Desferrioxamine Therapy Research Articles

Effect of Iron Chelator on Liver Function in Beta Thalassemia Major Patients

Background: Due to Regular blood transfusions and Desferrioxamine therapy, beta-thalassemic patients can live for over 30 years. It is becoming increasingly common for liver diseases to cause mortality and morbidity in these patients. Chelation compliance has improved with the recent addition of the oral single-dose therapy Deferasirox (DFX). This study will investigate the impact of iron therapy on liver function tests in BMT patients. Methodology: The patients enrolled in the study were HBV negative and treated with DFO and DFX after BTM. The LFTs include alanine transferase, Albumin, serum bilirubin and aspartate transferase. Sixty patients with Beta-thalassemia were followed every six months for serum ferritin concentrations. Results: Therapy with Desferrioxamine significantly decrease serum ferritin levels inbeta-thalassemia patients and isconcerned with high reduction in serumalanine transaminase and serum aspartate transaminase. Albumin concentrations remain the same in DFX treatment. Association between serum ferritin levels ALT and AST levels were found. There is a negative correlation between serum ferritin concentration and ALT. Conclusion: Patients with Hepatitis negative having thalassemia with iron overload may have some liver function impairment. As a result of DFX treatment, AST, ALP and ALT levels were significantly reduced.

Comparison of Visual Evoked Potential in Thalassemia Patients Receiving Iron Chelation Therapy

Patients of thalassemia require iron chelation therapy for the treatment of iron overload in the form of desferrioxamine (DFO), combination of DFO and deferiprone and oral deferiprone only. One of the side effects of DFO is ocular toxicity. Present study was conducted to elicit the subclinical effects of DFO on visual pathways by doing Visual Evoked Potential (VEP). Forty five patients of thalassemia major were divided into three groups (I, II &III) based on their iron chelation therapy as desferrioxamine, combination of desferrioxamine& deferiprone and only deferiprone respectively. VEP was recorded in each group and comparison was done. In VEP P100 was significantly prolonged in the group of thalassemia patients receiving DFO and combination of DFO and deferiprone suggesting vulnerability to ocular toxicity of DFO. We can suggest that in patients receiving chronic DFO therapy, VEPs may be considered to monitor the toxic effects of DFO on visual system. Keywords: Thalassemia, iron chelation, visual evoked potential.

Assessment of serum ferritin levels in transfusion dependent thalassemic children on oral deferiprone in a tertiary care centre

Background: Thalassemic patients require regular blood transfusions to maintain haemoglobin level around between 10gm/dl-15gm/dl, which would result in transfusional iron overload. The treatment of iron overload is carried out by using parenteral desferrioxamine (DFX) therapy or recently introduced oral Deferiprone (DFP,L1,Ferriprox,KELFER,CP20) an oral iron chelator, Oral deferiprone, DFP (3-hydroxy-1,2-dimethylpyridin-4-one) is a synthetic analogue of mimosine, an iron chelator isolated from the legume Mimosa paduca. Our study was undertaken to asses ferritin concentration in transfusion dependent thalassemic children on Deferiprone, attending thalassemia clinic in Anil Neerukonda hospital, Sanghivalasa, Visakhapatnam.Methods: The present study was a hospital based prospective study, 50 transfusion dependent thalassemic children on Deferiprone, attending thalassemia clinic in Anil Neerukonda hospital, Sanghivalasa, Visakhapatnam attached to NRI Medical College, Visakhapatnam were enrolled during the study period October 2017 and September 2018.Results: In our study authors found an increase in Serum ferritin concentration from 3067.99±1520.13 to 4281.10 ±1760.42 ng/ml at the end of 12 months, which was quite significant.Conclusion: Authors concluded that oral Deferiprone is not an effective iron chelation agent and is associated with complications like GI symptoms, joint pains in significant number of children. So, search for an alternative iron chelator or combined chelation therapies which are safe and cost effective should be continued.

B0 Vs. Non-B0 Genotype: Differences in Non-Transfusion-Dependent Thalassemia Patients

