A Novel Approach for Iron Deficiency Anaemia with Liposomal Iron: Concept to Clinic ()
1. Introduction
Iron is amongst the most essential mineral required for human life and is abundantly available in the earth’s crust. From ancient times, man has recognized the importance of iron in health and disease. Its early medicinal uses were explored and identified by Egyptians, Hindus, Greeks, and Romans [1]. Iron is vital for several bodily functions including haemoglobin synthesis, transport of oxygen throughout the body and catalytic activity of various enzymes. In foetus and infants, it is vital for the development of brain, and therefore cognitive functions in developing stages of life [2].
For many years, nutritional interest in iron mainly involved its role in haemoglobin synthesis and oxygen transport in the body. However, today low iron intake and/or bioavailability are attributed for most anaemia in developing countries. As per World Health Organization (WHO) estimates, approximately two billion people are anaemic worldwide and around 50% of all anaemias are attributed to iron deficiency [3]. It occurs at all stages of the life cycle but is more prevalent in pregnant women and young children [4]. The liposomal form of iron has emerged as a novel concept in the management of iron deficiency anaemia. In this review, we discuss in detail about the role of liposomal iron in the management of iron deficiency anaemia (IDA).
2. Iron Physiology
Iron is mainly distributed in two compartments in the body. The functional compartment includes a number of compounds like haemoglobin, myoglobin, transferrin and enzymes, and others which require iron as a cofactor or a prosthetic (ion or haem) group. The second is a storage compartment, which includes ferritin and haemosiderin constituting the body’s mineral reserves [2]. The body iron content of a normal 70 kg individual is around 50 mg/kg (3.5 - 4 g in women, and 4 - 5 g in men). Iron is majorly distributed as haemoglobin (65%, 2300 mg), myoglobin and enzymes (15%), iron stores (20%), and transferrin bound (0.1% - 0.2%) [5].
A normal diet may contain 6 mg iron per 1000 calories. With a daily intake of 15 - 20 mg of iron, only 1 - 2 mg/day gets absorbed in the duodenum and the first part of the jejunum. There are two forms of iron which gets absorbed, viz. haem (10%) and non-haem (90% ionic). Haem iron is found in foods of animal origin (e.g. red meat, chicken and fish) in the form of haemoglobin or myoglobin. Non-haem (inorganic) iron is mainly found in foods of plant origin, cereals, and some foods of animal origin such as milk and eggs. Absorption of haem iron (15% - 20%) is better than non-haem iron (5%). Haem iron is directly taken up by intestinal cells through a process called endocytosis, where haem-oxygenase (hox) breaks its ring to release ferrous iron (Fe2+) [2].
Dietary non-haem or inorganic iron is usually found in Ferric form (Fe3+). Fe3+ undergoes transformation to its soluble ferrous (Fe2+) iron form at the apical edge of enterocyte with the help of ferric reductase enzyme (duodenal cytochrome B [Dcytb]), thereby allowing it to pass through the mucous membrane of the intestine. Non-haem iron is transported through enterocyte by divalent metal transporter 1 (DMT1), a membrane transport proteins. DMT1 is also responsible for the transport of other metallic ions such as zinc, copper and cobalt by means of a proton coupling mechanism. Absorption of non-haem iron is strongly influenced by dietary factors, such as meat or ascorbic acid (vitamin C), which improve its bioavailability. However, diet containing calcium (dairy products), tannins (tea) or phytates (fibre-rich diets) or concomitant administration of medicines such as tetracycline, proton pump inhibitors and antacids can reduce the iron absorption [5] [6].
