Transport of 14C-deferiprone in normal, thalassaemic and sickle red blood cells.

The transport of deferiprone (L1) in normal (N), sickle (S) and thalassaemic (T) red blood cells (RBC) was determined by incubation with 14C-L1 at 37 degrees C. Following incubation with 0.5 mM 14C-L1 for 4 h, the intracellular concentration of L1 in T RBC was 3 times higher than was found extracellularly. In contrast, no concentration gradient across N and S RBC membranes was detected. Efflux studies showed that T RBC released only 17 +/- 2% of 14C-L1 into the extracellular space. We hypothesize that L1 accumulation in T RBC results from their high content of chelatable iron and formation of large, hydrophilic L1-Fe(III) complexes trapped within the cytosol.

Pharmacokinetics of the oral iron chelator deferiprone (L1) in patients with iron overload.

Single oral dose pharmacokinetics of the iron chelator deferiprone (L1) were studied in 24 patients with chronic iron overload and correlated with 24 h urinary iron excretion (UIE) and creatinine clearance. Absorption of L1 was rapid with a t1/2 of 22.2 +/- 17.7 (mean +/- SD) min. The elimination half-life (elt1/2) of the drug was 91.1 +/- 33.1 min and of its metabolite, L1-glucuronide (L1G) 147.7 +/- 52.0 min. Creatinine clearance of the patients correlated significantly with the elimination t1/2 of L1G (r = -0.79, P = 0.002). There was also a significant correlation between 24 h UIE in the 14 patients studied and L1 versus time area under the curve (AUC) (P = 0.007). The total amount of L1 recovered in urine in 24 h comprised 77.9 +/- 13.3% of the L1 dose. L1 efficiency (the 24 h UIE divided by the amount of iron the oral dose of L1 is capable of binding) in the 14 patients was 3.8 +/- 1.9%. These data show for the first time that the urinary elimination of L1G is influenced by the renal function of the patient. Although no significant accumulation of L1 and L1G will occur in most of the patients if L1 is given more than once daily, in some patients with impaired renal function, L1G may accumulate.

Oral iron chelation therapy with deferiprone. Monitoring of biochemical, drug and iron excretion changes.

The oral iron chelator 1,2-dimethyl-3-hydroxypyrid-4-one (L1, deferiprone, CAS 30652-11-0) has been given daily for 3-11 months to 6 transfusion dependent iron loaded patients (myelodysplasia (MDS) 2, Diamond-Blackfan anaemia 1, thalassaemia intermedia 1, thalassaemia major 2). Daily doses of 3 g, 2 x 2 g and 3 x 2 g were administered for the first 2-7 months. Daily doses of 2 x 3 g were also used for periods up to 4 months. Urine iron excretion following 3 g of L1 was found to be related to the number of previous transfusions but not to serum ferritin or the amount of L1 excreted. In each case 24 h urinary iron excretion in response to 3 g L1 ranged from 5-21 mg in MDS, 13-25 mg in a thalassaemia intermedia and a Diamond-Blackfan patient and 16-110 mg in thalassaemia major patients. Further increases of urinary iron were observed in all the patients when the daily dose was increased. Serum ferritin levels have fluctuated but overall have remained unchanged. Biochemical assessment did not show any major abnormalities ascribed to L1 except from subnormal serum zinc levels in two patients and white blood cell absorbate in another. In a separate study we have compared urinary L1 and iron excretions in 7 transfusional iron loaded patients. In all the cases the concentration of L1 was in excess of iron and higher than the level required for 100% iron binding. There was no other apparent correlation between the concentrations of L1 and iron in the urines studied.(ABSTRACT TRUNCATED AT 250 WORDS)

Selection of a new generation of orally active alpha-ketohydroxypyridine iron chelators intended for use in the treatment of iron overload.

The prospect of selecting oral alpha-ketohydroxypyridine chelators intended for clinical use in iron overload has been examined using several animal models of efficacy and toxicity. Studies using iron dextran-loaded mice labelled with 59Fe have shown that only the 1-substituted methyl, ethyl, (n)propyl, allyl, cyclopropyl, 2'-methoxyethyl, 3'-ethoxypropyl, or 2-methyl- or 2-ethyl-3-hydroxypyrid-4-one chelators were orally effective in increasing iron (59Fe) excretion by comparison to intraperitoneally administered desferrioxamine at the same dose (250 mg/kg). In contrast, chelators containing -H, mono- or dihydroxyalkyl and diethoxyethyl 1-substituents caused very little or no increase in iron (59Fe) excretion by the oral or intraperitoneal routes. In vitro studies using ferritin and haemosiderin have shown that equivalent iron release took place with both groups of chelators irrespective of their in vivo effects. In most cases there was no correlation between the n-octanol/water partition coefficient (Kpar) and iron removal efficacy but positive correlation between the lipophilicity and acute or subacute toxicity of these chelators in rats. The most toxic chelator in the chronic toxicity studies in rats was the lipophilic 1,2-diethyl-3-hydroxypyrid-4-one (EL1NEt). The most effective chelator in increasing iron excretion in mice and rabbits was 1-allyl-2-methyl-3-hydroxypyrid-4-one (L1NAII), and the chelator with the highest safety margin in mice and rats was 1,2-dimethyl-3-hydroxypyrid-4-one (L1). Overall the oral effectiveness in increasing iron excretion by these chelators in animals does not appear to be related to their lipophilicity or their ability to mobilise polynuclear iron in vitro but rather to other properties possibly related to their rate of biotransformation and excretion.