Background: In non transfusion dependent thalassemia (NTDT) the lack of a clear genotype-phenotype relationship complicates the already complex and extensive scenario in clinical practice. Our aim was to detect if the presence of a β°/β° homozygous genotype is associated to increased iron overload and rate of complications.Methods: We considered 81 patients with thalassemia intermedia never transfused o who received occasional transfusions (37.7±11.4 years, 39 females) enrolled in the Myocardial Iron Overload in Thalassemia (MIOT) project. Magnetic Resonance Imaging (MRI) was used to quantify iron overload (T2* technique), biventricular morphological and functional parameters (cine sequences), and the presence of myocardial fibrosis (late gadolinium enhancement-LGE technique). All complications were classified according to international guidelines.Results: Two groups of patients were identified: non homozygous β°/ β° genotype (N=61) and homozygous β°/ β° genotype (N=20.) No significant differences for sex and age were found between the groups.The frequency of non chelated patients was significantly lower in the homozygous β°/β° group (17.6% vs 49.1%; P=0.026) and the frequency of desferrioxamine therapy was 70.6 in the homozygous β°/β° group and 43.4 in the non homozygous β°/β° group (P=0.051).Patients with homozygous β°/β° genotype had lower mean haemoglobin levels (8.6±1.1g/dl vs 9.2±1.2 g/dl) but the difference did not reach the statistical significance (P=0.060).Serum ferritin levels, liver transaminases and MRI liver iron concentarion (LIC) values were comparable between the groups.No patient showed cardiac iron and global heart T2* values were comparable between the two groups.Left atrial area index, left ventricular (LV) end-diastolic, end-systolic and stroke volume indexes, LV mass index, right ventricular end-diastolic and end-systolic volume indexes were significantly higher in the homozygous β°/β° group (see Table).Frequencies of heart failure and arrhythmias were comparable between the groups.No patient showed diabetes or hypoparathyroidism and there was no difference between groups in terms of frequency of hypogonadism or hypothyroidism. Conversely, patients with homozygous β°/β° genotype had a significant higher frequency of osteoporosis (50.0% vs 16.7%; P=0.003). Among patients with osteoporosis, 75% were treated with DFO therapy.Conclusions: Heart remodelling related to a high cardiac output state cardiomyopathy was more pronounced in patients with homozygous β°/β° genotype. Osteoporososis was significantly more frequent in patients with homozygous β°/β° genotype, treated for more than two-thirds with DFO therapy. These data support the knowledge of different phenotypic groups in the management of NTDT patients. [Display omitted] DisclosuresPepe:Chiesi Farmaceutici S.p.A., ApoPharma Inc., and Bayer: Other: No profit support.

The effect of desferrioxamine chelation versus no therapy in patients with non transfusion-dependent thalassaemia: a multicenter prospective comparison from the MIOT network.

We prospectively assessed by magnetic resonance imaging (MRI) the advantages of desferrioxamine (DFO) with respect to the absence of chelation therapy in non transfusion-dependent thalassaemia (NTDT) patients. We considered 18 patients non-chelated and 33 patients who received DFO alone between the two MRI scans. Iron overload was assessed by the T2* technique. Biventricular function parameters were quantified by cine sequences. No patient treated with DFO had cardiac iron. At baseline, only one non-chelated patient showed a pathological heart T2* value (< 20ms) and he recovered at the follow-up. The percentage of patients who maintained a normal heart T2* value was 100% in both groups. A significant increase in the right ventricular ejection fraction was detected in DFO patients (3.48 ± 7.22%; P = 0.024). The changes in cardiac T2* values and in the biventricular function were comparable between the two groups. In patients with hepatic iron at baseline (MRI liver iron concentration (LIC) ≥ 3mg/g/dw), the reduction in MRI LIC values was significant only in the DFO group (- 2.20 ± 4.84mg/g/dw; P = 0.050). The decrease in MRI LIC was comparable between the groups. In conclusion, in NTDT patients, DFO therapy showed no advantage in terms of cardiac iron but its administration allowed an improvement in right ventricular function. Moreover, DFO reduced hepatic iron in patients with significant iron burden at baseline.

Neurophysiologic Evaluation of Children with Beta-Thalassemia Major

Neural pathway involvement is considered to be a neurological complication in Beta-thalassemia major (BTM). This study aimed to detect possible involvement of central and peripheral neural pathways in a group of neurologically asymptomatic patients with BTM. It was performed on 30 patients diagnosed as having BTM (group I), and 10 healthy children who were matched for age, sex, and height (group II). Serum ferritin, iron, glucose tolerance test, intelligence quotient (IQ) test, and electroencephalogram (EEG) were assessed in BTM patients. Electrophysiologic study was assessed in both groups. The mean age of the patients was 10.45 ± 2.88 years. They were 14 males and 16 females. The results of the present study showed that 66.7% of patients had subclinical sensory peripheral neuropathy. Twenty percent of the patients had abnormal somatosensory evoked potentials. Low average and slow learner total IQ score were found in 63.3% of the studied patients. These findings did not correlate with age, disease duration, serum iron, and ferritin. Twenty-three patients had mature EEG background activity, while seven patients had immature background activity. The EEG background maturity had significant correlation with age, duration of desferrioxamine therapy, and serum iron. There was no correlation between serum ferritin level, EEG, and electrophysiologic findings. Regular electrophysiologic monitoring and intellectual evaluation are recommended to detect relevant abnormalities and apply appropriate management.

A prospective MRI study of left ventricular iron and function in non-trasfusion-dependent thalassemia intermedia patients treated with desferrioxamine

Background In thalassemia intermedia (TI) patients no observational study prospectively evaluated in the real life the efficacy of the desferrioxamine (DFO) therapy in removing or preventing myocardial iron overload. The efficacy endpoint of this study is represented by the changes in cardiac T2* values and left ventricular (LV) function parameters in non-transfusion dependent (NTD) TI patients after 18 months of desferrioxamine therapy.

