Abstract
Background
Uncontrolled hyperphosphatemia in chronic kidney disease (CKD) patients commonly results in vascular calcification leading to increased risk of cardiovascular disease. Phosphate binders (PBs) are used for hyperphosphatemia and can be calcium-based (CBPBs) or non-calcium-based (NCBPBs), the latter being more expensive than CBPBs. In this study, we used meta-analysis approaches to assess the cost-utility of PBs for hyperphosphatemia in CKD patients.
Methods
Relevant studies published prior to June 2019 were identified from PubMed, Scopus, the Cochrane Library, the National Health Service Economic Evaluation Database, and the Cost-Effectiveness Analysis Registry. Studies were eligible if they included CKD patients with hyperphosphatemia, compared any PBs and reported economic outcomes. Meta-analysis was applied to pool incremental net benefit (INB) across studies stratified by country income.
Results
A total of 25 studies encompassing 32 comparisons were eligible. Lanthanum carbonate, a NCBPB, was a more cost-effective option than CBPBs in high-income countries (HICs), with a pooled INB of $3984.4 (599.5–7369.4), especially in pre-dialysis patients and used as a second-line option with INBs of $4860.2 (641.5–9078.8), $4011.0 (533.7–7488.3), respectively. Sevelamer, also a NCBPB, was not more cost-effective as a first-line option compared to CBPBs with a pooled INB of $6045.8 (− 23,453.0 to 35,522.6) and $34,168.9 (− 638.0 to 68,975.7) in HICs and upper middle-income countries, respectively.
Conclusions
Lanthanum carbonate was significantly more cost-effective than CBPBs as a second-line option for hyperphosphatemia in pre-dialysis patients in HICs. However, the use of sevelamer is not more cost-effective as a first-line option compared to CBPBs.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Chronic kidney disease (CKD) represents a significant global public health burden with high economic costs related to morbidity and mortality [1]. In 2016, global CKD prevalence was estimated to exceed 13%, of which four-fifths were classified as CKD stage 3 or higher [2]. Progression of CKD to end-stage renal disease (ESRD) increases the likelihood of complications particularly mineral and bone disorders, kidney failure and cardiovascular disease (CVD) [1, 3, 4].
Given the kidneys are responsible for the excretion of excess phosphorous, CKD leads to hyperphosphatemia in 40–85% [5,6,7,8,9,10,11,12]. Left untreated, the sequelae are renal osteodystrophy, secondary hyperparathyroidism, and vascular calcification [1, 11,12,13] leading to increased risk of CVD [14,15,16,17]. As such, clinical practice a few guidelines [13, 18, 19] recommend the prescription of phosphate binders (PBs), e.g., calcium-based PBs (CBPBs), as the initial management for hyperphosphatemia. If CBPBs are not effective, or there are contraindications for CBPBs, non-calcium-based PBs (NCBPBs, e.g., sevelamer, lanthanum carbonate, sucroferric oxyhydroxide or ferric citrate) are the next treatment options.
Previous systematic reviews (SR) and network meta-analyses (MA) [20,21,22,23] reported significantly increased mortality in CBPBs relative to NCBPBs [21]. CBPBs may increase hypercalcemia relative to NCBPBs, which may subsequently escalate the risk of CVD events [20, 22, 23]. These findings were consistent with those of conventional MA [24, 25] and observational studies [26, 27]. Consequently, clinical practice guidelines [13, 18, 19] have recommended NCBPBs instead of CBPBs. However, given NCBPBs are more expensive than CBPBs, they are not always regarded as the primary treatments due to affordability and availability [19].
Many economic evaluation (EE) studies and SRs assessed the cost-effectiveness of PBs [28, 29]. Studies conducted in high-income countries (HICs) suggested sevelamer and lanthanum carbonate may be more cost-effective treatments compared to CBPBs in patients with CKD. However, the cost-effectiveness of these treatments in low- and middle-income countries (LICs and MICs) has not been sufficient due to a lack of published data. Furthermore, evidence related to newer NCBPBs (e.g., ferric citrate, sucroferric oxyhydroxide, etc.) has not been previously reviewed.
Therefore, this SR and MA assessed the cost-effectiveness of PBs available under current practice guidelines for the treatment of hyperphosphatemia in CKD patients. Incremental net benefit (INB) for various PB comparisons were pooled and stratified by country income to provide reliable evidence for further consideration by policymakers.
Methods
This SR and MA was performed in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses Protocols (PRISMA-P) [30] and registered at PROSPERO (CRD42019145280).
Data sources
A literature search up to June 2019 was performed in PubMed, Scopus, the Cochrane Central Register of Controlled Trials, the National Health Service Economic Evaluation Database (NHS EED), and the Cost-Effectiveness Analysis (CEA) Registry by Tufts Medical Center. Lists of references from selected articles/SRs were also checked to identify additional relevant studies. The search terms were constructed based on interventions/comparators (i.e., phosphate binder, calcium carbonate, sevelamer, lanthanum, sucroferric) and outcomes (i.e., economic evaluation, cost-utility analysis, and incremental net benefit), see more detail in Supplementary Methods S1.
