George J. Kontoghiorghes

1,2-Dimethyl-3-hydroxypyrid-4-one, an orally active chelator for treatment of iron overload.

Subcutaneous desferrioxamine, though effective in preventing or reducing iron overload in transfusion-dependent refractory anaemia, is expensive and inconvenient. One potentially cheaper and orally active alternative is 1,2-dimethyl-3-hydroxypyrid-4-one (L1). This drug has been tested in three multiply transfused patients with myelodysplasia. Gelatin capsules were taken at doses ranging from 0.5 g to 3.0 g. Urinary iron excretion increased substantially in all three patients and in the one tested was equal to that achieved with comparable doses of subcutaneous desferrioxamine. The amounts of iron excreted were related to the dose of L1 administered and the iron load of the patients. The urinary excretion of zinc, magnesium, and calcium did not increase, and the drug was well tolerated.

Effective chelation of iron in beta thalassaemia with the oral chelator 1,2-dimethyl-3-hydroxypyrid-4-one.

The main iron chelator used for transfusional iron overload is desferrioxamine, which is expensive, has toxic side effects, and has to be given subcutaneously. An orally active iron chelator is therefore required. The effects of oral 1,2-dimethyl-3-hydroxypyrid-4-one on urinary iron excretion were studied in eight patients who had received multiple transfusions: four had myelodysplasia and four beta thalassaemia major. Different daily doses of the drug up to 100 mg/kg/day, alone or in combination with ascorbic acid, were used. In three patients with thalassaemia the effect of the drug was compared with that of subcutaneous desferrioxamine at the same daily dose. In all eight patients a single dose of oral 1,2-dimethyl-3-hydroxypyrid-4-one resulted in substantial urinary iron excretion, mainly in the first 12 hours. Urinary iron excretion increased with the dose and with the degree of iron loading of the patient. Giving two or three divided doses over 24 hours resulted in higher urinary iron excretion than a single dose of the same amount over the same time. In most patients coadministration of oral ascorbic acid further increased urinary iron excretion. 1,2-Dimethyl-3-hydroxypyrid-4-one caused similar iron excretion to that achieved with subcutaneous desferrioxamine at a comparable dose. In some cases the iron excretion was sufficiently high (maximum 99 mg/day) to suggest that a negative iron balance could be easily achieved with these protocols in patients receiving regular transfusions. No evidence of toxicity was observed on thorough clinical examination or haematological and biochemical testing in any of the patients. None of the patients had any symptoms that could be ascribed to the drug. These results suggest that the oral chelator 1,2-dimethyl-3-hydroxypyrid-4-one is as effective as subcutaneous desferrioxamine in increasing urinary iron excretion in patients loaded with iron. Its cheap synthesis, oral activity, and lack of obvious toxicity at effective doses suggest that it should be developed quickly and thoroughly tested for the management of transfusional iron overload.

Iron: mammalian defense systems, mechanisms of disease, and chelation therapy approaches.

During the past 6 decades, much attention has been devoted to understanding the uses, metabolism and hazards of iron in living systems. A great variety of heme and non-heme iron-containing enzymes have been characterized in nearly all forms of life. The existence of both ferrous and ferric ions in low- and high-spin configuration, as well as the ability of the metal to function over a wide range of redox potentials, contributes to its unique versatility. Not surprisingly, the singular attributes of iron that permit it to be so useful to life likewise render the metal dangerous to manipulate and to sequester. All vertebrate animals are prone to tissue damage from exposure to excess iron. In order to protect them from this threat, a complex system has evolved to contain and detoxify this metal. This is known as the iron withholding defense system, which mainly serves to scavenge toxic quantities of iron and also for depriving microbial and neoplastic invaders of iron essential for their growth. Since 1970, medical scientists have become increasingly aware of the problems involved in cellular iron homeostasis and of the disease states related to its malfunctioning. Scores of studies have reported that excessive iron in specific tissue sites is associated with development of infection, neoplasia, cardiomyopathy, arthropathy and a variety of endocrine and neurologic deficits. Accordingly, several research groups have attempted to develop chemical agents that might prevent and even eliminate deposits of excess iron. A few of these drugs now are in clinical use, e.g. deferiprone (L1). In the present review, we focus on recent developments in (i) selected aspects of the iron withholding defense system, and (ii) pharmacologic methods that can assist the iron-burdened patient.

