A Scoring System for the Assessment of Quality of Care in the Management of Transfusion Dependent Thalassemia
Abstract
1. Introduction
- Blood transfusions must be adequate in order to correct the anaemia and suppress ineffective erythropoiesis. This is achieved by maintaining pre-transfusion haemoglobin (Hb) at least above 9 mg/dL to promote growth and vitality, as well as survival [1,2,5]. Donated blood must also be compatible with the recipient and safe from viruses and other contaminants, minimising adverse reactions. This requires a transfusion service that relies on voluntary non-remunerated donations and is well-equipped to perform all the necessary tests to prevent adverse reactions and transmission of infections.
- Iron overload is subsequent to increased absorption from food and from breakdown of transfused red cells; excess iron damages vital organs. One measure of iron load is serum ferritin, which should be kept under 1000 ng/mL [6]. The body does not have a mechanism to remove excess iron, and so iron chelation (removal of iron pharmaceutically) must be adequate to prevent iron toxicity to vital organs, while being alert to possible chelator toxicity. Daily treatment is a necessary prerequisite for effectiveness.
- Multidisciplinary collaborations are needed to ensure protection and expert treatment of organ damage. Heart, liver and endocrine toxicity, in which all endocrine glands can be involved, but most commonly those involved in growth and sexual development, lead to hypogonadism, as well as hypothyroidism and diabetes. These complications are inevitable without timely detection and treatment.
- Psychosocial support is offered at all ages, both by the treating team of doctors and nurses, and by professional psychologists and social workers. Social achievements such as education, personal relationships, employment and social integration are all contributors to a satisfactory quality of life, a reason for pursuing survival despite the difficult life routine.
- Expert centres are a requirement for good outcomes, which can offer all the services briefly described above and follow a significant number of patients long-term so that clinical experience is accumulated. Such reference centres form a collaborating network with smaller peripheral centres. This can ensure equity in the management of the disease, reaching patients [9,10].
- The availability of innovative and curative treatments. These include medications which can improve the clinical course, but also those which are expected to render patients transfusion independent. These therapies currently benefit only a small minority of patients because of unaffordability, but also because the process requires specialised infrastructure, making access difficult for most patients [11,12].
- Those who are not treated at all. If they suffer from the severe transfusion-dependent form of thalassaemia, they will die in childhood, while those with less severe syndromes may survive for some years but with a poor quality of life.
- Those who benefit from some basic blood transfusion usually maintain low pre-transfusion haemoglobin and have indications of iron overload and organ involvement despite the availability of iron chelation. Multidisciplinary care to monitor and offer timely intervention to organ damage is not easily found, and full health coverage is not available; such patients may survive to adolescence or young adulthood with increasing complications to vital organs. Unfortunately, this group represents the majority of the global patient population [15,16,17].
- Patients who are cured through haemopoietic stem cell transplantation (HSCT) or gene therapy.
2. Methodology
- Indicators of treatment standards:
- a.
- Blood adequacy: pre-transfusion Hb;
- b.
- Blood safety: allo-immunisation rate;
- c.
- Iron chelation adequacy: serum ferritin and the proportion of patients with SF < 1000 ng/mL;
- d.
- Iron chelation effectiveness: serum ferritin and the proportion of patients with SF > 2500 ng/mL;
- e.
- Monitoring of iron deposition in vital organs: availability of MRI (not available, rarely used, annual measurements of iron in heart and liver). If available: proportion of patients with MRI T2* (an MRI relaxation parameter used for iron assessment) heart >20 ms, and Liver Iron Concentration (LIC) <3 mg/kg dw;
- f.
- Out-of-pocket expenses required by patients/families (Yes/No);
- g.
- Patient registry maintained: data of all patients attending the clinic, including those with transfusion-dependent thalassaemia (TDT), non-transfusion dependent thalassaemia (NTDT), HbH, and other diagnostic categories, are entered into an electronic disease-specific patient registry;
- h.
- Iron chelation availability: availability of all 3 chelators;
- i.
- Proportion taking combination chelation.
- Outcome measures:
- a.
- Age distribution/mean age;
- b.
- Body Mass Index (BMI);
- c.
- Comorbidities (see Table 1);
- d.
- Proportion of tertiary education;
- e.
- Proportion >18 y employed;
- f.
- Proportion single/married;
- g.
- Quality of life measures, if used.
