Peter Geisser

The Pharmacokinetics and Pharmacodynamics of Iron Preparations

Standard approaches are not appropriate when assessing pharmacokinetics of iron supplements due to the ubiquity of endogenous iron, its compartmentalized sites of action, and the complexity of the iron metabolism. The primary site of action of iron is the erythrocyte, and, in contrast to conventional drugs, no drug-receptor interaction takes place. Notably, the process of erythropoiesis, i.e., formation of new erythrocytes, takes 3–4 weeks. Accordingly, serum iron concentration and area under the curve (AUC) are clinically irrelevant for assessing iron utilization. Iron can be administered intravenously in the form of polynuclear iron(III)-hydroxide complexes with carbohydrate ligands or orally as iron(II) (ferrous) salts or iron(III) (ferric) complexes. Several approaches have been employed to study the pharmacodynamics of iron after oral administration. Quantification of iron uptake from radiolabeled preparations by the whole body or the erythrocytes is optimal, but alternatively total iron transfer can be calculated based on known elimination rates and the intrinsic reactivity of individual preparations. Degradation kinetics, and thus the safety, of parenteral iron preparations are directly related to the molecular weight and the stability of the complex. High oral iron doses or rapid release of iron from intravenous iron preparations can saturate the iron transport system, resulting in oxidative stress with adverse clinical and subclinical consequences. Appropriate pharmacokinetics and pharmacodynamics analyses will greatly assist our understanding of the likely contribution of novel preparations to the management of anemia.

The new generation of intravenous iron: chemistry, pharmacology, and toxicology of ferric carboxymaltose

An ideal preparation for intravenous iron replacement therapy should balance effectiveness and safety. Compounds that release iron rapidly tend to cause toxicity, while large molecules can induce antibody formation and cause anaphylactic reactions. There is therefore a need for an intravenous iron preparation that delivers appropriate amounts of iron in a readily available form but with minimal side effects and thus with an excellent safety profile. In this paper, a review is given on the chemistry, pharmacology, and toxicology of ferric carboxymaltose (FCM, Ferinject), a stable and robust complex formulated as a colloidal solution with a physiological pH. The complex is gradually taken up mainly from the hepatic reticulo-endothelial system (RES), followed by effective delivery of iron to the endogeneous transport system for the haem synthesis in new erythrocytes, as shown in studies on the pharmacodynamics and pharmacokinetics with radio-labelled FCM. Studies with radio-labelled FCM also demonstrated a barrier function of the placenta and a low transfer of iron into the milk of lactating rats. Safety pharmacology studies indicated a favourable profile with regard to cardiovascular, central nervous, respiratory, and renal toxicity. A high maximum non-lethal dose was demonstrated in the single-dose toxicity studies. Furthermore, based on the No-Observed-Adverse-Effect-Levels (NOAELs) found in repeated-dose toxicity studies and on the cumulative doses administered, FCM has good safety margins. Reproductive and developmental toxicity studies did not reveal any direct or indirect harmful effects. No genotoxic potential was found in in vitro or in vivo studies. Moreover, antigenicity studies showed no cross-reactivity of FMC with anti-dextran antibodies and also suggested that FCM does not possess sensitizing potential. Lastly, no evidence of irritation was found in local tolerance studies with FCM. This excellent toxicity profile and the high effectiveness of FCM allow the administration of high doses as a single infusion or bolus injection, which will enhance the cost-effectiveness and convenience of iron replacement therapy. In conclusion, FCM has many of the characteristics of an ideal intravenous iron preparation.

Pharmacokinetics, safety and tolerability of intravenous ferric carboxymaltose: a dose-escalation study in volunteers with mild iron-deficiency anaemia

