Abstract
There are racial differences in primary renal diseases for end-stage renal disease (ESRD) and the incidence and prevalence of cardiovascular disease (CVD). To reduce the number of patients with both ESRD and CVD, an effective screening method for CKD should be established. In Japan, screening with the urine dip-stick test for proteinuria has been used since 1972 targeting every child and worker and since 1983 for every resident over 40 years old. There are several reasons for continuing this screening program. First, the positive rate of proteinuria is high in the Japanese general population, especially subjects with neither hypertension nor diabetes. Most of these subjects have no symptoms, and the only sign of renal disease is asymptomatic urinary abnormalities. Second, the prevalence and incidence of glomerulonephritis, especially IgA nephropathy, are high in the Japanese and Asian races, and urinalysis is the only method for early detection of chronic glomerulonephritis. Third, 10-year survival of the ESRD patients due to glomerulonephritis was approximately twice that of ESRD patients due to diabetes and nephrosclerosis. Consequently, reducing the incidence of ESRD due to glomerulonephritis is one of the best ways to reduce the prevalence of ESRD. Furthermore, higher incidence of ESRD in Asian races than in Caucasians was reported. Proteinuria is known to be the best predictor for reducing renal function, and the urine dip-stick test for proteinuria is less expensive and is cost-effective. For an effective screening strategy to reduce the ESRD population in Japanese and Asians, universal screening with the urine dip-stick test for proteinuria could be one solution.
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Introduction
The estimated global maintenance dialysis population is just over 1.5 million patients [1]. The size of this population has been expanding at a rate of 7% per year. If current trends in end-stage renal disease (ESRD) prevalence continue, the ESRD population will exceed 2 million patients by the year 2010 [2]. At the end of 2005, patients with ESRD who required renal replacement therapy (RRT) were 257,765 in Japan. The prevalence of patients with ESRD was 1,797 per million population, and the incidence of patients with ESRD was 267 per million population in 2003 in Japan. Figure 1 shows yearly changes in the dialysis population from 1968 to the present in Japan (Fig. 1) [3]. Japan has the largest prevalence of ESRD patients in the world. Furthermore, Japan was the fourth in terms of ESRD incidence patients worldwide [4]. A health-related quality of life among dialysis patients was also poor [5], and life expectancy of the ESRD population is about half that of the general population in Japan [3]. The growing dialysis population is emerging not only to be a major global socio-economic problem, but also a public health problem.
In 2002, the Kidney Disease Outcomes Quality Initiative (K/DOQI) of the National Kidney Foundation gave a definition and classification system for chronic kidney disease (CKD) [6]. The definition and classification of CKD were accepted by the international board of directors of Kidney Disease: Improving Global Outcomes [7]. CKD was defined in five stages based on the appearance of proteinuria and GFR levels. It was estimated that there are 19.2 million US adults with CKD; patients with early stage CKD had no symptoms, and the majority of individuals in early stage CKD were undiagnosed, even in developed countries [8, 9]. Furthermore, patients with CKD have an increased risk of not only ESRD, but poor cardiovascular outcomes and death [10–13]. A vast number of those with moderate CKD die before they develop more advanced CKD [14]. To reduce the number of patients with both ESRD and cardiovascular disease (CVD), effective screening and treatment methods for CKD should be established [7, 15, 16]. However, primary renal diseases for ESRD differ by race and area [17–20]. Also, the incidence and prevalence of CVD and its mortality differ by race and area [21, 22]. Consequently, the screening procedure for CKD requires different approaches depending on the patient’s race, habitual, and socio-economical status. We should pay more attention to these differences to clarify a strategy for an effective screening procedure.
In Japan, an annual urinalysis screening program was introduced for every school child in 1973, for every working adult in 1972, and for every resident older than 40 years of age in 1982 under the auspices of local governments and the Ministry of Health, Labor and Welfare of Japan. Also, an annual measurement of serum creatinine was started in 1992 for every resident over 40 years of age [23, 24], although most countries do not perform universal urinalysis screening [25].
In this review, we will focus on our experiences with the Japanese urinalysis screening program and its achievement, problems, and reasons why it has continued until today. Furthermore, we will discuss our strategies for screening systems for CKD in Japan and in Asian populations, and future perspectives.
