Risk of chronic kidney disease in patients with kidney stones—A nationwide cohort study

Abstract

Background Chronic kidney disease (CKD) and kidney stones are common in Taiwan; in particular, CKD has a high prevalence but low self-awareness rate. CKD-related risk factors such as diabetes, hypertension, and nephrotoxic drugs are well-known and uncontested; however, kidney stones are relatively less studied and easily overlooked as a risk factor. The objective of this study was to investigate whether kidney stones are a risk factor for CKD.

Methods We conducted a nationwide population-based matched cohort study to assess the risk of incident CKD in people with kidney stones. Data on incident stones formers in the year 2001—excluding those with a history of CKD—were obtained from Taiwan’s National Health Insurance database. Stone formers were matched (1:4) to control subjects according to sex, age, and index date. The total observation period of the study was 10 years, and the primary end-point was the occurrence of CKD. Student’s t-test and Chi-squared test were used to compare continuous and categorical data, respectively. Logistic regression was used to calculate the odds ratio of kidney stone patients with incident CKD relative to the control group. Cox proportional hazard regression model was used to obtain the hazards ratio for development of incident CKD among patients with kidney stones.

Results The incidence of CKD in the kidney stone cohort was 11.2%, which was significantly higher than that of the control group (P < .001). Survival analysis showed that the stones cohort was 1.82 times more likely to experience CKD than the controls. Age, sex, hypertension, diabetes mellitus, and hyperlipidemia increased the risk of CKD incidence (1.04, 1.27, 1.55, 3.31, and 1.25 times, respectively).

Conclusion Kidney stones are a definite risk factor for CKD; therefore, patients with stones are suggested to undergo regular renal function monitoring and receive appropriate treatment to avoid CKD.

1. Background

The prevalence of urinary tract stones differs by region worldwide and ranges from 5–10%. Recent data shows that kidney stones affect approximately 1 in 11 people in the United States.¹ According to Huang et al., the prevalence rate of upper urinary tract stones in Taiwan is as high as 7.38%, with predilection higher in males than in females; furthermore, the recurrence rates were higher in males than in females in their study.²

The prevalence of chronic kidney disease (CKD) is increasing in developed countries such as the United States of America and Japan. Taiwan also has a high incidence and prevalence of CKD, and Taiwan has the highest prevalence of end-stage renal disease (ESRD) in the world.³ Wen et al. reported that the national prevalence of CKD in Taiwan was 11·93%, but the rate of awareness of the disease among the patients in their study (462,293 individuals aged older than 20 years) was only 3·54%.⁴

Kidney stone is not a major contributor to ESRD. Jungers P et al. reported the overall proportion of nephrolithiasis-related ESRD was only 3.2%.⁵ According to the United States Renal Data System 2011 Annual Data Report, only 2% of ESRD were caused by urologic disease which included kidney stones.⁶ In other words, kidney stones accounted for few cases of ESRD (< 2%) compared with other major contributors such as diabetes, glomerulonephritis, and hypertension. With such a relatively low proportion of contribution by kidney stones, there might be a tendency to underestimate or ignore the influence of kidney stones on CKD.

Intuitively, one might expect kidney stones to be a risk factor for CKD. Symptomatic stones result in pain secondary to urinary tract obstruction and hematuria due to irritation by the stones. Frequent exposure to nephrotoxic analgesics are a well-known risk factor for CKD. Kidney stones also share many common risk factors with CKD such as low water intake, high protein diet,⁷ bacterial infection,⁸ and urinary tract anomalies.^9,10 In addition, examination using contrast medium¹¹ and the use of therapeutic methods¹² or even surgical procedures on stone-forming patients might prove harmful to kidney function.

The presence of kidney stones is an infrequent cause of renal failure; however, their occurrence secondary to several kinds of rare hereditary disorders, such as Dent disease, primary hyperoxaluria, 2-8-hydroxyadenine crystalluria, and cystinuria, has been associated with progressive loss of renal function and ESRD at a young age.^13–16 In addition, struvite (infection stones), which form due to repeated bacterial infection, can lead to obstructive nephropathy through the formation of staghorn stones and accounts for the majority of ESRD cases caused by nephrolithiasis.⁵