3. Discussion
- The health system within which the service operates: is there adequate support from administration, is there understanding and prioritisation of chronic hereditary disorders, and are there other pressing priorities to the health system (such as malnutrition, infectious diseases)? One major concern is the provision of healthcare coverage for these chronic conditions, either as part of a universal coverage system for the whole population or through a specialised insurance for such conditions.
- The socio-economic environment, including the educational level of the people, the income level compared to the out-of-pocket expenses, and the complexity of the population structure (ethnic minority groups, religious groups, cultural diversity, and recent migrants). Such subgroups can make service provision more complex, with additional needs such as the need for translations, reaching tribal communities, and raising awareness. Education and culture have been shown to influence the acceptability of certain services, such as prevention policies, adherence to treatment, and utilisation of services.
4. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Abbreviations
| Hb | Haemoglobin |
| MRI | Magnetic Resonance Imaging |
| LIC | Liver Iron Concentration |
| BMI | Body Mass Index |
| HSCT | Haematopoietic Stem Cell Transplantation |
| NGOs | Non-Governmental Organisations |
| USD | United States dollars |
| UHC | Universal Health Coverage |
| SCI | Service Coverage Index |
| WHO | World Health Organization |
| TIPSS | Thalassaemia International Prognostic Scoring System |
| SF | Serum Ferritin |
| TDT | Transfusion-Dependent Thalassaemia |
| NTDT | Non-Transfusion Dependent Thalassaemia |
| HbH | Haemoglobin H |
| PTHb | Pre-Transfusion Haemoglobin |
| DALYs | Disability-Adjusted Life Years |
| QALYs | Quality-Adjusted Life Years |
| UAE | United Arab Emirates |
| USA | United States of America |
| UK | United Kingdom |
| IU/L | International Units per Litre |
| T2* | T2-star (MRI relaxation parameter used for iron assessment) |
| dw | dry weight |
| wt | weight |
Appendix A
| Criterion | 0 Points | 5 Points | 10 Points |
|---|---|---|---|
| Mean age (excluding paediatric clinics) | 0–20 years | 21–30 years | 31+ years |
| Proportion of patients pre-trans Hb < 9 g/dL | 50–100% | 10–49% | 0–9% |
| SF | >1500 ng/mL (50+% patients) | 1000–1499 | <1000 (0–20% of patients) |
| MRI availability | Not available | Available with a fee | |
| Available occasionally | Available for free use according to guidelines | ||
| Heart iron (where available) >20 ms | <20% of patients | 20–40% of patients | 50% of patients |
| LIC (where available) <3 mg/kg dw | <20% of patients | 20–40% of patients | 50% of patients |
| LIC > 15 mg/kg dw | >50% | 20–40% | <20% of patients |
| Combination chelation within the last year | 0–10% of patients | >10% of patients | |
| BMI < 18.5 kg/m2 | >10% of patients | <10% of patients | |
| Completed tertiary education | <10% of patients | 10–30% | >30% |
| Married/cohabiting | <10% of patients | 10–30% | >30% |
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| Childhood (<12 Years) | Adolescence (13–17 Years) | Adulthood (>18 Years) |
|---|---|---|
| The effects of anaemia | Iron overload | All endocrinopathies |
| Growth failure | Delayed puberty | Cardiomyopathy |
| Skeletal deformities and fractures | Onset of other endocrinopathies | Bone pain/osteoporosis |
| Splenomegaly | Liver disease |
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Angastiniotis, M.; Cannon, L.; Eleftheriou, A. A Scoring System for the Assessment of Quality of Care in the Management of Transfusion Dependent Thalassemia. Hematol. Rep. 2026, 18, 46. https://doi.org/10.3390/hematolrep18040046
Angastiniotis M, Cannon L, Eleftheriou A. A Scoring System for the Assessment of Quality of Care in the Management of Transfusion Dependent Thalassemia. Hematology Reports. 2026; 18(4):46. https://doi.org/10.3390/hematolrep18040046
Chicago/Turabian StyleAngastiniotis, Michael, Lily Cannon, and Androulla Eleftheriou. 2026. "A Scoring System for the Assessment of Quality of Care in the Management of Transfusion Dependent Thalassemia" Hematology Reports 18, no. 4: 46. https://doi.org/10.3390/hematolrep18040046
APA StyleAngastiniotis, M., Cannon, L., & Eleftheriou, A. (2026). A Scoring System for the Assessment of Quality of Care in the Management of Transfusion Dependent Thalassemia. Hematology Reports, 18(4), 46. https://doi.org/10.3390/hematolrep18040046