Study selection
Two reviewers (KC and NR) independently screened titles and abstracts, full articles were reviewed if a decision could not be made. Any disagreement was discussed with a third party (OP). EE studies (e.g., cost-utility analysis (CUA) or cost-effectiveness analysis (CEA)) were eligible if they met the following criteria: adult CKD with hyperphosphatemia, compared any pair of PBs regardless of dosage and treatment duration (CBPBs: calcium carbonate/acetate; NCBPBs: sevelamer, lanthanum carbonate, ferric citrate, sucroferric oxyhydroxide, aluminum hydroxide, colestimide, bixalomer, nicotinic acid), and any EE outcomes including incremental cost-effectiveness ratio (ICER), incremental cost-utility ratio (ICUR), INB/net monetary benefit (NMB), incremental cost (ΔC), incremental effectiveness (ΔE, e.g., life years (LYs) gained/lost and quality-adjusted life years (QALYs)). The following studies were ineligible: cost-minimization analysis and insufficient data for pooling despite three data requests to the corresponding author.
Data extraction
Data extraction was performed independently by two of the three reviewers (KC, TS and NR). Any disagreement was discussed and resolved by a third party (OP). The data extraction forms (see Supplementary Methods S2) were designed by incorporating information from the consolidated health economic evaluation reporting standard (CHEERS) statement [31, 32], the NHS-EED [33], and the centre for reviews and dissemination guidance [34] consisting five parts: general information, study characteristics, participant characteristics and intervention/comparison, methods and outcomes of EE, and data for pooling.
The economic parameters including mean cost/ΔC, effectiveness/ΔE, and ICERs, along with dispersion (standard deviation (SD) or 95% confidence interval (CI)) were extracted. If not explicitly reported, they were extracted from cost-effectiveness plane graphs instead. Cost-effectiveness (C/E) threshold or willingness to pay (WTP) were also extracted, and if not reported, were based on the 2019 national agencies threshold (e.g., Canadian Agency for Drugs and Technologies in Health (CADTH), NICE) for that country.
Risk of bias assessment
Risk of bias was assessed using the Bias in Economic Evaluation (ECOBIAS) checklist consisting of the general domain (11 items) and model-specific issues in economic evaluations including structure (4 items), data (6 items), and internal consistency (1 item), see Supplementary Methods S3 [35]. Every item was rated as yes, no, partly, unclear or not applicable.
Interventions and economic outcomes
Interested interventions were comparisons of PBs including sevelamer versus CBPBs, lanthanum carbonate versus CBPBs, lanthanum carbonate versus sevelamer, and sucroferric oxyhydroxide versus sevelamer. The economic outcome measure was INB [36,37,38], which was calculated as follows: INB = K(ΔE)−ΔC, where K is the C/E threshold or WTP, ΔE, and ΔC are the difference of QALYs and cost between intervention and comparator. Those studies reported the ICERs were converted to the INB as INB = ΔE (K−ICER). However, variation in data reporting of EE studies necessitated the estimation of INB and variance based on five scenarios in line with previous recommendations (Supplementary Methods S4A) [39, 40]. The intervention was characterized as cost-effective if the INB was positive (i.e., favoring the intervention), otherwise the new intervention was characterized as not cost-effective [38, 41].
Currency conversion
Individual studies used various currencies and year by country. The currency was converted to a 2019 cost metric using the consumer price index (CPI) [42] and United States dollar (US$) using purchasing power parity (PPP) [43], see Supplementary Methods S4B.
Statistical analysis
Pairwise MA of pooled INB stratified by country income was applied for each PB comparison if there were at least 2 EE studies [44] (i.e., HICs, upper-middle-income countries (UMICs), lower-middle-income countries (LMICs), and LICs). A fixed-effect model using the inverse-variance method was used if heterogeneity was not present, otherwise a random effect model (DerSimonian and Laird) was applied, see Supplementary Methods S4C.
Heterogeneity was assessed by the Cochrane’s Q test and I2 statistic; a Q test p value < 0.1 or an I2 value > 25% was regarded as significant. Sources of heterogeneity were explored by fitting each co-variable independently within a meta-regression model e.g., pre-dialysis versus dialysis, first- versus second-line treatment, C/E thresholds, lifetime versus non-lifetime horizon (defined as the duration of study over which costs and outcomes are calculated), model discount rate (defined as the rate for adjusting future costs and outcomes to the present value in the economic model). A co-variable was considered a source of heterogeneity if the decrease in Tau2 ≥ 50%. Subgroup analysis was performed accordingly. In addition, a 95% prediction interval (PI) was estimated where there were at least three studies to predict if the pooled INB was still cost-effective in other settings [45, 46].
Publication bias was assessed using a funnel plot and Egger’s test. Indications of asymmetry were addressed through the use of contour enhanced funnel plots to distinguish the source of asymmetry. All data pooling was undertaken using Microsoft® excel version 2019 and analysed by STATA® version 16. A two-sided p value < 0.05 was considered statistically significant.
Results
Study identification
A total of 1790 studies were identified, of which 25 studies were eligible, comprising 32 comparisons [47,48,49,50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,66,67,68,69,70,71] (Fig. 1). Among them, 20 studies [47,48,49,50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,66] (number comparisons (n) = 26) and 7 studies [59, 60, 67,68,69,70,71] (n = 9) provided data on CUA in cost/QALYs and CEA in cost/LYs, respectively. Of the CUA studies, 18 [49,50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,66] and 2 [47, 48] were conducted in HICs and UMICs, respectively. Four comparisons of PBs were included: sevelamer versus CBPBs (N = 9 for HICs [49,50,51,52,53,54,55,56,57] and N = 2 for UMICs [47, 48]), lanthanum carbonate versus CBPBs (N = 7 for HICs [49, 57,58,59,60,61,62]), lanthanum carbonate versus sevelamer (N = 3 for HICs [49, 63, 64]), and sucroferric oxyhydroxide versus sevelamer (N = 2 for HICs [65, 66]). All CEA studies were from HICs with sevelamer versus CBPBs (N = 5 [67,68,69,70,71]) and lanthanum carbonate versus CBPBs (N = 2 [59, 60]). Only CUA studies were considered in MA for pooling INBs.