However, most cases of kidney stones are not hereditary. They may occur secondary to factors such as climate, water, dietary habits, living environment, and occupation. The causes for the development of kidney stones in these cases vary, and are infrequently associated with end-stage renal disease. Moreover, local and small-scale studies have found that kidney stones may be a contributing factor in a small percentage of patients with end-stage renal failure and that they may play an influential role in the development of CKD.¹⁷ A case–control study reported a significantly higher prevalence of pre-ESRD kidney stones in African-American hemodialysis patients compared with the general African-American population.¹⁸ Another cross-sectional study revealed decreased creatinine clearance in stone formers compared with normal individuals.¹⁹ However, strong evidence of decreased renal function secondary to kidney stones was not observed in either of the aforementioned studies. A population-based cohort study based in Olmsted County, Minnesota, found that stone formers were at increased risk for a clinical diagnosis of CKD, a sustained elevated serum creatinine level, and a sustained reduced glomerular filtration rate (GFR); therefore, the authors concluded that kidney stones are a risk factor for CKD.²⁰ The aforementioned study provided strong evidence for the causal relationship between kidney stones and CKD, but the sample was limited to a local county with a small population.

Thus, the present retrospective, nationwide, population-based study was conducted to assess the risk of incident CKD in people with kidney stones in a general population.

2. Methods

3. Results

The demographics and potential confounders of the study population are illustrated in Table 1. A total of 4,197 kidney stone patients were identified using the following criterion: at least two appearances of the kidney stones–related ICD-9-CM diagnostic codes. The number of males (2,762; 65.8%) was twice the number of females (1,435; 34.2%) in this study. The average age of the kidney stones cohort was 46.51 ± 14.69 years.

Matching of stones cohort at a ratio of 1:4 according to sex, age, and index date resulted in the identification of 16,788 cases without kidney stones. Cases with kidney stones or a history of CKD over the previous three years (1998–2000) were excluded.

The observation period for the incidence of CKD was 10 years (2001 to 2010). CKD was confirmed by the appearance of CKD-related ICD-9 diagnostic codes (at least twice) during the observation period. Thus, 1,505 cases were diagnosed with CKD, accounting for 7.2% of the stones cohort.

Chi-square test results revealed a significant difference in the incidence of CKD between the stones cohort and the controls (Table 2).

Binary logistic regression showed that the stone formers had a higher risk of CKD (OR, 1.94; P < .001; Table 3) after adjustment for potential confounders, including age, gender, comorbidities (hypertension, diabetes, hyperlipidemia, and cardiovascular disease). Cox proportional hazards regression models adjusted for age, gender, and comorbidities used to assess the risk for incident CKD in the stone formers revealed a HR of 1.82 (P < .001; Table 4). The survival curves of CKD-free probabilities for patients with or without kidney stones are illustrated in Fig. 2; CKD-free probability in the kidney stones cohort was significantly lower than that in the non–kidney stones controls (P < .01)

4. Discussion

After adjusting for potential confounders, we found that patients with kidney stones were 1.82 times more likely to develop CKD during the 10-year follow-up period (HR = 1.82; 95% CI 1.63–2.02) compared with the general population. To the best of our knowledge, this is the first nationwide population-based cohort study to investigate the risk of CKD in patients with kidney stones.

This study focused on acquired or environmental associated kidney stones but not hereditary related cases. To confirm that the stone cohort comprised patients with acquired stones, cases presenting with a history of kidney stones for the past three years (1998–2000) were excluded. Therefore, the exposure times between the cases in the stone cohort were similar. The inclusion criterion for the incident stone cases was the appearance of ICD-9-CM diagnosis codes of kidney stone (a minimum of two times because a single appearance of the code may prove as a false positive).

CKD development requires a long period of exposure to the risk factors; therefore, we observed the patients for a period of 10 years.²¹ As with kidney stones, the identification of CKD also relied on the appearance (at least two times) of the ICD-9-CM diagnosis codes associated with CKD.

Potential confounders were identified under conditions that were more stringent: at least three appearance of the ICD-9-CM codes for CKD-related comorbidities. In addition to diabetes, hypertension, hyperlipidemia, and cardiovascular diseases were more common in the stone cohort than in the controls (Table 1).

Kidney stones are more prevalent in middle-aged males, with a male to female ratio of approximately 2:1. The incidence of CKD in patients with kidney stones was approximately 11.2%, which was a crude estimation based on 470 patients out of the 4197 experiencing CKD in the kidney stones cohort group.