In the enterocyte, a small portion of iron is stored in the form of ferritin and the rest is transported through the basolateral membrane into the bloodstream through Fe2+ transporter ferroportin 1 (Ireg-1), aided by the protein hephaestin, which transforms Fe2+ into Fe3+ [7]. Thus iron entered into the bloodstream is scavenged by transferrin, which maintains Fe3+ in a redox-inert state and delivers it into tissues. A significant proportion of this iron also gets stored in the macrophage as ferritin. The macrophages export Fe2+ from their plasma membrane via ferroportin, through a process involving reoxidation of Fe2+ to Fe3+ by ceruloplasmin, followed by the loading of Fe3+ to transferrin. Although, the total iron content of transferrin (≈3 mg) corresponds to less than 0.1% of body iron, it is highly dynamic and undergoes more than 10 times daily turnover to sustain erythropoiesis. The transferrin iron pool is replenished mostly by iron recycled from physiological haemolysis of senescent RBCs [8]. Normally iron is lost through sloughing of epithelial cells from the lining of the gastrointestinal (GI) tract (main pathway) and from the skin. However, these losses are estimated to be very limited (≈1 - 2 mg/day). Iron losses through bleeding can be substantial and excessive menstrual blood loss is the most common cause of iron deficiency in women. Normal blood loss during menstruation is around 30 ml, which can be as high as 118 ml in some women. Every 100 ml of blood is estimated to contain around 40 - 50 mg iron, and excessive menstrual blood loss can result in iron deficiency anaemia in young women with insufficient dietary iron intake [9].
3. Hepcidin: The Key Regulator of Iron
The concentration of iron in biological fluids is tightly regulated to maintain iron levels as needed and to avoid toxicity, as excess iron can lead to the generation of reactive oxygen species. Hepcidin is the major regulator of systemic iron homeostasis. It is a 25 amino-acid peptide hormone mainly expressed by the liver [10]. The expression of hepcidin is regulated by several physiological conditions, such as systemic iron levels, hypoxia, anaemia, erythropoiesis, infection and inflammation [11] [12] [13]. Hepcidin binds the cellular iron exporter, ferroportin (Fpn), inducing its internalization and degradation in hepatocytes, enterocytes, and macrophages, preventing iron transport to plasma and causing cellular retention of iron [14]. Due to decreased iron entry into plasma, there can be low transferrin saturation and less iron delivery to the developing erythroblast. In contrary, decreased expression of hepcidin can increase cell surface ferroportin and increase iron absorption [15] (Figure 1).
Dysregulation of hepcidin expression results in iron disorders. Inflammatory conditions trigger the expression of hepcidin which lowers intestinal iron absorption and stored iron release (mucosal block). Overexpression of hepcidin
Figure 1. Hepcidin-mediated regulation of iron homeostasis. Source: De Domenico, et al. [15].
leads to the anaemia of chronic disease, while low hepcidin production results in hereditary haemochromatosis (HFE) with consequent iron accumulation in vital organs [15].
4. Dietary Iron Recommendations for Indians
In the Indian context, absorption of iron from a cereal-pulse based diet in adult male is 5% and is 8% in women who are expected to have better absorption due to iron deficient store. In infants of 6 - 12 months of age, iron absorption of 15% is observed [16] (Table 1).
5. Iron Deficiency Anaemia
Anaemia is defined as the condition with a decreased number of RBCs in the blood, or RBCs have less than the normal amount of haemoglobin. Iron deficiency is the most significant and common cause of anaemia worldwide. Iron deficiency is defined as a condition with depletion of iron stores characterized by signs of a compromised supply of iron to tissues, including the erythrocytes. Iron deficiency can present with or without anaemia. Some functional changes may be evident in the absence of anaemia, but the most functional deficits manifest with the development of anaemia. IDA is a severe condition characterised by low levels of iron and the presence of microcytic hypochromic red cells [17].
The aetiology of IDA can be classified as:
Table 1. RDA for iron in Indians [16].
5.1. Insufficient Iron Intake
Iron intake insufficiency is more common in paediatric population, in children during growth years, infants who are weaned early to cow’s milk or infant cereals (foods with low iron content), vegetarian diet or no intake of red meat and insufficient intake due to poverty.
5.2. Abnormal Iron Loss (Chronic Bleeding)
Commonly observed in adolescent and adult women with vaginal bleeding such as dysfunctional uterine bleeding or bleeding secondary to uterine disorders. Chronic conditions involving GI bleeding, such as erosive gastritis, bowel polyps, peptic ulcer, diverticulitis, benign tumours, intestinal cancer, inflammatory bowel diseases, angiodysplasia, haemorrhoids, hookworm infestation, obscure source.
5.3. Increased Iron Requirement
The main causes of increased demand for iron are pregnancy (second and third trimester), breastfeeding, and growth spurts in adolescence.
