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.
Deferiprone is the only orally active iron-chelating drug to be used therapeutically in conditions of transfusional iron overload. It is an orphan drug designed and developed primarily by academic initiatives for the treatment of iron overload in thalassaemia, which is endemic in the Mediterranean, Middle East and South East Asia and is considered an orphan disease in the European Union and North America. Deferiprone has been used in several other iron or other metal imbalance conditions and has prospects of wider clinical applications. Deferiprone has high affinity for iron and interacts with almost all the iron pools at the molecular, cellular, tissue and organ levels. Doses of 50-120 mg/kg/day appear to be effective in bringing patients to negative iron balance. It increases urinary iron excretion, which mainly depends on the iron load of patients and the dose of the drug. It decreases serum ferritin levels and reduces the liver and heart iron content in the majority of chronically transfused iron loaded patients at doses >80 mg/kg/day. It is metabolised to a glucuronide conjugate and cleared through the urine in the metabolised and a non-metabolised form, usually of a 3 deferiprone: 1 iron complex, which gives the characteristic red colour urine. Peak serum levels of deferiprone are observed within 1 hour of its oral administration and clearance from blood is within 6 hours. There is variation among patients in iron excretion, the metabolism and pharmacokinetics of deferiprone. Deferiprone has been used in more than 7500 patients aged from 2-85 years in >50 countries, in some cases daily for >14 years. All the adverse effects of deferiprone are considered reversible, controllable and manageable. These include agranulocytosis with frequency of about 0.6%, neutropenia 6%, musculoskeletal and joint pains 15%, gastrointestinal complains 6% and zinc deficiency 1%. Discontinuation of the drug is recommended for patients developing agranulocytosis. Deferiprone is of similar therapeutic index to subcutaneous deferoxamine but is more effective in iron removal from the heart, which is the target organ of iron toxicity and mortality in iron-loaded thalassaemia patients. Deferiprone is much less expensive to produce than deferoxamine. Combination therapy of deferoxamine and deferiprone has been used in patients not complying with subcutaneous deferoxamine or experiencing toxicity or not excreting sufficient amounts of iron with use of either drug alone. New oral iron-chelating drugs are being developed, but even if successful these are likely to be more expensive than deferiprone and are not likely to become available in the next 5-8 years. About 25% of treated thalassaemia patients in Europe and more than 50% in India are using deferiprone. For most thalassaemia patients worldwide who are not at present receiving any form of chelation therapy the choice is between deferiprone and fatal iron toxicity.
Iron chelating drugs are primarily and widely used in the treatment of transfusional iron overload in thalassaemia and similar conditions. Recent in vivo and clinical studies have also shown that chelators, and in particular deferiprone, can be used effectively in many conditions involving free radical damage and pathology including neurodegenerative, renal, hepatic, cardiac conditions and cancer. Many classes of phytochelators (Greek: phyto (φυτó)-plant, chele (χηλή)-claw of the crab) with differing chelating properties, including plant polyphenols resembling chelating drugs, can be developed for clinical use. The phytochelators mimosine and tropolone have been identified to be orally active and effective in animal models for the treatment of iron overload and maltol for the treatment of iron deficiency anaemia. Many critical parameters are required for the development of phytochelators for clinical use including the characterization of the therapeutic targets, ADMET, identification of the therapeutic index and risk/benefit assessment by comparison to existing therapies. Phytochelators can be developed and used as main, alternative or adjuvant therapies including combination therapies with synthetic chelators for synergistic and or complimentary therapeutic effects. The development of phytochelators is a challenging area for the introduction of new pharmaceuticals which can be used in many diseases and also in ageing. The commercial and other considerations for such development have great advantages in comparison to synthetic drugs and could also benefit millions of patients in developing countries.
The maintenance of iron and other essential metal ion balance in humans is based on the presence of homeostatic mechanisms of regulatory absorption, storage, re-utilisation and excretion. There are a number of factors and mechanisms that can affect the level of iron excretion or absorption and overall body iron stores. Net iron loss due to increased iron excretion by comparison to dietary iron absorption is considered as one of the causes of iron deficiency anaemia. Body iron loss greater than normal has been shown in many other conditions. These include the increase in urinary iron excretion observed in iron loaded patients, the substantial reduction in serum ferritin and liver iron of ex-thalassaemia patients several years following bone marrow transplantation and the increase in iron excretion in normal individuals following long term sport activities. There are differences in the metabolism, mode of action, interactions with the iron pools and routes of iron excretion, of the iron chelating drugs deferiprone (L1), deferoxamine and other experimental chelators such as ICL670 in iron-loaded patients. Naturally occurring chelators and some synthetic drugs are known to bind iron and affect iron absorption and excretion. The molecular characteristics of naturally occurring or synthetic chelators can influence other aspects of iron metabolism in addition to iron absorption or excretion. Similar mechanisms and factors can affect the metabolism of other essential metals. The understanding of the mechanisms involved in iron excretion and their overall effects on body iron levels can facilitate the design of new chelators and improved therapeutic protocols for the treatment of conditions of iron and other metal metabolic imbalance and toxicity.