Efficacy and possible adverse effects of the oral iron chelator 1,2-dimethyl-3-hydroxypyrid-4-one (L1) in thalassemia major.

Eleven patients with beta thalassemia major were entered into the trial of the oral chelator 1,2-dimethyl-3-hydroxypyrid-4-one (L1). Their ages ranged from 17 to 26 years (mean +/- SD, 22.3 +/- 2.7). Six were male and five were female. L1 was administered at an initial daily dose of 42.5 to 60 mg/kg as a single dose. After 4 weeks, the dose was increased to 85 to 119 (102 +/- 10.7) mg/kg for 191 to 352 days divided into either two or four doses daily, except for one patient who developed agranulocytosis after 11 weeks and was taken off the trial. Initial serum ferritin values in the remaining 10 patients ranged between 1,000 and 9,580 (5,549 +/- 3,333) micrograms/L and at end of the trial their mean serum ferritin was significantly lower (4,126 +/- 2,278; P less than .05 using the paired t-test). Urinary iron excretion at a daily dose of 85 to 119 mg/kg administered as two divided doses ranged between 0.14 and 0.82 (0.44 +/- 0.26) mg/kg/24 h. In three patients, the four doses per day schedule caused substantially more iron excretion than the same total dose divided into two. During the course of the trial, several possible adverse effects have been encountered. One patient (female, aged 20) developed agranulocytosis 11 weeks after starting treatment and 6 weeks after beginning treatment with a daily dose of 105 mg/kg. This patient's neutrophil count recovered spontaneously 7 weeks after the discontinuation of L1. A decrease in serum zinc levels to subnormal levels was observed in four patients with symptoms of dry skin, with an itchy scaly rash in two that was associated with low serum zinc levels that responded to zinc therapy. Urinary zinc levels ranged from 4.7 to 23.4 (13 +/- 5.5) mumol/24 h and were above 9 mumol/24 h (upper limit of normal) in eight patients. Mild nausea occurred in three patients and transient diarrhea in a fourth. Mild musculoskeletal symptoms occurred in three patients but settled without discontinuation of L1 therapy in two and with temporary discontinuation of L1 in the third. A transient increase in serum aspartate transaminase was also noted in five patients, but serum aspartate transaminase levels subsequently decreased in all of them. No cardiovascular, neurologic, renal, or retinal toxicities were demonstrable. These results confirm that L1 is an effective oral iron chelator. Further clinical trials are needed to determine the incidence and severity of adverse effects.

Long-term trial with the oral iron chelator 1,2-dimethyl-3-hydroxypyrid-4-one (L1). I. Iron chelation and metabolic studies.

A long-term clinical trial of 1-15 months has been carried out with the oral iron chelator 1,2-dimethyl-3-hydroxypyrid-4-one (L1) in 13 transfusion-dependent iron-loaded patients. Urinary iron excretion was greatest in patients with thalassaemia major and was related to the number of previous transfusions but not to the serum ferritin level. Substantial increases of urinary iron were observed in all the patients when the frequency of the daily dose was doubled and in response to 2 x 3 g L1 daily 11 of 12 patients tested excreted greater than 25 mg iron daily, the mean daily intake of iron from transfusion. Serum ferritin levels have fluctuated but overall have remained unchanged. Pharmacological studies in five patients have indicated rapid absorption probably from the stomach and variable plasma half life of 77 +/- 35 min (X +/- SD). Glucuronation was identified as a major route of L1 metabolism. Short-term intensive chelation studies using repeated administration of L1 resulted in further increases of urinary iron excretion by comparison to a single dose. In one case 325 mg of iron were excreted in the urine following the administration of 16 g (5 x 2 g + 2 x 3 g) within 24 h. Iron excretion studies were carried out in six transfusional iron-loaded patients who were maintained on a low iron diet before and during chelation. No significant increases of faecal iron excretion were observed with L1 using daily doses of up to 3 x 3 g and 4 x 2 g. The high level of compliance during treatment with L1 and the levels of urine iron excretion that can be achieved increase the prospects for oral chelation in transfusional iron-loaded patients.