Study characteristics are reported (Table 1) and all applied the third-party payer’s perspective. Most studies used Markov models (N = 18 [47, 48, 50,51,52,53,54,55,56,57,58,59,60, 63,64,65,66,67]) and were evaluated over a patient’s lifetime (N = 21 [47,48,49, 51,52,53,54,55,56,57,58,59,60,61,62, 64,65,66,67,68,69]). Nineteen [48,49,50,51,52,53, 60,61,62,63,64,65,66,67,68,69,70] and eight studies [47, 54,55,56,57,58,59, 71] focused on dialysis and pre-dialysis patients, respectively. The majority of studies accounted for dialysis costs in their analyses, although 9 studies failed to do so [48,49,50, 63,64,65,66, 68, 69]. All studies, with the exception of two [70, 71], reported direct costs with discounting for both costs and outcomes. Sources for model input parameters (N = 14 [50, 51, 55, 58,59,60,61,62,63,64,65,66, 68, 69]) and utility data (N = 11 [47, 50, 51, 56, 60,61,62,63,64,65,66]) were mostly from multiple studies. The majority of studies used country-specific thresholds (N = 22 [49,50,51,52, 54,55,56,57,58,59,60,61,62,63,64,65,66,67,68,69,70,71]).
Twenty-one of the 25 studies reported that NCBPBs were cost-effective, of which 19 [49, 50, 52,53,54,55,56, 58,59,60,61,62, 64, 66,67,68,69,70,71] and two studies [47, 48] originated from HICs and UMICs, respectively. For the 19 studies from HICs, 11 [50, 52,53,54,55,56, 67,68,69,70,71] concluded that sevelamer was more cost-effective than CBPBs. Five [58,59,60,61,62] and two studies [49, 64] found lanthanum carbonate was more cost-effective than CBPBs and sevelamer, respectively. And a single study reported that sucroferric oxyhydroxide was more cost-effective than sevelamer [66]. For UMICs, both studies reported that sevelamer was more cost-effective than CBPBs [47, 48].
Risk of bias assessment
Results from a risk of bias assessment are described, see Supplementary Table S1. For overall bias, all studies were regarded as unbiased on perspective, comparator, ordinal ICER, and reporting/dissemination. Between 84–96% of studies were unbiased on data collection, valuation, double counting and discounting. Seven studies demonstrated partial bias using one-way sensitivity analysis [49, 50, 52, 55, 56, 60, 62]. All studies were regarded as unbiased on structural assumptions, treatment comparator, utility weights, and on internal consistency of model-specific bias. Several studies demonstrated partial bias on the basis of time horizon [50, 70], data identification [50, 67], non-transparent data [60, 62] and baseline data [67]. A single study provided insufficient detail for assessment on wrong model bias [62].
Sevelamer versus CBPBs
Twelve comparisons (N = 11 [47,48,49,50,51,52,53,54,55,56,57]) between sevelamer and CBPBs were CUAs, with 10 and two in HICs [49,50,51,52,53,54,55,56,57] and UMICs [47, 48] (Supplementary Table S2). All studies evaluated PBs as primary interventions. Among HICs, INBs were homogenous (I2 = 0%) representing a pooled INB (95% CI) of $6045.8 (− 23,453.0 to 35,522.6), see Fig. 2a, suggesting sevelamer was more cost-effective than CBPBs, although this failed to reach statistical significance. The 95% PI also suggested that the true effect in future setting could be null or in the similar direction of the pooled INB, with the range of − $28,661.2 to $40,752.8.
In addition, subgroup analysis was undertaken according to pre-dialysis/dialysis patients with and without consideration of dialysis cost, and a median C/E threshold (< $48,114.6 versus ≥ $48,114.6), see Supplementary Figure S1. Sevelamer was more cost-effective than CBPBs in pre-dialysis, but not in dialysis patients, with and without accounting for dialysis costs (i.e., pooled INBs were $19,145.8 (− 27,797.5 to 66,089.2), − $1.986.5 (− 67.671.7 to 63,698.8), and − $2760.8 (− 49,203.4 to 43,681.8), respectively, but again all estimates failed to reach significance. Likewise, subgroup analysis based on the median threshold value of $48,114.6 failed to identify significant differences in associated costs. The 95%PIs according to subgroup analysis included the null effect, which were consistent with the pooled INBs.
All studies, bar one [50], were evaluated over a patient’s lifetime horizon. Sensitivity analysis was performed by excluding the study that used non-lifetime horizon [50] and the highest threshold studies [55], providing pooled INBs of $8073.3 (− 24,940.7 to 41,087.4), and $6131.4 (− 24,590.7 to 36,853.5) respectively (Supplementary Figure S2), which were consistent with the overall pooled INBs.
For UMICs, INBs of sevelamer versus CBPBs were pooled across two studies [47, 48] with values of $34,168.9 (− 638.0 to 68,975.7), suggesting sevelamer was more cost-effective than CBPBs, although this was also not significant, see Fig. 2b. The funnel plot and Egger’s test did not identify any asymmetry for pooling INBs in HICs and UMICs (see Supplementary Figure S3 and Table S3).