A T2* MRI Prospective Survey on Cardiac and Hepatic Iron in Non-Trasfusion-Dependent Thalassemia Intermedia Patients Treated with Desferrioxamine

Background. In thalassemia intermedia (TI) patients no observational study prospectively evaluated in the real life the efficacy of the desferrioxamine (DFO) therapy in removing or preventing iron overload from the heart and the liver by T2* Magnetic Resonance Imaging (MRI). The efficacy endpoint of this study is represented by the changes in cardiac T2* and MRI LIC (liver iron concentration) values in non-transfusion dependent (NTD) TI patients after 18 months of desferrioxamine therapy.Methods. Among the 325 TI patients enrolled in the MIOT (Myocardial Iron Overload in Thalassemia) network, we selected 129 TI patients NTD. We considered 29 patients who had been received DFO alone between the two MRI scans. Cardiac iron overload was assessed by the T2* multiecho technique. Hepatic T2* values were converted into liver iron concentration (LIC) values.Results. Mean age was 39.69 ± 8.12 years and 14 (48.3%) patients were females. Patients started regular chelation therapy at a mean age of 21.92 ± 15.89 years. The mean administered dosage of DFO via subcutaneous route was 38.46 ± 10.27 mg/kg body weight on 3.32 ± 1.54 days/week. The percentage of patients with excellent/good levels of compliance to the chelation treatment was 82.1%.At baseline only one patient showed cardiac iron overload (global heart T2*=15.23 ms) but he recovered at the FU (global heart T2*=26.93 ms). All patients without cardiac iron maintained the same status at the follow-up (FU).Eighteen patients (62.1%) had hepatic iron overload (MRI LIC ≥3 mg/g/dw) at the baseline.For this subgroup, the baseline and the FU LIC values were, respectively, 9.15 ± 7.97 mg/g/dw and 7.41 ± 6.28 mg/g/dw. The reduction in MRI LIC values was not significant (P=0.102). Out of the 11 patients with a baseline MRI LIC <3 mg/g/dw, only one (9.1%) showed hepatic iron at the FU. The Figure shows the evolution of different hepatic iron overload risk classes between the baseline and the FU.Conclusions. In this small population of sporadically or non transfused TI patients, DFO showed 100% efficacy in maintaining a normal global heart T2* value. As regards as the hepatic iron overload, the DFO therapy did not prevent the transition to a worst class in 2 patients. [Display omitted] DisclosuresPepe:Chiesi: Speakers Bureau; ApoPharma Inc.: Speakers Bureau; Novartis: Speakers Bureau.

Correction of Severe Anemia in a Patient with End Stage Renal Disease and Myelodysplastic Syndrome

Background: Anemia is a common complication of end-stage renal disease (ESRD) and is effectively managed by Erythropoietin Stimulating Agents (ESAs) and intravenous iron therapy. Management of anemia in ESRD patients with myelodysplastic syndrome (MDS) poses a unique challenge. ESAs even at extremely high doses do not result in a desired response, especially if the patients are iron-overloaded. Case: A 72-year-old man with history of ESRD and MDS on hemodialysis since September 2009 was severely anemic requiring massive doses of ESA in excess of 90,000 units/week. Iron saturation was consistently >60%; ferritin was >2500. Desferrioxamine (DFO) 125 mg IV/week was begun in November 2010. His PRBC transfusion and ESA requirements declined after the initiation of this therapy. He had 33 ER visits for PRBC transfusions (1 - 3 transfusions/visit) from September 2009 to November 2010 (average: 2.35/month), which decreased to 18 visits in 20 months (average: 0.9/month) after getting DFO. Conclusion: We report a case of MDS with ESRD on hemodialysis where anemia was managed with Desferrioxamine therapy along with ESA, after which it was noted that there was a significant reduction in the number of PRBC transfusions that the patient received along with a decrease in ESA requirements and a decrease in number of hospitalizations, which in the long term could be cost effective.