Transfusional iron overload in patients with thalassaemia could be reduced to normal body iron range levels using effective deferiprone/deferoxamine combinations. These levels could be maintained using deferiprone monotherapy.
Author contributions: Kolnagou A reviewed the organisational health structure of thalassaemia and Friedreich ataxia in Cyprus; Kontoghiorghe CN contributed the literature background on recent developments on thalassaemia and Friedreich ataxia and critically reviewed the clinical and other aspects of the manuscript; Kontoghiorghes GJ designed, wrote and edited the manuscript including the mechanisms of iron chelation therapy and iron metabolism and toxicity. AbstractThalassaemia major (TM) and Friedreich's ataxia (FA) are autosomal recessive inherited diseases related to the proteins haemoglobin and frataxin respectively. In both diseases abnormalities in iron metabolism is the main cause of iron toxicity leading to increased morbidity and mortality. Major efforts are directed towards the prevention of these diseases and also in their treatment using iron chelation therapy. Both TM and FA are endemic in Cyprus, where the frequency per total population of asymptomatic heterozygote carriers and patients is the highest worldwide. Cyprus has been a pioneering nation in preventing and nearly eliminating the birth of TM and FA patients by introducing an organized health structure, including prenatal and antenatal diagnosis. Effective iron chelation therapy, improved diagnostic methods and transfusion techniques as well as supportive therapy from other clinical specializations have improved the survival and quality of life of TM patients.Despite the tiresome clinical management regimes many TM patients are successful in their professional lives, have families with children and some are now living well into their fifties. The introduction of deferiprone led to the elimination of cardiac failure induced by iron overload toxicity, which was the major cause of mortality in TM. Effective combinations of deferiprone with deferoxamine in TM patients caused the fall of body iron to normal physiological ranges. In FA different mechanisms of iron metabolism and toxicity apply to that of TM, which can be targeted with specific iron chelation protocols. Preliminary findings from the introduction of deferiprone in FA patients have increased the hopes for improved and effective therapy in this untreatable condition. New and personalised treatments are proposed in TM and FA. Overall, advances in treatments and in particular of chelation therapy using deferiprone are transforming TM and FA from fatal to chronic conditions. The paradigm of Cyprus in the prevention and treatment of TM can be used for application worldwide.© 2014 Baishideng Publishing Group Inc. All rights reserved.Key words: Thalassaemia; Friedreich ataxia; Prenatal diagnosis; Survival; Chelation therapy; Deferiprone; Deferoxamine; Cyprus Core tip: Thalassaemia major (TM) and Friedreich's ataxia (FA) are inherited diseases related to iron toxicity, with high morbidity and mortality rates. Cyprus has the highest frequency of TM and FA worldwide. Prenatal diagnosis and other health policies almost abolished the birth of TM and FA patients in Cyprus. Deferiprone has increa...
Iron overload is known to exacerbate many infectious diseases. Infectious complications are considered to be the second main cause of morbidity and mortality in iron loaded thalassemia patients. Effective chelation therapy leading to the normalization of the iron stores could reduce the incidence of related infections. Microbial pathogens could obtain growth-essential iron from healthy hosts. Conversely, iron withholding and/or removal is an important defense strategy for mammalian hosts, which is primarily accomplished by the iron chelating proteins transferrin and lactoferrin. Chelating drugs could prevent microbial growth and play an essential role in antimicrobial therapeutic strategies. Specific mechanisms and interactions apply in the transfer or withholding of iron between the chelating drugs deferoxamine (DFO), deferiprone (L1) and deferasirox (DFRA) with microbial pathogens such as bacteria, fungi and protozoa. In some cases, chelators and in particular DFO, could act as a siderophore for the microbe and exacerbate infections such as yersiniasis and mucormycosis. Deferiprone appears to have the highest therapeutic index for long-term antimicrobial activity and the highest tissue penetration, including access to the brain. Selection of specific chelation therapy protocols could be considered in conditions where other antimicrobial therapies have failed or where resistance has developed to existing therapies.
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