Lanthanum carbonate versus CBPBs
Nine comparisons (N = 7 [49, 57,58,59,60,61,62]) evaluated CUAs between lanthanum carbonate and CBPBs in HICs. Three [49, 57] and six [58,59,60,61,62] focused on first and second-line treatments respectively, see Supplementary Table S2. High heterogeneity was observed (I2 = 83.6%) with a pooled INB of $3984.4 (599.5–7369.4) indicating lanthanum carbonate was significantly more cost-effective than CBPBs, see Fig. 3. However, the 95% PI was − $4231.0 to $12,199.8 indicating lanthanum carbonate was not cost-effective than CBPBs in other settings.
The source of heterogeneity was explored by considering each co-variable in a meta-regression model one by one including pre-dialysis versus dialysis, first- versus second-line treatment, discount rates, and C/E thresholds. None of them could reduce heterogeneity but worsen in increasing heterogeneity with the I2 for these corresponding co-variables of 85.1, 85.7, 84.1, and 84.1%, see Supplementary Table S4. A subgroup analysis suggested lanthanum carbonate was significantly more cost-effective relative to CBPBs in pre-dialysis patients, second-line treatment, discount rate < 3.5%, and at a median threshold ≥ $45,645.8 with pooled INBs of $4860.2 (641.5–9078.8), $4011.0 (533.7–7488.3), $8218.0 (3721.6–12,714.4), and $8218.0 (3721.6–12,714.4), respectively. However, none of these 95% PIs was statistically significant, see Supplementary Figure S4.
All studies, except one [49], considered dialysis costs in their evaluation. Sensitivity analyses excluding this study [49], and other studies with the highest discount rate [60] and C/E threshold [61] provided pooled INBs of $3660.1 (132.3–7187.8), $2761.0 (1996.0–3526.1), and $3993.6 (576.5–7410.7), respectively (Supplementary Figure S5). These were consistent with the overall pooled INB. Moreover, the exclusion of the highest discount rate study [60] reduced the I2 statistic for heterogeneity significantly from 83.6 to 5.1%, and its 95% PI of $1573.5–$3948.6 was still statistically significant.
The Egger’s test and the funnel plots suggested asymmetry for pooling of INBs (see Supplementary Table S3 and Figure S6). A contour enhanced funnel plot placed most of the studies in the non-significant area suggesting asymmetry may be due both to heterogeneity or missing positive studies (see Supplementary Figure S6).
Lanthanum carbonate versus sevelamer
Three studies [49, 63, 64] compared CUAs between lanthanum carbonate and sevelamer and all focused on dialysis patients and were conducted in HICs (see Supplementary Table S2). Two studies [49, 64] evaluated first-line PB treatments and a single study [63] evaluated second-line PB treatments. There was no heterogeneity (I2 = 0%) with the pooled INBs of $878.2 (− 94.1 to 1850.5), indicating lanthanum carbonate was more cost-effective than sevelamer, although this failed to reach significance, see Fig. 4a. The 95% PI also suggested that the true effect in future setting could be null or in the similar direction of the pooled INB, with the range of − $5425.1 to $7181.5. Neither the Egger’s test (see Supplementary Table S3) nor the funnel plot (see Supplementary Figure S7) indicated asymmetry or publication bias.
Sucroferric oxyhydroxide versus sevelamer
Only two studies [65, 66] compared CUAs of sucroferric oxyhydroxide to sevelamer, and these were based in HICs (see Supplementary Table S2) and evaluated PBs as second-line treatments in dialysis patients without considering dialysis costs. The pooled INB was $1956.1 (− 212,710.2 to 216,622.4) with no heterogeneity (I2 = 0%); the very wide confidence intervals, limited any inference, see Fig. 4b. Neither the Egger’s test (see Supplementary Table S3) nor the funnel plot (see Supplementary Figure S8) were asymmetrical indicating no publication bias.
Discussion
We conducted SR and MA for the economic evaluation of PBs for hyperphosphatemia treatments in CKD patients stratified by country income. Our findings identified lanthanum carbonate as a significantly more cost-effective second-line treatment in HICs compared to CBPBs, especially in pre-dialysis patients and in countries with a C/E threshold value ≥ $45,645.8. There was the suggestion of improved cost-effectiveness of sevelamer as a first-line treatment compared to CBPBs in both HICs and UMICs, but this was not significant. In addition, both lanthanum carbonate and sucroferric oxyhydroxide were more cost-effective than sevelamer, but these were also not significant.
Previous SRs of EE have provided limited qualitative comparisons of PBs without MAs [28, 29]. The evidence to date supports the cost-effective use of NCBPBs and lanthanum carbonate in particular. This evidence may guide clinical and safety considerations as NCBPBs have been reported in lowering side effects, hypercalcemia, CVD events and mortality compared to CBPBs [20,21,22,23]. The economic benefits and reduced expenditure associated with NCBPB usage, coupled with reduced side effects and complications, lead to improved patient adherence and quality of life. Our findings will better inform the drug selection process for clinicians, researchers, and policymakers. The first-line treatment options favor sevelamer or CBPBs as the drug of choice in both HICs and UMICs, although this doesn’t reach statistical significance. Lanthanum carbonate may offer a better second-line treatment option than CBPBs especially in pre-dialysis patients and in countries with a 2019 C/E threshold in excess of $45,645.8. Nevertheless, budget impact analysis will be necessary to assess affordability in each country’s drug selection process.
