users and non-users (HR = 1.84, 95%CI: 1.82-1.96, Supplementary Table 3) was found. Former PPI users had an 84% higher mortality risk within one year compared to those who never used PPIs.
This large, retrospective cohort study conducted using a well-established research network revealed significant negative associations between PPI use and higher all-cause mortality among cancer patients. These findings contribute impor
Across all time points analyzed, PPI users had a significantly increased risk of the evaluated outcome than non-users and H2RA users. This consistent pattern highlights a potential association between PPI usage and death, warranting further investigation into the long-term effects of PPI therapy. These findings were persistent, even as the lag period increased. Although there was a trend of lower risk with longer lag times, the consistently high HRs emphasize the importance of cautious use and careful monitoring during long-term PPI therapy. The sensitivity analyses showed a persistent and significantly greater all-cause mortality with PPI use across various cohorts and timeframes, even when early mortality was excluded. Thus, it emphasizes the need for careful prescribing and ongoing management of PPI therapy, particularly around the duration of use and potential long-term health implications.
The substantially higher mortality rate among former PPI users vs non-users within the first year highlights a critical concern regarding the long-term health implications of PPI usage. This elevated risk accentuates the importance of monitoring and possibly re-evaluating the necessity and duration of PPI therapy in clinical practice, particularly con
The results of our study are consistent with prior research indicating potential adverse outcomes associated with prolonged PPI use, including increased risks of cardiovascular disease[17], chronic kidney disease[18], and infections[19]. However, excess mortality risk among cancer patients, as indicated by our HRs, accentuates a potentially unique interaction between PPI use and cancer. The mechanisms may relate to the effects of PPIs on the absorption of vital nutrients[20], alterations of gut microbiota[21], and interference with the metabolism of chemotherapeutic agents[22]. Further research is needed to comprehensively understand the potential consequences of prolonged PPI usage in individuals undergoing cancer treatment.
Post-diagnostic PPI use is associated with higher cancer mortality, particularly in ovarian cancer[8]. In a cohort study, PPI use after colorectal cancer diagnosis or survivorship was associated with increased all-cause mortality[23]. Moreover, in the Veterans Affairs Cancer Center registry[24], post-diagnosis use of acid-suppressant medications, like PPIs, was associated with greater mortality in patients with gastric non-cardia cancer and hepatocellular carcinomas. Concomitant PPI use was also significantly associated with lower immune checkpoint inhibitor efficacy and greater risk of death in advanced cancer[22].
Our analysis showed that the highest HRs were predominantly seen in individuals who had used PPIs for less than two years. Interestingly, the HRs gradually decreased as the duration of PPI use extended beyond this period; this trend may be due to the underlying comorbidity conditions where PPIs are commonly prescribed for managing gastrointestinal symptoms and as a preventive measure against gastrointestinal damage from prolonged nonsteroidal anti-inflammatory drugs use among cancer patients[24-26].
Compared to earlier studies that often focused on specific cancer sites or smaller patient cohorts, our study has a robust sample size and diverse cancer patients. This enhances generalizability. For example, a previous study did not find an association between PPI use and increased mortality among general populations[10]; however, our cancer-specific patient population appears at higher risk, possibly due to their different baseline health status and unique metabolic and the
Our study had several strengths. First, methodological rigor allows a nuanced assessment of PPI impacts in real-world settings. It is the largest study to date to examine the association of PPI with all-cause mortality in cancer patients, consisting of 'real-world' data with long follow-up times. Second, the comprehensive cohort design and PSM minimized confounding variables with narrower CIs and higher precision. Third, the cohort was restricted to new users, eliminating bias associated with prevalent users[26]. Fourth, comparing PPIs with an HR2A comparator in secondary analysis likely minimized confounding by indication. Fifth, we used varying exposure times, eliminating immortal time bias by allowing a cohort to contribute time to different exposure categories during the follow-up period[27]; however, PPI use was still associated with higher mortality. Finally, our results remained consistent across several sensitivity analyses.
This study also has some limitations. First, the retrospective design and the reliance on an EHR-based database limited our results. Whenever patient information is translated into diagnosis codes, data from EHR-based databases are susceptible to errors in coding. Standardized measures identified cases to minimize documentation errors. Second, PPIs and H2RAs are available over the counter in the United States, potentially leading to some missing medication infor
Clinicians should weigh the risks and benefits of prolonged PPI use in cancer patients, considering alternative management strategies for acid-related symptoms when feasible. This is particularly relevant during chemotherapy, where PPI use might negatively impact treatment efficacy or exacerbate adverse effects. Regular reassessment of the necessity of PPI therapy should focus on minimizing the duration of use. Further prospective studies and randomized controlled trials could clarify the causative mechanisms behind the observed higher cancer mortality associated with PPIs. Studies exploring the interaction between PPI use and specific cancer therapies could also provide insights into how best to manage individually[28].
In conclusion, our study highlights a notable link between the use of PPIs and increased overall mortality in individuals with cancer. This indicates the need for heightened caution when prescribing PPIs to this especially vulnerable group, considering alternative approaches for managing acid-related symptoms, such as lifestyle modifications, non-PPI medications, or complementary therapies whenever possible. Although our study provides novel information, ran
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