Kidney stones are the predictors and risk factors of CKD, and their importance in the present study can be noted by their high prevalence rates (5–10%), OR (1.94), and HR (1.82), all of which were second to only those of diabetes (Tables 3 and 4).

The strength of the current study is that it is a nationwide population-based cohort study that could demonstrate the causal relationship between kidney stones and CKD. Because of the mandatory insurance policy of the NHI, the integrity and representativeness of the information is thorough compared with other regional research surveys. Moreover, Taiwan’s NHI has been in existence for more than two decades (since 1995),^22,23 providing a sufficient time period to make observations; the rate of data loss is very low, unless the insurant has emigrated to another country or the insurance is suspended because of other special reasons. Zero values were found to be missing during the sampling of this study. Therefore, our data, which covers a national source of information, are highly representative and can be used as reference for developing epidemiology, public health research, health care policy, and clinical guidelines. Although several local and small-scale studies have explored the relationship between kidney stones and CKD,^17–20 a nationwide population-based cohort study has not been published so far.

However, this study has some limitations. First, the NHIRD does not provide detailed information on precise relevant clinical variables such as laboratory data and imaging or pathologic findings for the kidney disease. Information about the severity of kidney stones and staging of CKD are also lacking. Second, the level of evidence derived from cohort studies is generally lower than that from randomized trials because of potential biases related to unknown confounders that cannot be adjusted for.²⁴ Third, data on symptoms related to kidney stones, such as hematuria, colicky pain, obstruction, and infection, were unavailable, as was information on relevant therapies, such as lithotripsy or stone surgery, and medications used during treatment. These factors may have potentially affected the analysis in the current study.

Kidney stones contributed to only a small proportion of ESRD patients receiving hemodialysis,^5,6 and the contribution was much lower than that of diabetes, hypertension, and hyperlipidemia. Given the slow progression of the clinical course of CKD and the minimal signs and symptoms encountered, patients often neglect the presence of this condition. Furthermore, the effect of kidney stones on CKD is probably underestimated by the clinical doctors, government health authorities, health care institutions, and policy decision makers.

5. Conclusion

In conclusion, the results of the present study suggest that kidney stones are a clear and independent risk factor for CKD; hence, patients with kidney stones should receive regular kidney function monitoring and obtain appropriate treatment to prevent or delay the development and progression of CKD.

Abbreviations

CKD                Chronic kidney disease

ESRD              End stage renal disease

GFR                            Glomerular filtration rate

NHI                 National Health Insurance

NHIRD                        NHI Research Database

ICD-9-CM      International Classification of Diseases Ninth Revision Clinical Modification

OR                              Odds ratio

HR                              Hazzard ratio

Declarations

Ethics approval and consent to participate

This study was approved by the ethics committee of China Medical University & Hospital Research Ethics Center [CTU103-1/CMUH103-REC1-088], and it adhered to the principles of the Declaration of Helsinki. Because the data were analyzed anonymously, the ethical committee waived the need for written consent.

Consent for publication

Data was obtained from NHI research database after ethics committee approval. No direct patient contact including consent took place.

Availability of data and materials

Data are available from the National Health Insurance Research Database (NHIRD) published by Taiwan National Health Insurance (NHI) Bureau. Due to legal restrictions imposed by the government of Taiwan in relation to the “Personal Information Protection Act”, data cannot be made publicly available. Requests for data can be sent as a formal proposal to the NHIRD (http://nhird.nhri.org.tw).

Competing interests

The authors declare that they have no competing interests.

Funding

No financial support was used for this study.

Authors' contributions

TFC, CTH contributed to conception and design, TFC performed the literature search, SFL acquisition of data, and TFC, CTH, SFL to analysis and interpretation; TFC, CTH were involved in drafting the manuscript, CTH, HCH, SFL,MWL in revising it critically for important intellectual content; ; all authors have given final approval of the version to be published.

Acknowledgements

This study was supported by a grant from the Central Taiwan University of Science and Technology (CTU100-2). This study was conducted partly using the data from the National Health Insurance Research Database that was provided by the Bureau of National Health Insurance, Department of Health and managed by National Health Research Institutes.