Our study had several strengths. We applied MA for estimate overall INBs to determine the most cost-effective treatment options. INBs were more amenable to pooling than ICERs which are more difficult to interpret [72,73,74]. The interested treatment was determined as more cost-effective if the INB was positive, representing a simple and uncomplicated message for the benefit of clinicians, researchers and policymakers [73]. We extracted data from individual EE studies, which reported results under five scenarios accounting for the type of patients, treatment strategies, clinical/cost/humanistic data, perspective, time horizon, and C/E thresholds [39, 40]. In addition, accurate comparisons of the EE studies required currency conversions standardized to US dollars using 2019 CPI and PPP conversions. Furthermore, stratified analysis by country income offered improved sensitivity given the variation in healthcare provision and service delivery systems. Lastly, subgroup and sensitivity analyses were performed according to test the robustness of the findings reported.
Our study also had several limitations. Firstly, the majority of studies were conducted in HICs limiting the generalizability. Secondly, the pooled INB comparison of lanthanum carbonate to CBPBs, which was the only statistically significant result, was subject to a high level of heterogeneity, although the sensitivity analysis significantly reduced the level of heterogeneity and potential bias observed. Thirdly, the pooled INBs of lanthanum carbonate and sucroferric oxyhydroxide for comparison to sevelamer were based on a small number of studies, limiting the robustness of the findings reported and also the assessment of publication bias. Finally, no studies were identified that evaluated the cost-effectiveness of sevelamer as a second-line treatment for comparison to CBPBs, which requires further consideration. Further EE studies are necessary to extend these results to UMICs, MICs, and LICs, as well as studies to evaluate the cost-effectiveness of NCBPBs as first- and second-line treatment options in both pre-dialysis and dialysis patients. In addition, a network meta-analysis should be further applied to compare cost-effectiveness of all possible treatment regimens.
Conclusion
Our data identified lanthanum carbonate might be more cost-effective as a second-line treatment for hyperphosphatemia in pre-dialysis patients than CBPBs in HICs. The use of sevelamer as a first-line treatment may also offer some savings over CBPBs in HICs and UMICs. The inclusion of additional studies as they become available, especially from UMICs, MICs, and LICs, will inform improved cost-effectiveness for the hyperphosphatemia treatments in different healthcare settings.
References
Wang, H., Naghavi, M., Allen, C., et al.: Global, regional, and national life expectancy, all-cause mortality, and cause-specific mortality for 249 causes of death, 1980–2015: a systematic analysis for the Global Burden of Disease Study 2015. Lancet 388(10053), 1459–1544 (2016)
Hill, N.R., Fatoba, S.T., Oke, J.L., et al.: Global prevalence of chronic kidney disease–a systematic review and meta-analysis. PLoS ONE 11(7), e0158765 (2016)
Neuen, B.L., Chadban, S.J., Demaio, A.R., Johnson, D.W., Perkovic, V.: Chronic kidney disease and the global NCDs agenda. BMJ Glob. Health 2(2), e000380 (2017)
Eknoyan, G., Lameire, N., Eckardt, K., et al.: KDIGO 2012 clinical practice guideline for the evaluation and management of chronic kidney disease. Kidney Int. 3(1), 5–14 (2013)
Kestenbaum, B., Sampson, J.N., Rudser, K.D., et al.: Serum phosphate levels and mortality risk among people with chronic kidney disease. J. Am. Soc. Nephrol. 16(2), 520–528 (2005)
Ghosh, B., Brojen, T., Banerjee, S., et al.: The high prevalence of chronic kidney disease-mineral bone disorders: a hospital-based cross-sectional study. Indian J. Nephrol. 22(4), 285 (2012)
Chuang, S.H., Wong, H.C., Vathsala, A., Lee, E., How, P.P.C.: Prevalence of chronic kidney disease-mineral and bone disorder in incident peritoneal dialysis patients and its association with short-term outcomes. Singapore Med. J. 57(11), 603 (2016)
Etta, P.K., Sharma, R., Gupta, A.: Study of chronic kidney disease-mineral bone disorders in newly detected advanced renal failure patients: a hospital-based cross-sectional study. Saudi J. Kidney Dis. Transpl. 28(4), 875–885 (2017)
Abrita, R.R., Pereira, B.D.S., Fernandes, N.D.S., et al.: Evaluation of prevalence, biochemical profile, and drugs associated with chronic kidney disease-mineral and bone disorder in 11 dialysis centers. Braz J. Nefrol. 40(1), 26–34 (2018)
Jin, J.J., Zhang, S.L., Xu, J.S., et al.: Prevalence of chronic kidney disease-mineral bone disorder in hemodialysis patients in Hebei, China. Chin Med. J. 131(22), 2749 (2018)
Shaman, A.M., Kowalski, S.R.: Hyperphosphatemia management in patients with chronic kidney disease. Saudi Pharm. J. 24(4), 494–505 (2016)
