Anemia
Hematopoesis
• erythroid differentiation in the
bone marrow takes 5-7 days
• the lifespan of an erythrocyte
in the blood is 120 days
• decreased in hemolytic anemias possibility of
compensation by increased production of
erythrocytes (8 – 10x)
• reticulocytes
• normally in blood 1-1.5% within 1-2 days of
maturation into erythrocytes
2
Hemopoietic growth factors
glycoproteins
• act on the cytokine-receptor superfamily
stimulating factors
• erythropoietin
• IL-3, 6, 7, 11, 12
• thrombopoietin
• produced in the kidney and liver
• controls platelet production
inhibiting factors
• TNF-α, TGF-β
use in treatment
– G-CSF
• accelerate recovery after chemotherapy
and hemopoietic cell transplantation
• EPO
• thrombopoietin receptor agonist
• treatment of immune thrombocytopenic purpura
3
Spleen
contains approximately 5% of blood
• function
• remodelling of the erythrocyte membrane uptake and
destruction of old and damaged erythrocytes
• splenomegaly
• enlargement of the spleen due to increased destruction of
erythrocytes in some pathological conditions (e.g.
spherocytosis)
• removal of the spleen
(=splenectomy) can correct anemia
and relieve symptoms
Kidneys and erythropoiesis
the main regulator of
erythropoiesis is erythropoietin
(EPO)
• produced by the peritubular cells of the kidney
reduce the production of
erythropoietin
• kidney disease
• antibodies against EPO
5
Journal of the Formosan Medical Association, Volume 117, Issue 11, 2018
Oxygen sensor of the cell
• transcription factor HIF (hypoxia-inducible factor)
• subunit α
• „oxygen-dependent“
• in normoxia - HIF-1α prolix is hydroxylated
• degradation in proteasomes using von Hippel-Lindau
protein
• in hypoxia – inhibition of hydroxylation and activation
of HIF signalling
• subunit β
• stable
• activation of gene expression and regulation of
multiple processes
• erythropoiesis and iron metabolism
• anaerobic glucose metabolism
• angiogenesis
• e.g. VEGF – increased vascularisation of tissues
• growth, proliferation
6
Hemoglobin synthesis
• performs main function of RBC
• adult Hb molecule (HbA)
• 2 α chains, 2 β chains (α2β2)
• 97 % of the Hb in adults
• other types
• HbA2 (α2δ2): 1.5 – 3.2 %
• HbF (α2γ2): < 1 %
• synthesis in the mitochondria
• production of aminolevulinic acid
• ALA synthase
• rate-limiting step
• coenzyme vitamin B6
• inhibited by heme
• stimulated by EPO
7
Degradation of erythrocytes
̶ hemolysis may occur
̶ extravascularly
• spleen, bone marrow, liver
• aggravated leads to jaundice
• hemoglobin is reused
̶ intravascularly
• serum haptoglobin is decreased
• hemoglobin is filtered in the kidneys
• appears in the urine
• precipitation in the tubules – up to acute kidney
failure
Anemia
criteria
•  the amount of hemoglobin - a basic criterion
• the transport capacity of the blood for oxygen depends on the amount of
hemoglobin !!!
•  haematocrit
• cave megaloblastic anemia
•  the number of erythrocytes in a unit volume of blood
• cave hypochromic anemia
• the reference level for the age and sex of the individual
• anemia
• light (Hb 110 – 90 g/l)
• moderate (Hb 90 - 60 g/l)
• serious (Hb <60 g/l)
Pathogenesis of anemia
• regulation of erythropoiesis
• [Hb]/O2  pO2 in kidney  erythropoietin  marrow erythropoiesis
• Ery v circulation ~120 days
• daily turnover 0.8% (~21011, =20ml erymass)
• anemia is the result of a production/destruction imbalance of Ery
• (1) reduced production
• (2) increased destruction
• (3) a combination of both mechanisms
Symptoms and Signs
Symptoms
Signs
• Palpitations
• Vertigo
• Pica (with iron
deficiency)
• Irritability
• Fatigue
• Dizziness
• ↓ exercise
tolerance
• Shortness of
breath
• Weakness
• Tachycardia
• Pale appearance
• ↓ mental acuity
• Neurological symptoms (with vitamin B12 deficiency)
Anemia symptoms
symptoms of anemia
subjective
nonspecific
weakness, fatigue
disturbances of sleep and performance
emotional lability
headache
objective
depends on ethiology and pathogenesis
paleness, jaundice, petechia, hematomas
Hunter glositis
smoothed tongue
albuminuria
nervous system
11
Anemic syndrome - compensatory mechanisms
• compensation mechanisms
•  erythropoesis (+/-)
• shift of the Hb dissociation curve to the right
• increase in cardiac output
•  viscosity - hyperkinetic circulation
• due to the half-life and speed of recovery of
leukocytes and platelets, the manifestation of posthemorrhagic
anemia is mainly due to changes in the
erythrocyte line
• Acute loss of 30% volume (~1500 ml)  circulatory
collapse, shock ( 50%  death)
• no "emergency" RBC pool, only the release of reticulocytes is possible
• medullary RBC production can increase up to 8-fold provided there is
sufficient Fe supply
• symptomatology depends very much on the speed
with which the anemia arose!!!