5.4. Impaired Iron Absorption or Acidification
Iron malabsorption can be due to digestive disorders, celiac disease, inhibited hydrochloric acid secretion (use of proton pump inhibitors); Helicobacter pylori infection, atrophic gastritis, etc.
IDA is chronic, often asymptomatic and thus may be difficult to diagnose. Low oxygen perfusion of body tissues and decreased activity of iron-containing enzymes may lead to weakness, fatigue, poor concentration and non-specific symptoms like poor productivity. IDA is known to affect cognitive performance and to delay mental and motor development in children. Severe IDA in pregnancy can increase the risk of preterm labour, low neonatal weight and neonatal and maternal mortality.
6. Management of IDA
For the management of IDA, the objective of therapy is to normalise haemoglobin levels and replenish iron stores along with the correction of pathways causing loss or malabsorption of iron. Iron deficiency correction should begin with dietary recommendations (intake of iron rich foods). However, when dietary changes alone are insufficient to replenish iron stores and normalise haemoglobin levels, or in severe anaemia cases, iron supplement therapy should be initiated.
6.1. Parenteral Iron Preparations
Iron is administered intravenously in iron carbohydrate complexes formulations consisting of a mineral core, composed of polynuclear iron (III)-hydroxide surrounded by the carbohydrate ligand [18]. The ligand helps to stabilise the complex and also protect it against further polynuclearisation. Examples include iron sucrose, ferric carboxymaltose, sodium ferric gluconate in sucrose, for injection and various iron dextran formulations. The stable complexes of parenteral irons such as ferric carboxymaltose and iron dextran, after administration, are taken up by endocytosis by macrophages of the reticuloendothelial system (RES) [18]. However, the highly regulated process of iron release from carbohydrate complexes can be disrupted in less stable preparations. In this case, release of significant amounts of labile iron from the complex may cause saturation of transferrin and form significant amounts of non-transferrin bound iron (NTBI). This weakly bound Fe3+ may get deposited in an unregulated way inside the cells of endocrine system, the heart and the liver, where it can induce oxidative stress by catalysing lipid peroxidation and reactive oxygen species formation [19].
Parenteral iron preparations could be an alternative in patients who are unable to tolerate oral iron and are non-compliant or need rapid restoration of iron stores.
6.2. Oral Iron Preparations
Iron preparations providing more elemental iron per dose should be an ideal choice. Along with elemental iron content, the side effects of these preparations like nausea, vomiting, and abdominal pain should also be considered [20].
The administration of oral iron is a convenient, inexpensive, and effective means for IDA correction. There are a number of oral iron formulations available, and for the most part all are equally effective. Among the myriad preparations in the market, iron sulphate is the most frequently used, along with gluconate and fumarate as effective iron salts.
The dose of oral iron depends on patient’s age, the estimated iron deficit, the rapidity with which it needs to be corrected and side effects. The recommended dose of oral iron in adults with iron deficiency anaemia is 100 - 200 mg of elemental iron daily. There are a number of oral iron preparations available for the management of IDA. Their appropriate dosage is determined by the amount of elemental iron they deliver. As an example, a 325 mg ferrous sulphate tablet contains 65 mg of elemental iron per tablet; three tablets per day will provide 195 mg of elemental iron, of which approximately 25 mg is absorbed [21]. Thus, in order to meet the recommended daily dose of elemental iron; one may end up consuming higher doses of iron supplement which may cause GI side effects.
6.3. Limitations of Conventional Oral Iron Preparations
Conventional iron preparations usage is associated with various side effects like nausea, vomiting, flatulence, abdominal pain, diarrhoea, constipation, dyspepsia and black or tarry stools. These side effects have been the main concern with oral iron therapy. Up to 70 percent of patients who are on oral iron preparations (especially ferrous sulphate) report GI side effects [22]. Limitations associated with conventional iron salt led to emergence of different oral iron preparations like carbonyl iron, iron polymaltose complex, ferrous ascorbate, sodium feredetate and ferrous bisglycinate. However, efficacy and side effects were comparable between these conventional iron preparations when used for treating patients with IDA [23]. The impact of GI related side effects results in non-adherence in up to 50% of patients. Undesirable organoleptic attributes (metallic taste) also significantly contributes to the non-adherence of the therapy. These factors predispose patients to significant treatment failures and unnecessary follow-up investigations [22].
