Longitudinal changes in bone and mineral metabolism after cessation of cinacalcet in dialysis patients with secondary hyperparathyroidism

This was a single-center prospective observational study performed at The Royal Melbourne Hospital. The aim was to assess the impact of withdrawal of cinacalcet in patients on dialysis over a 12-month period. The study was approved by the Melbourne Health Human Research Ethics Committee (#HREC 2015.180) and patient enrollment commenced in August 2015 with completion in March 2016.

Patients receiving dialysis at The Royal Melbourne Hospital or affiliated satellite dialysis units were eligible for recruitment, and written informed consent was obtained from all participants at study commencement. Inclusion criteria included patients with the ability to provide informed consent, aged over 18 years old and prescribed cinacalcet therapy for clinical features of severe SHPT, not adequately controlled with active vitamin D therapy, and a PTH level greater than nine times the upper limit of normal as per the Kidney Disease: Improving Global Outcome (KDIGO) CKD-MBD guidelines [1]. There were no specific exclusion criteria. Starting doses of cinacalcet were 30 mg/day and doses had been titrated to achieve symptom control and a PTH target within the KDIGO guideline suggested range. A detailed medication history was recorded for patients at each visit, and date of cinacalcet cessation was documented in the patient’s medical records. All patients provided written informed consent before enrollment and the study was conducted in accordance with the Declaration of Helsinki.

No specific protocol existed for the management of SHPT following cinacalcet withdrawal. Treatment was based on usual clinical care for SHPT including reduction of serum phosphate and administration of active vitamin D therapy with avoidance of hypocalcemia. Patients were referred for surgical parathyroidectomy if they had a persistently elevated PTH above the KDIGO guidelines, evidence of high turnover bone disease or symptoms of severe PTH. Dialysate calcium in hemodialysis and peritoneal dialysis patients remained unchanged following cinacalcet withdrawal.

Two control cohorts were used in this study to the potential effects of temporal changes unrelated to drug cessation. The first was a historical age-, gender- and dialysis vintage- matched control cohort who were cinacalcet naïve. We compared demographic features and biochemical parameters over a 12-month period between the control cohort and the cinacalcet withdrawal cohort from July 2015 to July 2016. This control cohort was identified from the Nephrology database at The Royal Melbourne Hospital, and all patients included had no history of prior cinacalcet use. The second control group included a subset of thirteen cinacalcet naïve dialysis patients from the historical control cohort that were age and dialysis modality matched, who had serum samples collected at baseline (June 2017) and after 6 months for CPP analysis. The purpose of this control group was to assess whether a rise in CPP observed in the intervention group reflected a response to drug cessation or a more generic rise in CPP that would be observed in any group of chronic dialysis patients with progressive disease over time. Management of CKD-MBD in the control cohort was as per usual standard care for SHPT, involving treatment of hyperphosphatemia and use of active vitamin D therapy as indicated by the treating clinician.

The primary endpoint was change in CPP following cessation of cinacalcet therapy over a 12-month period. Secondary biochemical outcome measures included serum changes in PTH, calcium, phosphate, alkaline phosphatase (ALP), ferritin and C-reactive protein (CRP), as well as hemoglobin.

Serum was collected in all patients at baseline, whilst still being administered cinacalcet and then following cessation of cinacalcet at 1 month, 6 months and 12 months. Samples were collected to measure the following parameters: total CPP, CPP-I, CPP-II, albumin, calcium, phosphate, PTH, hemoglobin, CRP, ferritin, and ALP. Serum calcium level was adjusted as follows if serum albumin was < 40 g/L: corrected serum calcium (mmol/L) = measured serum calcium (mmol/L) + 0.02 x (40 - serum albumin (g/L)). For CPP analysis blood was collected into 6 ml plain tubes using standard phlebotomy techniques. Blood samples were allowed to stand for 60 min and then centrifuged at 3000 g for 15 min at room temperature. Aliquots were stored at − 80 C until batched analysis.