Authors' information

Tzung-Fang Chuang, Email: [email protected]

Hung-Chang Hung, Email: [email protected]

Shu-Fen Li, Email: [email protected]

Mei-Wen Lee, Email: [email protected]

Chin-Tun Hung, Email: [email protected]

References

1. Scales CD, Smith AC, Hanley JM, Saigal CS. Urologic Diseases in America Project. Prevalence of kidney stones in the United States. Eur Urol. 2012;62(1):160–165.
2. Huang WY, Chen YF, Carter S, Chang HC, Lan CF, Huang KH. Epidemiology of upper urinary tract stone disease in a Taiwanese population: a nationwide, population based study. J Urol. 2013;189(6):2158–2163.
3. Saran R, Robinson B, Abbott KC, et al. US renal data system 2016 annual data report: epidemiology of kidney disease in the United States. Am J Kidney Dis. 2017;69(3):A7–A8.
4. Wen CP, Cheng TY, Tsai MK, et al. All-cause mortality attributable to chronic kidney disease: a prospective cohort study based on 462 293 adults in Taiwan. Lancet. 2008;371(9631):2173–2182.
5. Jungers P, Joly D, Barbey F, Choukroun G, Daudon M. ESRD caused by nephrolithiasis: prevalence, mechanisms, and prevention. Am J Kidney Dis. 2004;44(5):799–805.
6. Collins AJ, Foley RN, Herzog C, et al. US renal data system 2010 annual data report. Am J Kidney Dis. 2011;1(57):A8.
7. Gottlieb S. High protein diet brings risk of kidney stones. BMJ. 2002;325(7361):408.
8. Griffith DP, Musher DÁ, Itin C. Urease. The primary cause of infection-induced urinary stones. Invest Urol. 1976;13(5):346–350.
9. Basaklar AC, Kale N. Experience with childhood urolithiasis. BJU Int. 1991;67(2):203–205.
10. Milliner DS. Murphy ME. Urolithiasis in pediatric patients. In Mayo Clinic Proceedings. 1993, March; Vol. 68, No. 3, pp. 241–248. Elsevier.
11. Murphy SW, Barrett BJ, Parfrey PS. Contrast nephropathy. J Am Soc Nephrol. 2000;11(1):177–182.
12. Williams CM, Kaude JV, Newman RC, Peterson JC, Thomas WC. Extracorporeal shock-wave lithotripsy: long-term complications. Am J Roentgenol. 1988;150(2):311–315.
13. Frymoyer PA, Scheinman SJ, Dunham PB, Jones DB, Hueber P, Schroeder ET. X-linked recessive nephrolithiasis with renal failure. N Engl J Med. 1991;325(10):681–686.
14. Leumann EP. Primary hyperoxaluria: an important cause of renal failure in infancy. Int J Pediatr Nephrol. 1984;6(1):13–16.
15. Gambaro G, Favaro S, D'Angelo A. Risk for renal failure in nephrolithiasis. Am J kidney Dis. 2001;37(2):233–243.
16. Worcester EM, Coe FL, Evan AP, Parks JH. Reduced renal function and benefits of treatment in cystinuria vs other forms of nephrolithiasis. BJU Int. 2006;97(6):1285–1290.
17. Vupputuri S, Soucie JM, McClellan W, Sandler DP. History of kidney stones as a possible risk factor for chronic kidney disease. Ann Epidemiol. 2004;14(3):222–228.
18. Stankus N, Hammes M, Gillen D, Worcester EM. African American ESRD patients have a high pre-dialysis prevalence of kidney stones compared to NHANES III. Urol Res. 2007;35(2):83–87.
19. Worcester EM, Parks JH, Evan AP, Coe FL. Renal function in patients with nephrolithiasis. J Urol. 2006;176(2):600–603.
20. Rule AD, Bergstralh EJ, Melton LJ, et al. Kidney stones and the risk for chronic kidney disease. Clin J Am Soc Nephrol. 2009;4(4):804–811.
21. Levey AS, Eckardt KU, Tsukamoto Y, et al. Definition and classification of chronic kidney disease: A position statement from Kidney Disease: Improving Global Outcomes (KDIGO). Kidney Int. 2005;67(6):2089–2100.
22. Peabody JW, Yu JC, Wang YR, Bickel SR. Health system reform in the Republic of China: formulating policy in a market-based health system. JAMA. 1995;273:777–781. 10.1001/jama.273.10.777.
23. Chiang TL. Taiwan's 1995 health care reform. Health Policy. 1997;39:225–239. 10.1016/S0168-8510(96)00877-9.
24. Chi CC. Evidence-based dermatology. Dermatol Sinica. 2013;31(1):2–6.