Iron Deficiency Anemia Study Guide PDF

Summary

This document provides a detailed study guide on Iron Deficiency Anemia. It covers symptoms, causes, the iron regulation cycle, dietary absorption, and iron storage. The guide also details the mechanisms of control, gene regulation, and hormonal regulation related to iron deficiency anemia.

Full Transcript

Iron Deficiency Anaemia

07 October 2024

12:55

**Symptoms of Low Hb:**

- Tiredness,

- Breathlessness

- Pallor

- Cardiovascular symptpoms

**4 main causes of ID Anaemia:**

- Blood loss

- Inadequate intake

- Malabsorption

- Increased demand

**Iron Regulation Cycle:**

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- Dietary iron is absorbed by microvilli in SI (duodenum)

- Enters blood stream & is transported by transferrin (protein) to
bone marrow or liver:

- Used in bone marrow for RBC production

- Used in liver (or other tissues) to be stored as ferritin

- Old RBCs are broken down by macrophages within reticuloendothelial
system in liver and spleen.\
Iron is released from haemoglobin and is transported by transferrin
to bone marrow or iron stores

- Small about of iron is lost in urine, faeces, skin, nails, hair

- Iron absorption is just sufficient to make up for iron loss - a
tightly regulated delicate balance

**Dietary Iron Absorption and regulation:**

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- Dietary iron intake is \~10-15 mg/day, only 1 mg absorbed

- From haem and non-haem sources (meat or non-meat)

- Occurs within duodenal enterocytes via haem receptors or Divalent
Metal Transporter 1(DMT-1):

- Meat sources enter via haem receptor

- Non-haem iron is reduced by ferriductase from Fe^3+^ to Fe^2+^,
enters via DMT-1

- Iron either enters stores as ferritin or enters portal circulation
via ferroportin (transmembrane exporter)

- Transferrin transports iron to bone marrow or other tissues with
transferrin receptors (TFR-1) for storage

**Iron Storage**

- Stored as ferritin or haemosiderin

- Ferritin:

- Present in cell of liver, spleen & bone marrow.

- Has an outer protein cell (apoferritin) which binds and stores
iron in ferric-hydroxide-phosphate compound - ferritin

- Iron accounts for 20% of its weight

- Degradation of ferritin by phagolysosomes release iron from
storage

- Haemosiderin:

- Protein-iron complex present in macrophages

- Derived from partial lysosomal digestion of ferritin

- Iron accounts for 37% of its body weight

- Visible by perls stain:

**Iron Regulation**

- Self-regulated (regulated by iron status)

**4 Key points/stages where iron levels are controlled:**

- Iron import from the intestine into the enterocyte via DMT-1

- Iron export from the entroocyte into the circulation via ferroportin

- Ferritin synthesis

- TfR-1 (transferritin receptor 1) synthesis

**Mechanisms of control:**

- Gene regulation

- Hormonal control

**Gene Regulation:**

- Controlled by iron status:

- Regulation of ferritin, TfR1 and DMT-1 genes

- When iron levels are high:

- Increased ferritin production

- reduced TfR1 and DMT-1

- When iron levels are low:

- Reduced ferritin production

- Increased TfR1 and DMT-1

- Iron regulatory proteins (IRPs) control levels of ferritin. TfR1 and
DMT-1 by binding to Iron Response Element (IRE) structures within
untranslated regions of ferritin, TfR1 and DMT-1 mRNA

- Upstream IRP/IRE binding reduces translation

- Downstream IRP/IRE binding stabilises mRNA and increases
translation

- In iron deficiency, IRP/IRE binding is more effective

- In iron overload, binding is reduced

- Ferritin regulation:

- The IRE is at the 5\' end of the mRNA strand

- IRP binding reduces translation

- When iron levels are low IRP binding is increased and less
ferritin is produced

- When iron levels are high IRP binding is reduced and more
ferritin is produced

- TFR1 and DMT-1 regulation:

- The IRE is at the 3\' end of the strand

- IRP binding stabilises mRNA and there is increased translation

- When iron levels are low IRP binding is increased and more TFR1
and DMT-1 is produced

- When iron levels are high, IRP binding is reduced and less TFR1
and DMT-1 is produced

*Khan academy AI chat - simplified & explained:*

**Hormonal Regulation - Hepcidin:**

- Polypeptide hormone

- Produced in liver

- Production is controlled and regulated by iron status, inflammatory
cytokines, erythropoiesis and hypoxia

- Accelerates degradation of ferroportin (transmembrane iron exporter)

- Increased hepcidin leads to: Reduced iron absorption in SI & Reduced
release of iron from macrophages

- Elevated iron levels:

- Saturated transferrin stimulates liver sinusoidal cells to
secrete Bone Morphogenetic Proteins (BMPs)

- BMPs bind to receptors on hepatocyte cell membrane

- Saturated transferrin also stabilises TfR2

- Signalling complex comprises BMPRs, TfR2, HJV and HFE which
stimulates hepcidin synthesis via signalling proteins (SMADS)

- Reduced iron levels:

- Reduced presence of saturated transferrin and reduced synthesis
of BMPs

- TfR2 (stabilised at higher levels of saturated transferrin) is
degraded and HFE binds to un-occupied TfR1

- Matriptase is stimulated and cleaves HJV from the cell membrane
and histone deacetylase suppresses the hepcidin gene locus to
suppress transcription

- Haemochromatosis: Condition with mutation in HFE gene. Leads to
reduced hepcidin production and excessive iron absorption

- Other regulators of hepcidin:

- Inflammatory processes/cytokines(IL-6) increase hepcidin
production

- Hypoxia suppresses hepcidin synthesis

- Increased erythropoiesis suppresses hepcidin synthesis through
secretion of erythroferrone (suppresses BMP mediated cell
signalling)

**Laboratory findings**

- FBC: low Hb, low MCV, low MCH

- Blood film: microcytic/hypochromic anaemia

- Red Cell Distribution Width (RDW - measures variation of red cell
size, \>variation=\>value):


- Ferritin: Low

- Zinc Protoporphyrin (ZPP zinc is carried in RBCs instead of iron- ):
Raised

- Serum iron (not very useful, can indicate iron OD)

- Total Iron Binding Capacity (TIBC - amount of iron bound to
transferrin)

- Decreased serum iron & increased TIBC indicates low transferrin
saturation

- Reticulocyte Hb concentration (infant red cells)

- Bone marrow iron (only in complex cases)

\

**Differential Diagnosis of microcytic/hypochromic anaemia:**

- Thalassaemia (genetic mutations affecting haemoglobin production -
alpha or beta chains are not produced properly)

- Anaemia of chronic disease

- Sideroblastic anaemia (Deficiency of Aminolevulinic Acid (ALA)
enzyme which is used in haeme production. Causes iron to accumulate
in mitochondria, leading to ringed sideroblasts - immature RBCs with
iron deposits circling the nucleus):

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