Pharmacokinetic studies in humans with the oral iron chelator 1,2-dimethyl-3-hydroxypyrid-4-one.

Pharmacokinetic studies have been carried out with the oral iron chelator 1,2‐dimethyl‐3‐hydroxypyrid‐4‐one (L1). HPLC analysis of serum of a normal volunteer and seven transfusional iron loaded patients who ingested a 3 gm dose of L1 revealed that L1 was most probably absorbed from the stomach and was transferred to the blood with a half‐life of 0.7 to 32 minutes. L1 reached maximum concentration in the serum 12 to 120 minutes after administration with 85% to 90% elimination within the first 5 to 6 hours, with a half‐life of 47 to 134 minutes. L1 and its glucuronide metabolite were identified in serum and urine but not in feces. In most cases hydrolysis of 24‐hour urine samples with use of β‐glucuronidase resulted in almost complete recovery of the administered dose. Urinary iron excretion was proportional to the iron load but not to the serum or urine concentration of L1. The therapeutic efficiency of L1 can therefore be improved by repeated administration of 2 to 3 gm doses at least every 6 hours.

Long-term trial with the oral iron chelator 1,2-dimethyl-3-hydroxypyrid-4-one (L1) I. IRON CHELATION AND METABOLIC STUDIES

Summary 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 ironloaded 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 ± 3 g L1 daily 11 of 12 patients tested excreted > 2 5 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 (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 16g (5 ± 2g + 2 ± 3g) 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 3.3 g and 4 ± 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.

Comparative efficacy and toxicity of desferrioxamine, deferiprone and other iron and aluminium chelating drugs

The efficacy and toxicity aspects of the iron and aluminium chelating drugs desferrioxamine and deferiprone (L1, 1,2-dimethyl-3-hydroxypyrid-4-one), have been compared. Major emphasis was given in the use of these two and also of other chelators in conditions of iron overload, imbalance and toxicity, as well as the incidence and possible causes of toxic side effects in both animals and humans. The chemical basis of chelation and the interaction of these chelators with the iron pools are discussed within the context of clinical application in iron overload and other conditions such as renal dialysis, rheumatoid arthritis, cancer, heart disease, malaria, etc. The design and development of new orally active alpha-ketohydroxypyridine and other chelators are considered and compared with 14 other chelators which have been previously tested in man for the removal of iron, most of which, however, were later abandoned because of low efficacy or major toxicity. The design of new therapeutic protocols based on the pharmacological, toxicological and metabolic transformation properties of the chelating drugs is also being considered, within the context of maximising their efficacy and minimising their toxicity. Overall, oral deferiprone appears to be as effective as s.c. desferrioxamine in the removal of iron and aluminium in man and to have a similar but different toxicity profile from desferrioxamine in both animals and man. The low cost and oral activity of deferiprone will make it the drug of choice for the vast majority of patients, who are not currently being chelated either because they cannot afford the high cost of desferrioxamine therapy or are not complying or have toxic side effects with its s.c. administration.

Transfusional iron overload and chelation therapy with deferoxamine and deferiprone (L1).