Oral deferiprone for iron chelation in people with thalassaemia

Thalassaemia major is a genetic disease characterised by a reduced ability to produce haemoglobin. Management of the resulting anaemia is through red blood cell transfusions.Repeated transfusions result in an excessive accumulation of iron in the body (iron overload), removal of which is achieved through iron chelation therapy. A commonly used iron chelator, deferiprone, has been found to be pharmacologically efficacious. However, important questions exist about the efficacy and safety of deferiprone compared to another iron chelator, desferrioxamine. To summarise data from trials on the clinical efficacy and safety of deferiprone and to compare the clinical efficacy and safety of deferiprone with desferrioxamine for thalassaemia. We searched the Cochrane Cystic fibrosis and Genetic Disorders Group's Haemoglobinopathies trials Register and MEDLINE, EMBASE, CENTRAL (The Cochrane Library), LILACS and other international medical databases, plus registers of ongoing trials and the Transfusion Evidence Library (www.transfusionevidencelibrary.com). We also contacted the manufacturers of deferiprone and desferrioxamine.All searches were updated to 05 March 2013. Randomised controlled trials comparing deferiprone with another iron chelator; or comparing two schedules or doses of deferiprone, in people with transfusion-dependent thalassaemia. Two authors independently assessed trials for risk of bias and extracted data. Missing data were requested from the original investigators. A total of 17 trials involving 1061 participants (range 13 to 213 participants per trial) were included. Of these, 16 trials compared either deferiprone alone with desferrioxamine alone, or a combined therapy of deferiprone and desferrioxamine with either deferiprone alone or desferrioxamine alone; one compared different schedules of deferiprone. There was little consistency between outcomes and limited information to fully assess the risk of bias of most of the included trials.Four trials reported mortality; each reported the death of one individual receiving deferiprone with or without desferrioxamine. One trial reported five further deaths in patients who withdrew from randomised treatment (deferiprone with or without desferrioxamine) and switched to desferrioxamine alone. Seven trials reported cardiac function or liver fibrosis as measures of end organ damage.Earlier trials measuring the cardiac iron load indirectly by magnetic resonance imaging (MRI) T2* signal had suggested deferiprone may reduce cardiac iron more quickly than desferrioxamine. However, a meta-analysis of two trials suggested that left ventricular ejection fraction was significantly reduced in patients who received desferrioxamine alone compared with combination therapy. One trial, which planned five years of follow up, was stopped early due to the beneficial effects of combined treatment compared with deferiprone alone in terms of serum ferritin levels reduction.The results of this and three other trials suggest an advantage of combined therapy over monotherapy to reduce iron stores as measured by serum ferritin. There is, however, no conclusive or consistent evidence for the improved efficacy of combined deferiprone and desferrioxamine therapy over monotherapy from direct or indirect measures of liver iron. Both deferiprone and desferrioxamine produce a significant reduction in iron stores in transfusion-dependent, iron-overloaded people. There is no evidence from randomised controlled trials to suggest that either has a greater reduction of clinically significant end organ damage.Evidence of adverse events were observed in all treatment groups. Occurrence of any adverse event was significantly more likely with deferiprone than desferrioxamine in one trial, RR 2.24 (95% CI 1.19 to 4.23). Meta-analysis of a further two trials showed a significant increased risk of adverse events associated with combined deferiprone and desferrioxamine compared with desferrioxamine alone, RR 3.04 (95% CI 1.18 to 7.83). The most commonly reported adverse event was joint pain, which occurred significantly more frequently in patients receiving deferiprone than desferrioxamine, RR 2.64 (95% CI 1.21 to 5.77). Other common adverse events included gastrointestinal disturbances as well as neutropenia or leucopenia, or both. In the absence of data from randomised controlled trials, there is no evidence to suggest the need for a change in current treatment recommendations; namely that deferiprone is indicated for treating iron overload in people with thalassaemia major when desferrioxamine is contraindicated or inadequate. Intensified desferrioxamine treatment (by either subcutaneous or intravenous route) or use of other oral iron chelators, or both, remains the established treatment to reverse cardiac dysfunction due to iron overload. Indeed, the US Food and Drug Administration (FDA) recently only gave support for deferiprone to be used as a last resort for treating iron overload in thalassaemia, myelodysplasia and sickle cell disease. However, there is evidence that adverse events are increased in patients treated with deferiprone compared with desferrioxamine and in patients treated with combined deferiprone and desferrioxamine compared with desferrioxamine alone. There is an urgent need for adequately-powered, high-quality trials comparing the overall clinical efficacy and long-term outcome of deferiprone with desferrioxamine.

Observational study comparing long‐term safety and efficacy of Deferasirox with Desferrioxamine therapy in chelation‐naïve children with transfusional iron overload

An observational study was conducted to explore postmarketing safety and efficacy of Deferasirox (DFX) in comparison with conventional Desferrioxamine (DFO) in chelation-naïve children with transfusional iron overload. Transfusion-dependent children (aged ≤ 5 yr) who had serum ferritin above 1000 μg/L and had been prescribed either first-line DFX or DFO for at least 12 months to maintain serum ferritin between 500 and 1000 μg/L were included. Initial DFX dose was 20 mg/kg/d for 7 d a week, and DFO dose was 25-35 mg/kg/d subcutaneously, given for 5 d a week. Dose adjustments were based on serum ferritin changes and safety markers. The primary efficacy endpoint was change in serum ferritin from baseline. The effect of transfusional iron loading rate (ILR) and different doses of chelators on serum ferritin was also assessed. A total of 111 patients were observed for a median of 2.29 yr on DFX (n = 71) and 2.75 yr on DFO (n = 40). Absolute change in serum ferritin from baseline to the last available observation was not significant with DFX (91 μg/L, P = 0.5) but significantly higher with DFO (385 μg/L, P < 0.005). ILR and DFX doses had a major impact on serum ferritin changes in DFX cohort. The height- and weight-standard deviation scores did not differ significantly in both cohorts during the study. Fluctuations in liver enzymes and non-progressive increase in serum creatinine were the most common adverse events (DFX; 9.8%, 18.0% and DFO; 5.0%, 7.5%, respectively). DFX is well tolerable and at least as effective as DFO to maintain safe serum ferritin levels and normal growth progression in chelation-naïve children.