Kates, D.M., Sherrard, D.J., Andress, D.L.: Evidence that serum phosphate is independently associated with serum PTH in patients with chronic renal failure. Am. J. Kidney Dis. 30(6), 809–813 (1997)
Isakova, T., Nickolas, T.L., Denburg, M., et al.: KDOQI US commentary on the 2017 KDIGO clinical practice guideline update for the diagnosis, evaluation, prevention, and treatment of chronic kidney disease–mineral and bone disorder (CKD-MBD). Am. J. Kidney Dis. 70(6), 737–751 (2017)
McGovern, A.P., de Lusignan, S., van Vlymen, J., et al.: Serum phosphate as a risk factor for cardiovascular events in people with and without chronic kidney disease: a large community based cohort study. PLoS ONE 8(9), e74996 (2013)
Dhingra, R., Gona, P., Benjamin, E.J., et al.: Relations of serum phosphorus levels to echocardiographic left ventricular mass and incidence of heart failure in the community. Eur. J. Heart Fail. 12(8), 812–818 (2010)
Connolly, G.M., Cunningham, R., McNamee, P.T., Young, I.S., Maxwell, A.P.: Elevated serum phosphate predicts mortality in renal transplant recipients. Transplantation 87(7), 1040–1044 (2009)
Eddington, H., Hoefield, R., Sinha, S., et al.: Serum phosphate and mortality in patients with chronic kidney disease. Clin. J. Am. Soc. Nephrol. 5(12), 2251–2257 (2010)
Centre for Clinical Practice at National Institute for Health Excellence (NICE) Hyperphosphataemia in chronic kidney disease: management of hyperphosphataemia in patients with stage 4 or 5 chronic kidney disease. National Institute for Health and Clinical Excellence (UK), Manchester (2013)
Kidney Disease: Improving Global Outcomes CKD-MBD Work Group: KDIGO clinical practice guideline for the diagnosis, evaluation, prevention, and treatment of Chronic Kidney Disease-Mineral and Bone Disorder (CKD-MBD). Kidney Int. Suppl. 7(1), 59 (2017)
Sekercioglu, N., Veroniki, A.A., Thabane, L., et al.: Effects of different phosphate lowering strategies in patients with CKD on laboratory outcomes: a systematic review and network meta-analysis. PLoS ONE 12(3), e0171028 (2017)
Sekercioglu, N., Thabane, L., Martinez, J.P.D., et al.: Comparative effectiveness of phosphate binders in patients with chronic kidney disease: a systematic review and network meta-analysis. PLoS ONE 11(6), e0156891 (2016)
Yang, X., Bai, Q., Li, Y., et al.: Comparative efficacy and safety of phosphate binders in hyperphosphatemia patients with chronic kidney disease. J. Parenter. Enteral. Nutr. 42(4), 766–777 (2018)
Palmer, S.C., Gardner, S., Tonelli, M., et al.: Phosphate-binding agents in adults with CKD: a network meta-analysis of randomized trials. Am. J. Kidney Dis. 68(5), 691–702 (2016)
Jamal, S.A., Vandermeer, B., Raggi, P., et al.: Effect of calcium-based versus non-calcium-based phosphate binders on mortality in patients with chronic kidney disease: an updated systematic review and meta-analysis. Lancet 382(9900), 1268–1277 (2013)
Jamal, S.A., Fitchett, D., Lok, C.E., Mendelssohn, D.C., Tsuyuki, R.T.: The effects of calcium-based versus non-calcium-based phosphate binders on mortality among patients with chronic kidney disease: a meta-analysis. Nephrol. Dial. Transplant. 24(10), 3168–3174 (2009)
Spoendlin, J., Paik, J.M., Tsacogianis, T., et al.: Cardiovascular outcomes of calcium-free vs calcium-based phosphate binders in patients 65 years or older with end-stage renal disease requiring hemodialysis. JAMA Intern. Med. 179(6), 741–749 (2019)
Komaba, H., Wang, M., Taniguchi, M., et al.: Initiation of sevelamer and mortality among hemodialysis patients treated with calcium-based phosphate binders. Clin. J. Am. Soc. Nephrol. 12(9), 1489–1497 (2017)
Rizk, R., Hiligsmann, M., Karavetian, M., Evers, S.M.: Economic evaluations of interventions to manage hyperphosphataemia in adult haemodialysis patients: a systematic review. Nephrology 21(3), 178–187 (2016)
Petrou, P.: A systematic review of the economic evaluations of non-calcium-containing phosphate binders, sevelamer and Lanthanum, in end-stage renal disease patients with hyperphosphatemia. Expert Rev. Pharmacoecon. Outcomes Res. 19(3), 287–298 (2019)
Moher, D., Shamseer, L., Clarke, M., et al.: Preferred reporting items for systematic review and meta-analysis protocols (PRISMA-P) 2015 statement. Syst. Rev. 4(1), 1 (2015)
Husereau, D., Drummond, M., Petrou, S., et al.: Consolidated health economic evaluation reporting standards (CHEERS) statement. Cost Eff. Resour. Alloc. 11(1), 6 (2013)
Husereau, D., Drummond, M., Petrou, S., et al.: Consolidated health economic evaluation reporting standards (CHEERS)—explanation and elaboration: a report of the ISPOR health economic evaluation publication guidelines good reporting practices task force. Value Health 16(2), 231–250 (2013)
Craig D., Rice S.: NHS economic evaluation database handbook 2007. 3rd ed. p. 110. Centre for Reviews and Dissemination, University of York, York, UK (2007)
Centre for Reviews Dissemination: CRD’s guidance for undertaking reviews in healthcare. York Publ. Services, Layerthorpe, University of York (2009)