Iron-deficiency anaemia (IDA) represents a major burden to public health worldwide. The therapeutic aim for patients with IDA is to return iron stores and haemoglobin (Hb) levels to within the normal range using supplemental iron therapy and erythropoiesis-stimulating agents. Oral and previous intravenous (i.v.) iron formulations have a number of disadvantages, including immunogenic reactions, oxidative stress, low dosages, long administration times and the requirement for a test dose. Ferric carboxymaltose (FCM, Ferinject) is a novel, next-generation i.v. iron formulation with the potential to overcome these limitations. In this single-centre, randomized, double-blind, placebo-controlled study, the pharmacokinetics (PK), pharmacodynamics (PD), safety and tolerability of single, escalating doses of FCM were investigated. Four ascending doses were investigated in a total of 24 patients with mild IDA (defined as serum ferritin < 20 microg/l and transferrin saturation [TfS] < 16%): 100 mg iron as FCM given as an i.v. bolus injection, and 500, 800 and 1000 mg iron as FCM given as an i.v. infusion over 15 min. At each dose level six patients received FCM and two received placebo. The decision to escalate to the next dose was based on evaluation of safety and tolerability data from the previous dose. The maximum duration of the study was 5 weeks from screening to final assessment. Assessments were made of PK iron-status parameters up to 168 h post-dose. Safety assessments included incidence of adverse events (AEs), clinical laboratory parameters and vital signs. PK and PD parameters were analysed using descriptive statistics. All analyses were performed on the safety population, which included all patients who received > or = 1 dose of study medication. Seventy-seven patients were screened and, of these, 32 male and female patients with pre-study Hb between 9.2 and 11.9 g/dl and serum ferritin < 20 microg/l were included in the study. Two patients had TfS > 16% (19.2% and 17.2%); both patients were considered by the investigator to be eligible for inclusion. Compared with placebo, a rapid, dose-dependent increase in total serum iron was observed across all dose groups. Mean (standard deviation) maximum total serum iron levels ranged between 36.9 (4.4) and 317.9 (42.3) microg/ml in the 100 and 1000 mg groups. Concentration-time curves of total serum iron continuously declined for up to 24 and 72 h post-dose in the 100 and 500-1000 mg groups, respectively. Non-compartmental analysis of PK parameters was truncated at 24 h (100 mg) and 72 h (500-1000 mg doses). A dose-dependent, but not dose-linear, increase in serum ferritin was seen in all treatment groups compared with placebo, with peak levels of a 23-210-fold increase above baseline occurring 48-120 h postdose. Iron-binding capacity was transiently almost fully utilized after doses of 500, 800 and 1000 mg (TfS > 95%). No meaningful changes in serum transferrin or serum transferrin receptor concentrations were observed during this study. The elimination pattern for FCM appeared to be mono-exponential; FCM was cleared from serum with a terminal halflife of approximately 7.4-12.1 h. The percentage of FCM excreted in urine was negligible (0.0005%). FCM was well tolerated; a total of 19 AEs were reported by 8/32 patients (25%), of which three were considered by the investigator to be related to FCM: nausea and vomiting (one patient [100 mg]), and headache (one patient [1000 mg]). The incidence of AEs did not increase with dose. No severe or serious AEs, or deaths occurred. FCM had no significant effect on laboratory safety parameters or vital signs. This study satisfactorily characterized the PK/PD parameters of single doses of 100, 500, 800 and 1000 mg iron as FCM. The majority of FCM was utilized or eliminated within 24 h of administration of a 100 mg dose and within 72 h of a 500-1000 mg dose. FCM was generally well tolerated across all doses in patients with mild IDA.

Pharmacodynamics and safety of ferric carboxymaltose: a multiple-dose study in patients with iron-deficiency anaemia secondary to a gastrointestinal disorder.

This multiple-dose Phase I/II study provided pharmacodynamics and pharmacokinetics data on the therapeutic benefit of ferric carboxymaltose (FCM, Ferinject) and evaluated the safety and tolerability of this intravenous (i.v.) iron preparation. Two doses of iron as FCM were given as i.v. infusion over 15 min, 500 mg iron given once weekly for up to 4 weeks (Cohort 1) or 1000 mg iron weekly for 2 weeks (Cohort 2), in patients with a total requirement > or = 1000 mg iron (total cumulative maximum dose < or = 2000 mg iron). Adults with moderate to severe, stable iron-deficiency anaemia (IDA) (haemoglobin [Hb] < or = 11.0 g/dl, serum ferritin < 100 microg/l, transferrin saturation [TSAT] < 16%) due to a gastrointestinal (GI) disorder were included. Pharmacodynamics variables: proportion of patients achieving values within the reference range for Hb (men: 14.0-18.0 g/dl, women: 12.0-16.0 g/dl), serum ferritin (20-500 microg/l), TSAT (16-45%) and proportion of patients with an increase in Hb of at least 2.0 g/dl. Pharmacokinetics variables: total serum iron levels at time of maximum serum iron concentration during the fast elimination phase and at trough time-points. Safety assessments: the incidence of adverse events (AEs) and changes in vital signs, physical examinations, and clinical laboratory parameters. In Cohorts 1 and 2, 14/20 (70%) versus 19/26 (73%) of patients completed the study. Individual calculated iron deficits were 1000-2100 mg. The mean cumulative dose of FCM in Cohorts 1 and 2 was 1800 mg and 1563 mg iron, respectively. At baseline, patients in both cohorts had similar Hb levels (mean 8.7 g/dl in both cohorts). More than 97% of patients demonstrated a clinically meaningful increase in Hb levels (> or = 1.0 g/dl) during the study. By the week 4 follow-up visit, an increase of at least 2.0 g/dl was achieved by 15/20 (75%) and by 19/26 (73.1%) patients in Cohorts 1 and 2, respectively, and the mean increase in Hb was 3.2 g/dl in Cohort 1 and 3.3 g/dl in Cohort 2. By day 28, 3/6 (50%) patients in Cohort 1 had achieved normal Hb levels, and by the 4-week post-treatment followup visit 7/19 patients (37%) in Cohort 1 and 12/25 (48%) in Cohort 2 had reached Hb levels within the reference range. Serum ferritin levels increased rapidly at the start of treatment and remained in the reference range throughout the study; increases were greater in Cohort 2. Mean baseline TSAT values were similar in both cohorts (24.2% in Cohort 1, 20.7% in Cohort 2), and were within the reference range at the week 4 follow-up visit for 41.0 and 39.1% of the patients in Cohorts 1 and 2, respectively. The incidence of AEs occurring after the first administration of FCM (treatment-emergent AEs, TEAE) was generally low and similar in Cohorts 1 (11/20 [55.0%]) and 2 (13/26 [50.0%]). Most TEAEs were mild; only 2/ 20 patients (10.0%) in Cohort 1 and 3/26 (11.5%) in Cohort 2 had TEAEs of moderate intensity. There were no AEs of severe intensity, serious AEs, or deaths. Most AEs were considered by the investigator to be unrelated or unlikely to be related to the study medication. Since accumulation of serum iron was not observed, a dosing interval of 3-4 days (500 mg iron) or 1 week (1000 mg iron) was demonstrated to be adequate. The increase in serum ferritin and TSAT at the 4-week follow-up visit is indicative of a repletion of the iron stores. The results suggest that doses up to 1000 mg i.v. iron administered as FCM over 15 min arewell tolerated and effective in the treatment of patients with IDA due to a GI disorder.