Racial and geographical differences in primary renal disease in Japan and other countries in terms of ESRD
At the end of 2005, patients with ESRD who required RRT were 257,765 in Japan. The incidence of patients with ESRD was 36,063 in Japan [3]. Figure 2 shows international comparisons of primary renal disease for those who started RRT for ESRD treatment [3, 4, 26–28]. Not only primary renal disease, but also the availability of ESRD treatment, along with age and population growth, race and the number of people with diabetes also vary between countries and areas [29, 30]. As shown in Fig. 2, while the proportion of diabetes was almost the same as in all countries, the proportion of nephrosclerosis and glomerulonephritis among countries was quite different. In Japan, glomerulonephritis was the most frequent primary renal disease for ESRD, actually accounting for more than 50% of patients entering the ESRD program in Japan from 1969 to 1996. In Taiwan, which has the highest incidence of ESRD patients in the world [4, 31], primary renal disease in patients with ESRD showed almost the same pattern as Japan.
Screening method for early detection of CKD
Most primary chronic glomerulonephritis is first manifested as asymptomatic proteinuria and/or hematuria [32, 33]. Figure 3 shows clinical manifestation of IgA nephropathy among 487 patients in Japan [34]. Approximately 68.2% of the patients with IgA nephropathy were discovered by asymptomatic proteinuria and/or hematuria [34]. For early detection of glomerulonephritis, urinalysis has been considered one of the best methods [35, 36]. The level of proteinuria is one of the strongest predictors for renal function deterioration [24, 37–41]. Consequently, to prevent an increase in the number of ESRD patients in Japan, a dipstick urine examination has been continued under the auspices of local governments and the Ministry of Health, Labor and Welfare of Japan since 1972 [23, 24]. However, in 1989 the US preventive service task force reported that routine dipstick urinalysis was not recommended for asymptomatic persons [25]. Although urinalysis screening may detect early glomerular diseases, the efficacy of early treatment of glomerulonephritis had not been studied in a randomized controlled trial at that time [25]. Furthermore, as shown in Fig. 2, about half of ESRD cases in the USA were due to hypertension or diabetes, which caused proteinuria after several years of exposure to hypertension and diabetes, and few cases of significant diseases had been detected with dipstick screening for hematuria and proteinuria after reviewing several population-based studies in both adults and children [25]. Also, most other countries did not recommend annual urinalysis screening for the same reasons [42].
Figure 4 shows yearly changes for the number of patients starting RRT in three major primary renal diseases in Japan. Recently the number of ESRD cases due to glomerulonephritis has decreased in Japan [20, 43]. There are several reasons for this decrease. One is an improvement in the prognosis of patients with IgA nephropathy. IgA nephropathy is the most common glomerulonephritis worldwide [44, 45], and 68.2% of patients with IgA nephropathy were detected by the Japanese urinalysis screening program as mentioned above [23, 34]. Early referral to a nephrologist and starting early treatment were established by this program [20, 43]. Although treatment methods for protenuric subjects were an angiotensin converting enzyme (ACE) inhibitor [46] or angiotensin receptor blocker (ARB) [47], treatment methods for IgA nephropathy were diverse, including steroids [48, 49], immunosuppressants [49] and tonsillectomy [50, 51], which showed superior results than treatment to ACEI or ARB alone. In countries or races where glomerulonephritis was the frequent primary renal disease for ESRD, such as Japan and Asian countries, universal dip-stick proteinuria screening is recommended.
Racial difference of proteinuria prevalence
Boulware et al. [52] reported that annual screening for proteinuria in US adults was not cost-effective because the prevalence and incidence of proteinuria were very low. However, selective annual testing focusing on high-risk groups is highly cost-effective. They reported that annual screening starting at age 60 years or older is cost-effective for persons with neither hypertension nor diabetes, and annual screening from ages 30 to 70 years is highly cost-effective for persons with hypertension. Table 1 shows the prevalence of proteinuria from NHANES III [53] and annual urinalysis data held in Ibaraki prefecture in Japan [54]. As shown in Table 1, the prevalence of proteinuria in US adults aged 60 years or older with neither hypertension nor diabetes was 0.8%, while the prevalence of proteinuria in Japanese adults with neither hypertension nor diabetes of same age group was 1.8%. Furthermore, the prevalence of proteinuria in US adults with hypertension was 2.2%, but the prevalence of proteinuria in Japanese adults with hypertension was 3.3%. Iseki et al. [55] reported that the positive rate of proteinuria in screened subjects was as high as 5.3% among 106,177 subjects in Okinawa, Japan. This high prevalence of proteinuria in the overall Japanese population supported the idea that annual urinalysis screening for the whole population in Japan might be cost-effective. A striking difference between the Japanese population and US population is the high prevalence of proteinuria in Japanese adults with neither hypertension nor diabetes. Most of these subjects have no symptoms, and the only sign of renal disease is asymptomatic urinary abnormalities [56]. The Malay race, a Southeast Asian population, also showed a high prevalence of proteinuria [57].