Serum ferritin levels and endocrinopathy in medically treated patients with β thalassemia major

The association between iron overload indices and pathology of the heart and liver in transfusion-dependent patients with β thalassemia major (TM) has been extensively studied. Nonetheless, data on endocrine disease remains limited. This was a cross-sectional study of 382 TM patients treated with regular transfusions and desferrioxamine at the Thalassemia Center in Dubai, UAE. Retrieved data included demographics, splenectomy status, steady-state serum ferritin levels, and the presence of endocrinopathies (diabetes mellitus, hypothyroidism, hypoparathyroidism, and hypogonadism). Multivariate logistic regression analyses were used to determine which variables were independently associated with the occurrence of each endocrinopathy. The mean age of patients was 15.4 ± 7.6years, with an equal sex distribution. The mean serum ferritin level was 2597.2 ± 1976.8μg/l. The frequencies of specific endocrinopathies were diabetes mellitus (10.5%), hypothyroidism (6.3%), hypoparathyroidism (10.5%), and hypogonadism (25.9%). On multivariate logistic regression analysis, patients with a serum ferritin level >2,500μg/l, but not >1,000-2,500μg/l, were 3.53 times (95% CI 1.09-11.40) more likely to have diabetes mellitus, 3.25 times (95% CI 1.07-10.90) more likely to have hypothyroidism, 3.27 times (95% CI 1.27-8.39) more likely to have hypoparathyroidism, and 2.75 times (95% CI 1.38-5.49) more likely to have hypogonadism compared to patients with a serum ferritin level ≤1,000μg/l. However, splenectomized patients with serum ferritin levels ≤2,500μg/l had comparably high rates of all endocrinopathies as patients with serum ferritin levels >2,500μg/l. Endocrinopathy is common in TM patients treated with desferrioxamine therapy, especially in patients with serum ferritin levels >2,500μg/l or those splenectomized.

Serum ferritin levels, socio-demographic factors and desferrioxamine therapy in multi-transfused thalassemia major patients at a government tertiary care hospital of Karachi, Pakistan

BackgroundBeta thalassemia is the most frequent genetic disorder of haemoglobin synthesis in Pakistan. Recurrent transfusions lead to iron-overload manifested by increased serum Ferritin levels, for which chelation therapy is required.FindingsThe study was conducted in the Pediatric Emergency unit of Civil Hospital Karachi after ethical approval by the Institutional Review Board of Dow University of Health Sciences. Seventy nine cases of beta thalassemia major were included after a written consent. The care takers were interviewed for the socio-demographic variables and the use of Desferrioxamine therapy, after which a blood sample was drawn to assess the serum Ferritin level. SPSS 15.0 was employed for data entry and analysis.Of the seventy-nine patients included in the study, 46 (58.2%) were males while 33 (41.8%) were females. The mean age was 10.8 (± 4.5) years with the dominant age group (46.2%) being 10 to 14 years. In 62 (78.8%) cases, the care taker education was below the tenth grade. The mean serum Ferritin level in our study were 4236.5 ng/ml and showed a directly proportional relationship with age. Desferrioxamine was used by patients in 46 (58.2%) cases with monthly house hold income significant factor to the use of therapy.ConclusionsThe mean serum Ferritin levels are approximately ten times higher than the normal recommended levels for normal individuals, with two-fifths of the patients not receiving iron chelation therapy at all. Use of iron chelation therapy and titrating the dose according to the need can significantly lower the iron load reducing the risk of iron-overload related complications leading to a better quality of life and improving survival in Pakistani beta thalassemia major patients.Conflicts of Interest: None

What should be done to treat dialysis‐associated ascites?