Iron is essential for all living organisms. Under normal conditions there is no regulatory and rapid iron excretion in humans and body iron levels are mainly regulated from the absorption of iron from the gut. Regular blood transfusions in thalassaemia and other chronic refractory anaemias can result in excessive iron deposition in tissues and organs. This excess iron is toxic, resulting in tissue and organ damage and unless it is removed it can be fatal to those chronically transfused. Iron removal in transfusional iron overload is achieved using chelation therapy with the chelating drugs deferoxamine (DF) and deferiprone (L1). Effective chelation therapy in chronically transfused patients can only be achieved if iron chelators can remove sufficient amounts of iron, equivalent to those accumulated in the body from transfusions, maintaining body iron load at a non-toxic level. In order to maintain a negative iron balance, both chelating drugs have to be administered almost daily and at high doses. This form of administration also requires that a chelator has low toxicity, good compliance and low cost. DF has been a life-saving drug for thousands of patients in the last 40 years. It is mostly administered by subcutaneous infusion (40-60 mg/kg, 8-12 h, 5 days per week), is effective in iron removal and has low toxicity. However, less than 10% of the patients requiring iron chelation therapy worldwide are able to receive DF because of its high cost, low compliance and in some cases toxicity. In the last 10 years we have witnessed the emergence of oral chelation therapy, which could potentially change the prognosis of all transfusional iron-loaded patients. The only clinically available oral iron chelator is L1, which has so far been taken by over 6000 patients worldwide, in some cases daily for over 10 years, with very promising results. L1 was able to bring patients to a negative iron balance at doses of 50-120 mg/kg/day. It increases urinary iron excretion, decreases serum ferritin levels and reduces liver iron in the majority of chronically transfused iron-loaded patients. Despite earlier concerns of possible increased risk of toxicity, all the toxic side effects of L1 are currently considered reversible, controllable and manageable. These include agranulocytosis (0.6%), musculoskeletal and joint pains (15%), gastrointestinal complaints (6%) and zinc deficiency (1%). The incidence of these toxic side effects could in general be reduced by using lower doses of L1 or combination therapy with DF. Combination therapy could also benefit patients experiencing toxicity with DF and those not responding to either chelator alone. The overall efficacy and toxicity of L1 is comparable to that of DF in both animals and humans. Despite the steady progress in iron chelation therapy with DF and L1, further investigations are required for optimising their use in patients by selecting improved dose protocols, by minimising their toxicity and by identifying new applications in other diseases of iron imbalance.

Advances in Iron Overload Therapies. Prospects for Effective Use of Deferiprone (L1), Deferoxamine, the New Experimental Chelators ICL670, GT56-252, L1NAll and their Combinations

Effective new therapies and mechanisms have been developed for the targeting and prevention of iron overload and toxicity in thalassaemia and idiopathic haemochromatosis patients. A new era in the development of chelating drugs began with the introduction of deferiprone or L1, which as a monotherapy or in combination with deferoxamine can be used universally for effective chelation treatments, rapid iron removal, maintenance of low iron stores and prevention of heart and other organ damage caused by iron overload. Several experimental iron chelators such as deferasirox (4-[3,5-bis (2-hydroxyphenyl)-1,2,4-triazol-1-yl]-benzoic acid) or ICL670, deferitrin (4,5-dihydro-2- (2,4-dihydroxyphenyl)-4-methylthiazole-4 (S)-carboxylic acid) or GT56-252, 1-allyl-2-methyl-3-hydroxypyrid-4-one or L1NAll and starch deferoxamine polymers have reached different stages of clinical development. The lipophilic ICL670, which can only be administered once daily is generally ineffective in causing negative iron balance but is effective in reducing liver iron. It is suspected that it may increase iron absorption and the redistribution of iron from the liver to the heart and other organs. The experimental iron chelators do not appear to have significant advantages in efficacy and toxicity by comparison to deferiprone, deferoxamine or their combination. However, the prospect of combination therapies using deferiprone, deferoxamine and new chelators will provide new mechanisms of chelator interactions, which may lead to higher efficacy and lower toxicity by comparison to monotherapies. A major disadvantage of the experimental chelators is that even if they are approved for clinical use, they are unlikely to be as inexpensive as deferiprone and become available to the vast majority of thalassaemia patients, who live in developing countries.