Adarkwah, C.C., van Gils, P.F., Hiligsmann, M., Evers, S.M.: Risk of bias in model-based economic evaluations: the ECOBIAS checklist. Expert Rev. Pharmacoecon. Outcomes Res. 16(4), 513–523 (2016)
Zethraeus, N., Johannesson, M., Jönsson, B., Löthgren, M., Tambour, M.: Advantages of using the net-benefit approach for analysing uncertainty in economic evaluation studies. Pharmacoeconomics 21(1), 39–48 (2003)
Crespo, C., Monleon, A., Díaz, W., Ríos, M.: Comparative efficiency research (COMER): meta-analysis of cost-effectiveness studies. BMC Med. Res. Methodol. 14(1), 139 (2014)
Willan, A.R.: Incremental net benefit in the analysis of economic data from clinical trials, with application to the CADET-Hp trial. Eur. J. Gastroenterol. Hepatol. 16(6), 543–549 (2004)
Haider, S., Chaikledkaew, U., Thavorncharoensap, M., et al.: Systematic review and meta-analysis of cost-effectiveness of rotavirus vaccine in low-income and lower-middle-income countries. Open Forum Infect. Dis. (2019). https://doi.org/10.1093/ofid/ofz117
Bagepally, B.S., Gurav, Y.K., Anothaisintawee, T., et al.: Cost utility of sodium-glucose cotransporter 2 inhibitors in the treatment of metformin monotherapy failed type 2 diabetes patients: a systematic review and meta-analysis. Value Health 22(12), 1458–1469 (2019)
Hoch, J.S., Dewa, C.S.: A clinician’s guide to correct cost-effectiveness analysis: think incremental not average. Can. J. Psychiatry 53(4), 267–274 (2008)
World Bank Country and Lending groups. The World Bank data (Consumer price index) (2019). https://data.worldbank.org/indicator/FP.CPI.TOTL
World Bank Country and Lending groups. The World Bank data (PPP conversion factors) (2019). https://data.worldbank.org/indicator/PA.NUS.PPP
World Bank Country and Lending Groups. World Bank country classification (2019) [updated 2019; cited 2019 July]. https://datahelpdesk.worldbank.org/knowledgebase/articles/906519-world-bank-country-and-lending-groups
IntHout, J., Ioannidis, J.P., Rovers, M.M., Goeman, J.J.: Plea for routinely presenting prediction intervals in meta-analysis. BMJ Open. 6(7), 10247 (2016)
Riley, R.D., Higgins, J.P., Deeks, J.J.: Interpretation of random effects meta-analyses. BMJ 342, d549 (2011)
Goh, B., Soraya, A., Goh, A., Ang, K.: Cost-effectiveness analysis for the treatment of hyperphosphatemia in predialysis patients: calcium-based versus noncalcium-based phosphate binders. Int. J. Nephrol. 2018, 1–7 (2018)
Yang, L., Tan, S.C., Chen, C., et al.: Economic evaluation of sevelamer versus calcium-based binders in treating hyperphosphatemia among patients with end-stage renal disease in China. Clin. Ther. 38(11), 2459–2467 (2016)
The National Institute for Health and Clinical Excellence (NICE). NICE clinical guideline 157—hyperphosphataemia in chronic kidney disease (appendix F Full health economic report). London, United Kingdom: the Centre for Clinical Practice at NICE (2009)
Taylor, M.J., Elgazzar, H.A., Chaplin, S., Goldsmith, D., Molony, D.A.: An economic evaluation of sevelamer in patients new to dialysis. Curr. Med. Res. Opin. 24(2), 601–608 (2008)
Manns, B., Klarenbach, S., Lee, H., et al.: Economic evaluation of sevelamer in patients with end-stage renal disease. Nephrol. Dial. Transplant. 22(10), 2867–2878 (2007)
Bernard, L., Mendelssohn, D., Dunn, E., Hutchison, C., Grima, D.T.: A modeled economic evaluation of sevelamer for treatment of hyperphosphatemia associated with chronic kidney disease among patients on dialysis in the United Kingdom. J. Med. Econ. 16(1), 1–9 (2013)
Cho, J.-H., Jang, H.M., Jung, H.-Y., et al.: A real-world cost-effectiveness analysis of sevelamer versus calcium acetate in Korean dialysis patients. Clin. Ther. 40(1), 123–134 (2018)
Thompson, M., Bartko-Winters, S., Bernard, L., et al.: Economic evaluation of sevelamer for the treatment of hyperphosphatemia in chronic kidney disease patients not on dialysis in the United Kingdom. J. Med. Econ. 16(6), 744–755 (2013)
Nguyen, H.V., Bose, S., Finkelstein, E.: Incremental cost-utility of sevelamer relative to calcium carbonate for treatment of hyperphosphatemia among pre-dialysis chronic kidney disease patients. BMC Nephrol. 17(1), 45 (2016)
del Pino, M.D., Pons, R., Rodríguez-Carmona, A., Liria, M.R., Subirà, R.: Análisis coste-efectividad de sevelámero frente a carbonato cálcico en pacientes con enfermedad renal crónica no dependientes de diálisis en España. PharmacoEcon. Span. Res. Artic. 13(2), 49–56 (2016)
Habbous, S., Przech, S., Martin, J., Garg, A.X., Sarma, S.: Cost-Effectiveness of first-line sevelamer and lanthanum versus calcium-based binders for hyperphosphatemia of chronic kidney disease. Value Health 21(3), 318–325 (2017)
Gros, B., Galán, A., González-Parra, E., et al.: Cost effectiveness of lanthanum carbonate in chronic kidney disease patients in Spain before and during dialysis. Health Econ. Rev. 5(1), 14 (2015)
Vegter, S., Tolley, K., Keith, M.S., Postma, M.J.: Cost-effectiveness of lanthanum carbonate in the treatment of hyperphosphatemia in chronic kidney disease before and during dialysis. Value Health 14(6), 852–858 (2011)