Proteinuria is a better risk marker for developing ESRD than impaired renal function
Both proteinuria and impaired renal function predict a worse prognosis with respect to cardiovascular morbidity and mortality [10–13]. Subjects with proteinuria showed three times faster GFR loss than both control and impaired renal function subjects [58]. Therefore, proteinuria is a better risk marker than impaired renal function in population screening of individuals to identify who is at risk for developing ESRD [58]. Hallan et al. [59] reported that during an 8-year follow-up, only 38 of 3,069 people (1.2%) with impaired renal function (CKD stage 3 or later) progressed to ESRD, while Iseki et al. [37] reported that during a 17-year follow-up, 186 of 5,436 people (3.4%) with proteinuria progressed to ESRD.
There are several reasons for the large dialysis population in Japan, including a low transplantation rate, full coverage of medical expenses for dialysis patients and an excellent survival rate after initiation of RRT. From the Japan ESRD registry, 10-year survival of the ESRD population is 52.7% for glomerulonephritis, 28.0% for diabetes, and 27.0% for nephrosclerosis (hypertensive nephropathy) [3]. Consequently, to reduce the prevalence of ESRD patients effectively in Japan, both increasing kidney transplantation and decreasing the incidence of ESRD due to glomerulonephritis are effective methods.
Furthermore, there are several reports about a higher incidence of ESRD in Asian races than in Caucasians [60–62]. Reasons for these differences are unclear, but genetic [60, 63] and environmental differences [64] are related. Further studies are needed to clarify about these points.
Future strategy for CKD screening in Japan
Chronic kidney disease was first proposed by K/DOQI, and it was accepted by KDIGO; however, most written standards and effective CKD perspectives are suitable for Caucasians or people living in Western countries [65, 66]. One example is CVD morbidity and mortality differences between Japanese and Caucasians. Hollan et al. [67] reported that the prevalence of CKD in the USA and Norway was the same, and the occurrence of CVD in CKD patients in Norway was almost the same as in the US population, while the proportion of heart disease and stroke among CVD patients was identical between Norway and the USA [21]. During an 8-year observation period, 2,604 of 5,640 deaths were from CVD, and 691 of 2,604 deaths (26.5%) had CKD stage III or higher in Norway [59]. However, during a 10-year observation period, 1,932 of 6,906 deaths were from CVD, while only 307 subjects (15.9%) had CKD in Japan [68], and the Japanese general population had an incidence of CVD among CKD subjects that was much lower than the US population [69].
Another example is the indication for microalbuminuria. Previous studies in general Western populations have suggested that microalbuminuria was a significant predictor for both coronary heart disease and stroke [70, 71]. Some people proposed that universal testing for microalbuminuria should be considered [72–74]. However, the prevalence of microalbuminuria in mass screening was 11.8–17.8% of the study population in Asians [75, 76], which was a several times higher positive rate compared to the USA [53]. It is possible to improve microalbuminuria by using ARB, ACEI and statins [74, 77–81] and to avoid the development of both ESRD and CVD. However, medical fees for follow-up and prescriptions of these drugs are very expensive, especially in countries and for races with a high prevalence of microalbuminuria. Furthermore, urinary albumin and creatinine ratio testing is more expensive than the urine dip-stick test for proteinuria. Consequently, universal screening with the urine dip-stick test for proteinuria is suitable for most countries or races that have a high prevalence of proteinuria such as Asians and Japanese. However, there are lifestyle modifications; along with a higher prevalence of diabetes in the general population and a higher incidence of stroke and stroke mortality in Japan, we might have to change urinalysis screening policy from the urine dip-stick test for proteinuria to microalbuminuria in the near future.
In summary, universal screening with the urine dip-stick test for proteinuria has been used in Japan. There are several reasons for continuing this screening program. First, the positive rate of proteinuria is high in the Japanense general population. Second, the prevalence and incidence of glomerulonephritis, especially IgA nephropathy, are high in Japan. Third, urinalysis is the only method for early detection of most chronic glomerulonephritis. Fourth, reducing the incidence of ESRD due to glomerulonephritis is one of the best ways to reduce the prevalence of ESRD. Furthermore, the death rate due to CVD was the same between Japan and the USA. Although CKD is one of the important risk factors for CVD in the Japanese general population, the Japanese incidence of CVD and mortality due to CVD among CKD subjects were lower than those of Caucasians. Japanese and Asians should focus on reducing ESRD and subjects with reduced renal function. To do this, universal screening with the urine dip-stick test for proteinuria could be one solution.
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Yamagata, K., Iseki, K., Nitta, K. et al. Chronic kidney disease perspectives in Japan and the importance of urinalysis screening. Clin Exp Nephrol 12, 1–8 (2008). https://doi.org/10.1007/s10157-007-0010-9
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DOI: https://doi.org/10.1007/s10157-007-0010-9