Dialysis-associated ascites (‘‘nephrogenic’’ or ‘‘nephrogenous’’ ascites) is an entity that develops in only a small number of hemodialysis patients. This entity was first described in the 1970s (1,2), and over 150 cases have subsequently appeared in the literature. The characteristics of patients with dialysis-associated ascites are reported in three major series (2,4,5) revealing a wide range of age at presentation (11–71 years of age), male predominance (3,4) but no race predilection. Ascites can appear anywhere from 18 to 69 months after the initiation of dialysis and also occurs in nondialysis requiring kidney disease (3).Most cases developed in patients with underlying primary glomerular diseases and hypertension. The number of cases has decreased since the 1970s, which might be related to better treatment of glomerular diseases, better fluid management in dialysis, more diabetic nephropathy as a primary cause of renal disease, and the universal use of angiotensin-converting enzyme inhibitors (ACEIs). Increased abdominal girth, anorexia, early satiety, and cachexia characterize the clinical presentation (6), while massive ascites with minimal lower extremity edema is found on physical examination. The ascitic fluid is straw colored, with a white blood cell count of usually 25–1600 ⁄mm and a mean serum – ascites gradient (SAAG) of 1.1 g ⁄dl. Cultures are negative. Dialysisassociated ascites is a diagnosis of exclusion and can only be established after portal hypertension or known primary liver or biliary disease, cardiac disease, peritoneal carcinomatosis, pancreatic disease, inferior vena caval obstruction, urinary extravasation, and hypothyroidism are excluded. The postulated pathogenic mechanisms for dialysisassociated ascites include peritoneal membrane changes because of uremic toxins (5), exposure to dialysis solution (1), up-regulation of the renin-angiotensin system (2), the presence of circulating immune complexes in patients with underlying glomerular diseases (2), and iron deposition (4). Elevated hepatic vein hydrostatic pressure (7), fluid retention, increased peritoneal membrane permeability (8), and impaired lymphatic drainage have also been cited as possible contributing factors (2). Although fluid retention occurs in more than 70% of the reported cases, the role of fluid retention is not completely clear as dialysis patients are commonly fluid overloaded yet do not develop ascites. Perhaps, other factors (noted above) serve as a ‘‘second hit’’ in the presence of fluid overload (5). Hypoalbuminemia (5), which was present in 75%of uremic patients with ascites in one series, may contribute to ascites formation (4). While some authors have found an association between duration of HD and ascites development (8), others have not (5). Prior therapy with peritoneal dialysis (PD) may play a role in either altering peritoneal membrane permeability or inducing inflammation. However, the low incidence of prior peritoneal dialysis in patients with dialysis-associated ascitesmakes this unlikely (4). Treatment of patients with refractory dialysis-associated ascites initially requires appropriate fluid management and salt restriction. A recent study (9) on six patients with this condition showed that severe salt restriction and frequent ultrafiltration (UF) andHD significantly improved the ascites. Intensive daily isolated UFmay prove beneficial. DailyHDwas effective in controlling ascites in 78% of the patients in 1–2 weeks (4). However, volume reduction may not be well tolerated especially if simultaneous cardiac dysfunction is present. Intradialytic hypotension and noncompliance with strict salt restriction (large interdialytic fluid gains) contribute to intolerance of aggressive UF. Thus, it is essential that excessive interdialytic weight gain is prevented. Interventions such as hyperalimentation and repeated paracentesis are often undertaken to control ascites (5). Reinfusion of ultrafiltered ascitic fluid and extracorpeal ascites dialysis has improved hemodynamic stability and reduced ascites in some patients (10,11). Unfortunately, CAPD is complicated by decreased serum protein concentration, because of repeated removal of protein-rich ascitic fluid (12). However, resolution of abdominal distention ultimately leads to an improvement in appetite and increased protein intake, which may improve serum albumin levels. Because peritoneal hemosiderosis has been implicated as a cause of this entity, desferrioxamine therapy along with phlebotomy has improved ascites in some cases (4). Intraperitoneal administration of steroids and parathyroidectomy has proved successful in some cases (13,14). Table 1 summarizes medical and surgical therapies attempted in this entity. Surgical placement of peritoneovenous shunts has been reported to be effective in some patients; however, they are critically dependent on shunt longevity (15). This approach should be considered only after medical options have been tried, particularly because it limits future employment of peritoneal dialysis. Another surgical option that has been attempted is bilateral nephrectomy (6). In a series of 10 patients, seven who did not undergo nephrectomy died of cachexia, uncontrolled hypertension, and ascites. In contrast, the three who underwent bilateral nephrectomy gained lean body mass with prompt resolution of ascites. The use of an ACEI was evaluated in one patient with ascites (16). Seminars in Dialysis—Vol 24, No ** (***–***) 2011 pp. ***–*** DOI: 10.1111/j.1525-139X.2011.00893.x a 2011 Wiley Periodicals, Inc.