A novel method to evaluate CPP using flow cytometry has recently been published by our group [15]. Briefly, batched patient samples were run on a BD FACSVerse flow cytometer using high sensitivity fluidics. The instrument was operated using BD FACSSuite software (version 1.0.5). Raw FCS files were acquired and imported into FlowJo LLC version 10.1 revision 3 (Ashland, Oregon, USA) for analysis. OsteoSense 680EX fluorescence was detected with a red 640 nm laser. Acquisition settings were held constant for all samples (60 s or 30,000 events). All measurements were displayed in logarithmic scale and signal stability was assessed in real-time using SSC-H vs. time plots. The gating strategy for CPP was set empirically, as described in Fig. 1.

Baseline characteristics are reported as mean+/− standard deviation (SD) or, when appropriate, median (interquartile range [IQR]) for continuous variables and as a number and percentage for categorical variables. Paired t test and Wilcoxon signed-rank test were used for between group comparisons. Categorical variables were analyzed with the chi-square test. Continuous variables were compared with independent samples paired t test if normally distributed or with Mann-Whitney U test if the distribution was skewed. Mixed linear effect modelling was used to determine differences within groups over the study period, with the variables selected a priori, based on known regulatory relationships. CPP and PTH were natural log-transformed (Ln) for the purposes of these analyses. All mixed-effect model analyses were performed allowing for the random effect of different pathology collection times and locations. Two-tailed P values < 0.05 were considered statistically significant. Analyses were performed using SPSS software for Macintosh version 21 (IBM SPSS, Chicago, IL).

One hundred and twenty-eight patients on dialysis were being administered cinacalcet during the recruitment period of August 2015 to March 2016 and were approached to participate in the study. Figure 2 describes the participant flow. Sixty-six were excluded either due to patient or physician preference as many of these patients had a supply of medication remaining and continued on therapy. Sixty-two patients were enrolled in the study, and their cinacalcet cessation date was documented in medical records. Six patients received a kidney transplant and five re-commenced cinacalcet therapy via an industry sponsored special-access scheme during the 12-month follow up period. Fifty-one patients were included in the primary outcome analysis.

Baseline characteristics of study participants and the contemporaneous age- and gender-matched cinacalcet-naïve dialysis controls are shown in Table 1. Only dialysis modality was significantly different between the two groups, with more patients in the cinacalcet withdrawal cohort on hemodialysis, 86% vs 57%, (p = 0.001). The mean age and time on dialysis were 69.9±13.2 years and 7.1±3.6 years respectively in the cinacalcet withdrawal cohort. Over 50% of participants were male, 45% had a history of diabetes and 76% had hypertension. The main etiology of CKD was diabetic nephropathy.

In the 12 months following withdrawal of cinacalcet therapy there were two lower limb fractures, one parathyroidectomy with three patients referred for parathyroid surgery, and one episode of calciphylaxis. Thirteen patients died during the study period, with deaths due to cardiovascular causes (n = 5), withdrawal from dialysis (n = 3) and other causes including malignancy and infection (n = 4). In the control group there were five fractures, one parathyroidectomy and no episodes of calciphylaxis. Of the 10 deaths in the control group, three were due to cardiovascular causes.

A change in prescribing patterns following cinacalcet withdrawal were observed. At baseline 76% of patients (n = 39) were on calcitriol, which reduced to 57% (n = 29) by 12 months (p = 0.03). Four patients were commenced on calcitriol de novo. Calcitriol doses increased over the study period (1.3 mcg/week versus 1.7 mcg/week at baseline and 12 months respectively, p = 0.04). Of 21 patients on a calcium-based phosphate binder at baseline, 12 continued this therapy at 12 months (p = 0.05). Seventy-six percent of patients (n = 39) were on a non-calcium based phosphate binder at baseline, 59% of patients (n = 30) remained on therapy at study completion (p = 0.06). No patients were on magnesium supplementation. There were 12 episodes of hypercalcemia (serum corrected calcium > 2.60 mmol/L), with 9 episodes occurring by 6 months. There were no episodes of hypercalcemia in the control arm. The dosage or number of patients taking nutritional vitamin D supplementation did not significantly change over the year (12 at baseline versus 10 at 12 months, p = 0.63).