The Design and Development of Deferiprone (L1) and Other Iron Chelators for Clinical Use: Targeting Methods and Application Prospects

Iron is essential for all human cells as well as neoplastic cells and invading microbes. Natural and synthetic iron chelators could affect biological processes involving iron and other metal ions in health and disease states. Iron overload is the most common metal toxicity condition worldwide. There are currently two iron chelating drugs, which are mostly used for the treatment of thalassaemia and other conditions of transfusional iron overload. Deferoxamine was until recently the only approved iron chelating drug, which is effective but very expensive and administered parenterally resulting in low compliance. Deferiprone (L1 or 1,2-dimethyl-3-hydroxypyrid-4-one) is the worlds first and only orally active iron chelating drug, which is effective and inexpensive to synthesise thus increasing the prospects of making it available to most thalassaemia patients in third world countries who are not currently receiving any form of chelation therapy. Deferiprone has equivalent iron removal efficacy and comparable toxicity to deferoxamine. There are at least four other known iron chelators, which are currently being developed. Even if successful, these are not expected to become available for clinical use in the next five years and to be as inexpensive as deferiprone. The variation in the chemical, biological, pharmacological, toxicological and other properties of the chelating drugs and experimental chelators provide evidence of the difference in the mode of action of chelators and the need to identify and select molecular structures and substituents based on structure/activity correlations for specific pharmacological activity. Such information may increase the prospects of designing new chelating drugs, which could be targeted and act on different tissues, organs, proteins and iron pools that play important role not only in the treatment of iron overload but also in other diseases of iron and other metal imbalace and toxicity including free radical damage. Chelating drugs could also be designed, which could modify the enzymatic activity of iron and other metal containing enzymes, some of which play a key role in many diseases such as cancer, inflammation and atherosclerosis. Other applications of iron chelating drugs could involve the detoxification of toxic metals with similar metabolic pathways to iron such as Al, Cu, Ga, In, U and Pu.

Serum non‐transferrin‐bound iron in beta‐thalassaemia major patients treated with desferrioxamine and L1

Summary. Non‐transferrin‐bound iron (NTBI) in plasma is toxic due to its ability to participate in free radical formation with resultant peroxidation and damage to cell membranes and other biomolecules. NTBI concentration was determined in serum in 12 normal volunteers and in 52 patients with β‐thalassaemia major by a modification of the method described by Singh et al (1990). There was no detectable NTBI in normal individuals. In the patients NTBI values ranged from −1.5 to 9.0 μmol/l (mean ± SD: 3.6 ± 2.3). The patients’serum ferritin concentrations ranged from 207 to 11400 μg/l (2674±2538), total serum iron from 20 to 61 μmol/l (39.5 ± 9.6) and transferrin saturation from 44 to 110% (84.5 ± 13.8). The NTBI correlated significantly with serum ferritin (r=0.467, P < 0.001), total serum iron (r=0.608, P<0.001) and transferrin saturation (r=0.481, P<0.005). When patients were grouped according to their compliance with desferrioxamine (DFX) therapy, the good compliers had significantly lower NTBI concentrations compared to the poor compliers (poor: 5.4±1.8 μmol/l v good: 2.7±1.7 μmol/l, P<0.001). There was also a significant difference between the level of NTBI and whether or not the patients had complications of iron overload (5.2±1.7 μmol/l v 2.9±1.6 μmol/l, P <0.001). During this study 10 patients were entered into a trial of the oral iron chelator 1,2‐dimethy 1–3‐hydroxypyrid‐4‐one (L1). Their NTBI values were observed during the first 6 months of the trial and showed a significant fall (paired t‐test: P= 0.007). These results suggest that the level of NTBI may prove helpful in assessing the efficiency of chelation in patients with transfusion dependent anaemia and help to predict organ damage.