Self‐reported level of and factors influencing the compliance to desferrioxamine therapy in multitransfused thalassaemias

To analyse the self-reported degree of and factors influencing the compliance to desferrioxamine (DFO) therapy in children with transfusion-dependent thalassaemia major in Malaysia. A cross-sectional study was conducted on all children with thalassaemia major on DFO attending Likas Hospital, Sabah, in September 2008. Patients or carer-providers were interviewed to report on the degree of compliance as either highly (administering >90% of DFO), moderately (51-90%), poorly (1%-50%) or non-compliant (0%) to DFO in the preceding month. The latest serum ferritin levels were noted. The median (range) age at first blood transfusion of these 139 (73 males, median (range) age at interview: 9.0 years (2-16 years)) patients were 1.0 year (2 months to 10 years). The median (range) duration of regular DFO therapy was 2 years (2 months to 10 years). Forty-three (31%) of the patients reported themselves to be highly compliant, 70 (50%) moderately and 26 (19%) poorly or non-compliant. Multivariate analysis showed that a lower family income negatively affected the degree of compliance, while family support positively affected the degree of compliance to DFO. No correlation existed between self-reported degree of compliance and latest serum ferritin level (6444 ± µmol/L; P = 0.186). The self-reported compliance to DFO therapy was moderate in this cohort of patients with thalassaemia major in Malaysia. The serum ferritin level was high, possibly because of the relatively short duration of DFO therapy and compliance. Oral iron chelator should be considered to improve the compliance to iron chelation.

Combined therapy of silymarin and desferrioxamine in patients with β‐thalassemia major: a randomized double‐blind clinical trial

Silymarin, a flavonolignan complex isolated from Silybum marianum, has a strong antioxidant, hepatoprotective, and iron chelating activities. The present study was designed to investigate the therapeutic activity of orally administered silymarin in patients with thalassemia major under conventional iron chelation therapy. A 3-month randomized, double-blind, clinical trial was conducted in 59 beta-thalassemia major patients in two well-matched groups. Patients were randomized to receive a silymarin tablet (140 mg) three times a day plus conventional desferrioxamine therapy. The second group received the same therapy but a placebo tablet instead of silymarin. Clinical laboratory tests were assessed at the beginning and the end of the trial, except for serum ferritin level that was assessed at the middle of the trial as well. Results of this study revealed that the combined therapy was well tolerated and more effective than desferrioxamine in reducing serum ferritin level. Significant improvement in liver alkaline phosphatase and glutathione levels of red blood cells was also observed in silymarin-treated beta-thalassemia patients. However, no significant difference in serum ferritin levels was detected between silymarin and placebo groups after 1.5 and 3 months treatment, probably because of insufficient sample size to detect subtle changes in ferritin levels between groups. This is the first report showing the beneficial effects of silymarin in thalassemia patients and suggests that silymarin in combination with desferrioxamine can be safely and effectively used in the treatment of iron-loaded patients.

Current Status in Iron Chelation in Hemoglobinopathies

Although blood transfusions are important for patients with hemoglobinopathies, chronic transfusions inevitably lead to iron overload as humans cannot actively remove excess iron. The cumulative effects of iron overload lead to significant morbidity and mortality, if untreated. Desferrioxamine (DFO) is the reference-standard iron chelator whose safety and efficacy profile has been established through many years of clinical use. DFO side effects are acceptable and manageable however the prolonged subcutaneous infusion regimen of 5-7 days per week is very demanding and results in poor adherence to therapy. Deferiprone (Ferriprox, L1) is a bidentate molecule, orally administrable three-times/day, licensed in Europe and in other regions but in the USA and Canada, for the treatment of iron overload in patients for whom DFO therapy is contraindicated or inadequate. Preliminary evidences suggest that Deferiprone may be more effective than DFO in chelating cardiac iron. The side effects include gastrointestinal symptoms, liver dysfunction, joint pain, neutropenia and agranulocytosis. A weekly assessment of white blood cell counts is recommended because of the risk of agranulocytosis. Deferasirox is a new, convenient, once-daily oral iron chelator that has demonstrated in various clinical trials good efficacy and acceptable safety profile in adult and pediatric patients affected by transfusion-dependent thalassemia major and by different chronic anemias (SCD, BDA, MDS). The long half-life of Deferasirox (16-18 hours) provides sustained 24 hr iron chelation coverage. The efficacy and safety profile have been evaluated in more than 1000 patients in clinical trials allowing FDA registration. Patient satisfaction with Deferasirox was superior than with DFO therapy.

Assessment of Renal Function in Transfused b-Thalassemia Patients Based on Cystatin C Measurements and Equations.