Baseline levels of PTH, phosphate, calcium and ALP were similar across the two groups (Table 2). In the cinacalcet withdrawal cohort, there was an increase in PTH from 42.2 pmol/L (27.8–94.6 pmol/L) at baseline to 114.8 pmol/L (83.9–159.1 pmol/L) at 12 months (p < 0.001). The highest rate of change in PTH occurred at 1 month with a mean PTH increase of 93% from baseline (p < 0.001). Serum calcium also increased from 2.31±0.21 mmol/L to 2.46±0.14 mmol/L over 12 months (p < 0.001). There was no change in PTH or serum calcium in the control group over 12 months. Phosphate remained unchanged in the cinacalcet withdrawal group (p = 0.8) and the control group (p = 0.6) over the 12-month study period. Table 2 summarizes baseline, 6- and 12-month values for biochemical outcomes in the control and cinacalcet withdrawal cohorts.

A trend towards increased ALP (141.4±61 IU/L at baseline to 161.7±72.9 IU/L at 12 months) was seen in the cinacalcet withdrawal cohort over the study period but did not reach statistical significance (p = 0.09). Inflammatory markers including CRP and the positive acute-phase reactant ferritin remained unchanged over 12 months, however there was a modest decrease in serum albumin from 35±4.2 g/L to 33±4.5 g/L, p = 0.03. This trend was not observed in the control group. Hemoglobin and serum bicarbonate were also equivalent in both groups over the study period. Changes in biochemical markers in the cinacalcet withdrawal group are presented in Fig. 3.

CPP assessment and characterization was performed using a novel flow cytometry method published by our group [15]. Four out of 51 study patients were excluded from final CPP analysis due to sample instability and unknown analytical interference. Table 3 describes the changes in CPP in the cinacalcet withdrawal group, including patients who received a transplant or re-started therapy during the study period. Total CPP at baseline were 3.3 × 10⁴/μL (IQR: 1.5 × 10⁴/μL to 5.7 × 10⁴/μL), predominantly as CPP-II at baseline (61% of total CPP) and 12 months (58% of total CPP), p = 0.06.

CPP-I increased significantly over the study period (396% mean increase, p = 0.002). Total CPP showed a trend towards increasing levels, but this did not reach statistical significance (p = 0.05). Figure 4 depicts cohort and patient-level changes in serial absolute CPP levels over the study period and relative % changes from baseline values.

Utilizing a mixed linear effect model, allowing for random effects, changes in total and CPP-I counts were significantly associated with changes in PTH (p = 0.007 and 0.04 respectively). Total CPP, CPP-I and CPP-II counts were all longitudinally associated with changes in serum calcium (p = 0.002, 0.02 and 0.001 respectively), albumin (p = 0.001, 0.004 and < 0.001) and ferritin concentrations (p = 0.03, 0.01, and 0.009). Only changes in CPP-II were associated with the change in phosphate (p = 0.03) and ALP (p = 0.05). In contrast to those in the cinacalcet withdrawal cohort, there was no change in total CPP (p = 0.4), CPP-I (p = 0.2) or CPP-II (p = 0.1) in patients who received a kidney transplant or in those who re-started cinacalcet (total CPP (p = 0.15), CPP-I (p = 0.2), CPP-II (p = 0.2)) over the study period, although numbers were small.

Thirteen stable cinacalcet-naïve dialysis patients were used as a control cohort for CPP analysis, mean age 70.8±13years, 77% male, with 12 patients on hemodialysis and one on peritoneal dialysis. There were no significant differences in demographic characteristics between the control and the cinacalcet withdrawal cohorts, other than a higher proportion of patients on hemodialysis in the CPP analysis cohort (p = 0.02). There were no hospitalizations or changes in phosphate binder or active vitamin D prescription patterns in the control group. Over a six-month period, there was no significant increase in PTH (p = 0.1), serum calcium (p = 0.69), phosphate (p = 0.37), ALP (p = 0.86) or CPP-I (p = 0.08) and CPP-II (p = 0.26). In the control cohort of 13 stable cinacalcet naïve patients, CPP were mainly CPP-I (mean 79% CPP-I versus mean 21% CPP-II). The mean percentage increase in total CPP and CPP-I over a six-month period was significantly lower in the control group compared to the cinacalcet withdrawal cohort (p = 0.03 and p = 0.05 respectively). This effect was not seen for CPP-II (p = 0.07). Figure 5 shows the mean percentage changes in total CPP, CPP-I and CPP-II from baseline to 6 months values in cinacalcet withdrawal patients compared to control patients.