Oral iron therapy may not be effective for individuals with ongoing blood loss, inflammatory bowel disease or gastric bypass, chronic kidney disease (CKD), or those with substantial distress from the side effects of the same. During inflammation, macrophages produce high levels of IL-6, the pro-inflammatory cytokine that triggers the expression of hepcidin. This mechanistic increase in hepcidin levels reduces oral iron absorption in patients with concomitant inflammatory states like CKD, infection and cancer [24]. Hepcidin released into the circulation binds ferroportin, and the complex is internalized and degraded, in turn blocking iron export into the circulation (mucosal block). Moreover, higher or more frequent doses of iron supplement also raise circulating hepcidin levels and reduced subsequent fractional iron absorption [25]. This potential mechanism result in poor response to conventional oral iron preparations and supports the approach of switching to IV iron in patients with these conditions.
7. Liposomal Iron: Breakthrough in the Management of IDA
Liposomal iron is the breakthrough in the management of IDA, non-responsive to conventional oral iron preparations. Liposomes are effective drug carrier systems which have potential for target specific delivery of different therapeutic substances. Their biocompatibility, biodegradability and low toxicity make them suitable option for delivering drugs [26].
Liposomal iron, a new generation oral iron preparation of ferric pyrophosphate carried within a phospholipid and lecithin membrane, shows a high GI absorption and high bioavailability with lower incidence of side effects. It involves a sophisticated technology that uses liposomes as a carrier, where iron without coming in contact to GI mucosa gets directly absorbed in the intestine. The particle size of ferric pyrophosphate is reduced by the process known as Micronisation, which increases the solubility of iron. Processing into smaller particles increases the surface area of the molecule and thereby its dissolution rate. Further the micronised iron is encapsulated by a lipid bilayer membrane like biological membranes through Microencapsulation. The formed liposome thus has the structure of outer bilayer membrane and inner core containing the iron particles (Figure 2). Outer phospholipid bilayer prevents degradation of iron from enzymes in mouth and/or stomach, interaction with alkaline juices, bile salts, intestinal flora and protect from free radicals. Thus, liposomes prevent oxidation and degradation of the iron contents in the core and assists in targeted delivery [26] [27] [28].
Through “Trojan Horse-like” mechanism, the liposome is directly absorbed in the intestinal lumen by the microfold cells (M cells) of the small intestine, which is the part of lymphatic system. Subsequently, the liposome is incorporated in macrophages by endocytosis and through the lymphatic system reaches hepatocytes. In hepatocytes, the liposome is opened by lysosomal enzymes, making the iron available for utilization [29].
8. Advantages of Liposomal Iron
8.1. Better Bioavailability
Liposomal iron facilitates quicker absorption and availability of iron in the body.
Figure 2. Technological representation of micronization and microencapsulation.
Experimental studies have shown faster and significant improvement of serum iron and liver iron contents by liposomal iron as compared to conventional oral iron preparations [30].
An experimental study was done to evaluate the efficiency of iron absorption in four groups of rats. These Group received Liposomal iron (Lipofer®), Ferrous sulphate, Ferric pyrophosphate free salt or control (carboxymethyl cellulose 1%). The pharmacokinetic profile revealed that Lipofer® has the higher values of iron concentrations at any time points as compared to other salts [31] (Figure 3).
Liposomal iron (Lipofer®) was 2.7 and 3.5 times more bioavailable than ferrous sulphate and plain ferric pyrophosphate, respectively [31] (Figure 4).
8.2. Better Tolerability
In a study, 30 post-menopausal females with iron deficiency anaemia (Haemoglobin, Hb < 11.5 g/dL) who were already been treated with other iron supplements and experiencing side effects, were treated with liposomal iron supplement (microencapsulated iron pyrophosphate in liposomal form). After 8 weeks of supplementation there was a significant rise in haemoglobin and hematocrit levels and the treatment was well tolerated with statistically significant improvement in most of the side effects previously experienced by the patients [32] (Figure 5).
Figure 3. Iron concentration measured at different time points.