Effects of oral iron (III) hydroxide polymaltose complex supplementation on hemoglobin increase, cognitive function, affective behavior and scholastic performance of adolescents with varying iron status: a single centre prospective placebo controlled study.

OBJECTIVE To assess the effects of iron supplementation on iron status, cognitive function, affective behavior and scholastic performance in adolescents with varying iron status. METHODS Adolescents of both sexes with varying iron status were allocated to four treatment groups by using inclusion criteria. Three of the four groups (iron deficient anemic, iron deficient and control supplement) received iron(III) hydroxide polymaltose complex (IPC, Maltofer) containing 100 mg of elemental iron 6 days a week for 8 months, while the fourth group (control placebo) was given a placebo. Hematological parameters, cognitive function, affective behavior and scholastic performance were assessed at baseline, 4 months and 8 months of supplementation. RESULTS Cognitive and scholastic performance test scores for the three supplemented groups increased from baseline to 4 months and from 4 months to 8 months (with concomitant increases in hematological parameters), whereas no increase was observed in the placebo group. No increase was seen in affective behavior scores for any of the groups during or after supplementation. CONCLUSIONS IPC supplementation for eight months yielded significant improvements in cognitive function and scholastic performance in Indian adolescents with and without iron deficiency and anemia.

Effect of oral aluminium hydroxide on iron absorption from iron(III)-hydroxide polymaltose complex in patients with iron deficiency anemia / a single-centre randomized controlled isotope study.

The study was carried out as an open-label, laboratory-blind, single-dose, randomized, two-period crossover, isotope efficacy study. Twenty-two patients with iron-deficiency anemia were enrolled in the study. The study consisted of two treatment phases of 15 days each, including blood sample measurements for Fe-59 activity. The two treatments were given orally. Treatment A was Fe-59 labeled iron(III)-hydroxide polymaltose complex (IPC, Maltofer) equivalent to 100 mg elemental iron given orally. Treatment B consisted of Fe-59 labeled IPC complex equivalent to 100 mg elemental iron and 500 mg tetracycline HCl (CAS 64-75-5) given orally. No differences between the two treatment groups with regard to the erythrocyte iron uptake were found, and thus IPC can be used with tetracycline, if necessary.

Milk iron content in breast-feeding mothers after administration of intravenous iron sucrose complex

Abstract Objective: To study the transfer of parenteral iron sucrose into maternal milk in the postpartum period. Study design: Ten healthy lactating mothers with functional iron deficiency 2–3 days after delivery received 100 mg intravenous iron sucrose and were observed together with a control group (n=5) without iron treatment during four days. Milk samples were taken before the treatment and every day afterwards. Results: Mean milk iron levels at baseline were 0.43 and 0.46 mg/kg in the treatment and control group and decreased until the end of observation in both groups by 0.11 mg/kg. No significant difference between the groups was found on any study day as well as in the mean change from baseline over all four days. Conclusion: We could not show transfer of iron-sucorose into maternal milk for the given dosage. Since parenteral iron sucrose is widely used in obstetrics, the results provide information about safety of parenteral iron sucrose in the lactation period. The findings are also in agreement with other reports on active biological mammary gland regulation of milk iron concentration.