Cystatin C is a non-glycosylated protein that belongs to the cystatin superfamily of cysteine protease inhibitors. Its low molecular weight (13.3kDa) and positive charge at physiological pH levels facilitates its glomerular filtration and subsequently it is reabsorbed and almost completely catabolized in the proximal renal tubules. Therefore and due to its constant rate of production, its serum concentration is determined by the rate of glomerular filtration (GFR). Cystatin C production in the body is a stable process that is not influenced by renal conditions, increased protein catabolism or dietary factors. Moreover, in contrary to creatinine, it does not change with age or muscle mass. For these reasons, serum cystatin C has been suggested to be an ideal endogenous marker of GFR. Studies on the renal function of patients with transfusion-dependent β-thalassemia are sparse. These studies suggested that the renal abnormalities observed in β-thalassemia are due to proximal tubular dysfunction and postulated that their severity is related with the degree of anemia. They were less severe in patients on hypertransfusion and appropriate desferrioxamine therapy suggesting that the damage might be caused by both anemia and increased oxidation induced by excess iron deposition. None of these studies have demonstrated renal insufficiency as reflected by decreased GFR. This was probably due to the fact that all estimations were based on creatinine measurements. In this study we estimated GFR in 195 transfused patients with β-thalassemia major by measuring cystatin C and calculating GFR according to the recently proposed cystatin C-based prediction equation using only concentration in mg/L and a prepubertal factor:1GFR [mL/min/1.73m2] = 84.7 × cystatin C (mg/L)−1.68 × 1.38* (*if a child <14 years). We found that 136 patients had normal cystatin C levels (0.66–1.03mg/L) and GFR values (80–170mL/min/1.73m2), 36 patients had mild renal insufficiency (cystatin C levels: 1.04–1.22mg/L and GFR values: 60–79mL/min/1.73m2), 21 patients had moderate renal insufficiency (cystatin C levels: 1.23–1.72mg/L and GFR values: 34–59mL/min/1.73m2), while 2 patients had severe renal insufficiency with cystatin C levels >2.5mg/L and GFR values <20mL/min/1.73m2. We further determined plasma levels of Neutrophil gelatinase-associated lipocalin (NGAL) in 30 randomly selected patients. NGAL is a protein expressed on tubular cells of which the production is markedly increased in response to harmful stimuli, such as ischemia or toxicity. We found increased NGAL levels in 19 β-thalassemia patients (mean: 95.0±45.0mg/L compared to normal values of 51.2±11.8mg/L, p<0.0003). NGAL levels correlated significantly with cystatin C levels (r=0.740, p<0.0001), indicating that the renal impairment in these patients seems to be originated from tubular injury. The findings of this study indicate that renal insufficiency is present in a significant proportion of transfusion-dependent β-thalassemia patients. Further studies are warranted in order to identify predisposing factors that contribute to the renal damage in thalassemia and to establish appropriate guidelines for the evaluation and follow up of renal function in these patients. 1. Clin Chem 2005; 51:1420–143.

Marrow proliferation as a cause of hearing loss in beta-thalassaemia major

The aim of this report was to highlight the fact that hearing loss in thalassaemia patients can be related to marrow expansion affecting the ossicles, resulting in a conductive loss. A six-year-old boy with transfusion-dependent beta-thalassaemia developed a unilateral hearing loss shortly after commencing desferrioxamine therapy. Ototoxicity was assumed, but the deficit was later found to be of a conductive nature, due to marrow proliferation within the ossicular chain as a consequence of the disease process--a phenomenon previously unreported in the literature. It is important to elucidate the precise nature of new onset hearing loss in patients receiving iron chelation therapy, in order to avoid unnecessary cessation of much needed medication, on the assumption of ototoxicity.

Iron Studies in Infants Born to an Iron Overloaded Mother With β-Thalassemia Major: Possible Effects of Maternal Desferrioxamine Therapy

A 30-year-old woman with transfusion-dependent, homozygous beta-thalassemia major and transfusional hemosiderosis had 2 successful pregnancies after ovulation induction and in vitro fertilization. Treatment with subcutaneous desferrioxamine (DF) was discontinued before the conception but restarted at 6 months of gestation. Elective cesarean section was performed at 35 weeks of pregnancy because of partial placenta previa. The infant was clinically normal. At the time of delivery, the maternal serum ferritin was 2000 ng/mL, serum iron/iron binding capacity (SI/TIBC) were 274/380 microg/dL, and % saturation 72%. Serum ferritin level in the infant was 42 ng/mL, SI/TIBC were 53/222 microg/dL, and % saturation 23%. During a twin pregnancy 2 years later, DF therapy was totally withheld. Elective cesarian section was performed at 36 weeks of gestation. Both twins were clinically normal. At delivery, the maternal serum ferritin was 1700 ng/mL, SI/TIBC 447/450 microg/dL, and % saturation 99%. Serum ferritins of the twins were 227 and 203 ng/mL, SI/TIBC were 30/182 and 27/203 microg/dL, and % saturations 16% and 13%. Despite elevated iron studies in the mother during both pregnancies, the SI/TIBC of the infants were quite low. In the first pregnancy in which DF was administered in last months of gestation, a low level of serum ferritin was present in the newborn that was even lower at 3 months of age. In the second pregnancy, high normal, levels of ferritin were present in both twin newborns. Despite comparable gestational ages, hemoglobin levels were lower in the first pregnancy than the second. These studies indicate that very high maternal levels of SI/TIBS and serum ferritin were not associated with increased fetal SI/TIBC, which were, in fact, quite low. Because of the different fetal ferritin levels in the 2 pregnancies, it is possible that treatment of the mother with DF in the last weeks of pregnancy may have resulted in depletion of fetal iron stores.