Vegter, S., Tolley, K., Keith, M.S., et al.: Cost-effectiveness of lanthanum carbonate in the treatment of hyperphosphatemia in dialysis patients: a Canadian payer perspective. Clin. Ther. 34(7), 1531–1543 (2012)
Goto, S., Komaba, H., Moriwaki, K., et al.: Clinical efficacy and cost-effectiveness of lanthanum carbonate as second-line therapy in hemodialysis patients in Japan. Clin. J. Am. Soc. Nephrol. 6(6), 1375–1384 (2011)
Brennan, A., Akehurst, R., Davis, S., Sakai, H., Abbott, V.: The cost-effectiveness of lanthanum carbonate in the treatment of hyperphosphatemia in patients with end-stage renal disease. Value Health 10(1), 32–41 (2007)
Park, H., Rascati, K.L., Keith, M.S., et al.: Cost-effectiveness of lanthanum carbonate versus sevelamer hydrochloride for the treatment of hyperphosphatemia in patients with end-stage renal disease: a US payer perspective. Value Health 14(8), 1002–1009 (2011)
González-Parra, E., Gros, B., Galán, A., et al.: Análisis coste-efectividad de carbonato de lantano frente a clorhidrato de sevelámero en el tratamiento de la hiperfosfatemia en pacientes con enfermedad renal crónica en España. PharmacoEcon. Span. Res. Artic. 12(1), 11–22 (2015)
Gutzwiller, F.S., Pfeil, A.M., Ademi, Z., et al.: Cost effectiveness of sucroferric oxyhydroxide compared with sevelamer carbonate in the treatment of hyperphosphataemia in patients receiving dialysis, from the perspective of the National Health Service in Scotland. Pharmacoeconomics 33(12), 1311–1324 (2015)
Canadian Agency for Drugs and Technologies in Health (CADTH). Pharmacoeconomic Review Report: Sucroferric Oxyhydroxide (Velphoro): (Vifor Fresenius Medical Care Renal Pharma Ltd.): Indication: For the control of serum phosphorus levels in adult patients with end-stage renal disease on dialysis. Ottawa (ON) (2019)
Panichi, V., Rosati, A., Di Giorgio, A., et al.: A pharmacoeconomic analysis of phosphate binders cost-effectiveness in the RISCAVID study. Blood Purif. 39(1–3), 174–180 (2015)
Huybrechts, K.F., Caro, J.J., Wilson, D.A., O’Brien, J.A.: Health and economic consequences of sevelamer use for hyperphosphatemia in patients on hemodialysis. Value Health 8(5), 549–561 (2005)
Huybrechts, K.F., Caro, J.J., O’Brien, J.A.: Prevention and management of hyperphosphatemia with sevelamer in Canada: health and economic consequences. Value Health 12(1), 16–19 (2009)
Ruggeri, M., Cipriani, F., Bellasi, A., et al.: Sevelamer is cost-saving vs calcium carbonate in non-dialysis-dependent CKD patients in Italy: a patient-level cost-effectiveness analysis of the INDEPENDENT study. Blood Purif. 37(4), 316–324 (2014)
Ruggeri, M., Bellasi, A., Cipriani, F., et al.: Sevelamer is cost-effective versus calcium carbonate for the first-line treatment of hyperphosphatemia in new patients to hemodialysis: a patient-level economic evaluation of the INDEPENDENT-HD study. J. Nephrol. 28(5), 593–602 (2015)
O’Mahony, J.F.: The limitations of icers in screening interventions and the relative net benefit alternative. Value Health 18(7), A705 (2015)
Net Monetary Benefit [online]. York: York Health Economics Consortium; (2016) [updated 2016; cited 2019 December 8]. Available from: https://yhec.co.uk/glossary/net-monetary-benefit/
Chow S.C.: Encyclopedia of biopharmaceutical statistics (Four volume set). 3rd ed., p. 2780. Chapman and Hall/CRC, North Carolina (2018)
Acknowledgement
This manuscript was generated from the Ph.D. thesis of Kamolpat Chaiyakittisopon’s under the Clinical Epidemiology (International Program), Faculty of Medicine, Ramathibodi Hospital and Faculty of Graduate Studies, Mahidol University.
Funding
None.
Author information
Authors and Affiliations
Contributions
KC, AT, OP, AI: Research idea and study design; KC, OP, NR, TS: Data acquisition; KC: Data analysis/interpretation; KC, AT: Statistical analysis; AT, OP, AI, GJM, JA: Supervision or mentorship. Each author contributed important intellectual content during manuscript drafting or revision, accepts personal accountability for the author’s own contributions, and agrees to ensure that questions pertaining to the accuracy or integrity of any portion of the work are appropriately investigated and resolved. KC takes responsibility that this study has been reported honestly, accurately, and transparently; that no important aspects of the study have been omitted.
Corresponding author
Ethics declarations
Conflict of interest
All authors declared no conflict of interest.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Below is the link to the electronic supplementary material.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Chaiyakittisopon, K., Pattanaprateep, O., Ruenroengbun, N. et al. Evaluation of the cost-utility of phosphate binders as a treatment option for hyperphosphatemia in chronic kidney disease patients: a systematic review and meta-analysis of the economic evaluations. Eur J Health Econ 22, 571–584 (2021). https://doi.org/10.1007/s10198-021-01275-3
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10198-021-01275-3