Figure 4. AUC values for different iron dosages.
Figure 5. Side effect total score from previous iron and liposomal iron treatment.
8.3. No Oxidative Adverse Effects
The conventional iron can increase the oxidative damage evident by alteration in the malondialdehyde (MDA) and super-oxide dismutase (SOD) levels. Studies have confirmed that liposomal iron is associated with decreased MDA levels and increase in SOD levels. This may help in minimizing the oxidative damage otherwise seen with conventional iron preparations [30].
8.4. No Interaction with Dietary Inhibitors
The absorption of conventional non-haem iron could be restrained by factors like dietary inhibitors. Phytic acid in diets based on cereals and legumes has been shown to inhibit iron absorption in-vivo and in cell culture models. Iron preparation in liposomal form, due to technological processing advantage and different mechanism of absorption, offers a better iron delivery without being affected by dietary inhibitors [33].
9. Evidence in Different Clinical Conditions
9.1. Pregnancy
Parisi et al. conducted a study to compare the liposomal iron with ferrous sulphate in 80 non-anaemic pregnant women recruited at 11 to 13 weeks of gestation. They were randomised to one of the four treatment groups, controls (C; n = 20) and groups supplemented with ferrous iron 30 mg (SF; n = 20), liposomal iron 14 mg (FF14; n = 20) and liposomal iron 28 mg per day (FF28; n = 20) up to 6 weeks post-partum. Both FF28 and FF14 groups showed significantly higher haemoglobin and ferritin concentrations compared with SF group and controls (Figure 6). Birth weight showed a trend to increase with supplementation, resulting in higher birth weight in the FF28 group compared with controls (3499 ± 464.1 g and 3092 ± 469.5 g, respectively, p < 0.01) [34].
9.2. Menstruating Women
In a randomised, double-blind, placebo-controlled study of 16 weeks of duration, 122 iron deficient women were randomised to either microencapsulated
Figure 6. Liposomal iron group showed significant increase in Hb and ferritin levels compared to SF (p < 0.01) and C (p < 0.05) groups at 28 weeks and in post-partum period.
iron pyrophosphate (F group, n = 64) or placebo (P group, n = 58) as a supplement to usual diet. Microencapsulated iron pyrophosphate provided 18 mg iron per day (100% of the RDA). There was a significant 79% (p <= 0.001) increase in Ferritin levels in F group as compared to P group after 16 weeks (Figure 7). There was also significant increase in hematocrit (p = 0.006), RDW (p = 0.003) and Hb (p < 0.0001) levels [35].
9.3. Inflammatory Conditions
The inflammatory conditions render the absorption of conventional oral iron ineffective, due to increased hepcidin levels causing mucosal block. Hence, IV iron has shown a significant superiority to conventional oral iron in increasing Hb. However, Liposomal iron due to sophisticated technology overcomes mucosal block and ensures better bioavailability in such patients. Pisani et al. in a randomized trial showed that oral liposomal iron can be a safe and efficacious alternative to parenteral iron to correct anaemia in CKD patients. In this study, there was a similar increase in Hb in both liposomal iron group (30 mg/day) and IV iron group (ferrous gluconate 1000 mg/day) with significantly low incidence of adverse event in the oral group (3.1 vs 34.5%, p < 0.001) [36]. Also the results from studies done in refractory anaemia (myelodysplastic syndrome-MDS) indicate that oral liposomal iron may be as effective as IV iron in such patients [37]. Study with liposomal iron has shown to reduce inflammatory markers in correction of anaemia of chronic inflammatory disease of young women [38].
Figure 7. Increase in ferritin levels in F group as compared to P group.
10. Conclusion
Conventional iron preparations are often associated with various GI side effects resulting in non-adherence to the therapy by substantial number of patients. Liposomal iron, a new generation oral iron preparation, technologically engineered through process of micronisation and microencapsulation, helps to overcome the limitation associated with the conventional iron preparations. The technological advancement has translated the benefit into clinical outcomes as evidenced by multiple studies. Liposomal iron significantly increases Hb, ferritin levels in pregnant as well as in women of reproductive potential and it is an effective and safe alternative to parenteral iron in chronic inflammatory conditions associated with IDA.