Anemia classification
pathogenetic
• increased RBC loss
• bleeding
• haemolytic anaemia
• corpuscular
• membrane
• hemoglobinopathy
• enzymopathy
• extracorpuscular
• toxic
• autoimmune
• insufficient RBC production
• lack of erythropoietin
• lack of essential factors
• bone marrow disorder
morphologic
• RBC size
• haemoglobin content
• pathologic morphology
13
Increased loss
Increased Ery
destruction
Blood loss
• Membrane defects
• hereditary spherocytosis, elliptocytosis
• paroxysmal nocturnal hemoglobinuria
• Enzyme defects
• glucose-6-phosphate dehydrogenase
• pyruvat kinase
• disorders of hemoglobinization and
hemoglobinopathy
• talasemia
corpuscular
• damage caused by nonimmunological
and toxic effects
• mechanical
• bacterial toxins
• membrane disorders with altered lipid
metabolism
• drugs, parasites
• Damage by auto-antibodies
• Fetal erythroblastosis
• Autoimmune hemolytic anemia
• SLE
extracorpuscular
acute
chronic
Anemia due to blood loss
• acute
• intravascular volume loss
• amount is important
• cardiovascular collapse, shock, death
• volume repletion
• water shift, ↓ haematocrite
• ↑ EPO production
• iron loss
• blood pressure decrease
• epinephrine release
• granulocytes mobilization
• leukocytosis
• reticulocytosis
• 10 – 15 % after 15 days
• thrombocytosis
• chronic
• less activated erythropoiesis
• losses may exceed regeneration
capacity of bone marrow
• iron stores depletion
15
Hemolytic anemias
• common signs
• premature RBC destruction
• normally in mononuclear phagocytes
• usually extravascular
• phagocytes hyperplasia
• splenomegaly
• increased EPO and stimulation of
erythropoiesis
• accumulation of haemoglobin
degradation products
• iron deficit is not present
• clinical signs
• anaemia
• splenomegaly
• jaundice
• intravascular haemolysis
• hemoglobinemia
• hemoglobinuria
• hemosiderinuria
• splenomegaly is missing
• ↓ haptoglobin
Ústav patologické fyziologie LF MU16
Hereditary spherocytosis
• most common inherited hemolytic anemia
in Northern Europeans (1:5000)
• autosomal dominant - one defect (75 %)
• in 75 % neither parent is affected
• spontaneous mutation
• recessive?
• defect in RBC membrane
• deficit of structural proteins
• ankyrin
• spectrin
• mutations
• reading frame shift or premature stop
codon
• RBC lifespan 10 – 20 days
• changes
• young RBC – normal shape
•  membrane stability with aging
•  deformability – trapping in the spleen
• splenectomy
• spherocytes remain
• correction of anaemia
• clinical features
• possible jaundice at birth
• onset can be delayed for many years
• some patients - without symptoms
17
Glucose-6-phosphate dehydrogenase
(G6PD) deficiency
18
• recessive X-linked disease (Xq28)
• more common in males
• affects millions of people
• Africa, Mediterranean, Middle East (20 %)
• South-East Asia (up to 40 % in certain
areas)
• G6PD function
• oxidation of G6P to 6-phosphoglycerate
• production of NADPH
• the only source of RBC
• regeneration of glutathione
• protection of oxidative damage
G6PD deficiency
19
• episodic hemolysis
•  oxidative stress
• infection
• viral hepatitis, pneumonia
• drugs
• antimalarics, sulfonamids
• ingestion of fava beans
• favism
• denaturation of globin chains
• binding of sulfhydryl groups
• precipitates bound to membrane
• Heinz bodies
•  deformability
• intravascular haemolysis
• clinical features
• anemia
• jaundice
• hemoglobinuria
Pyruvate kinase deficiency
• the most common defect of RBC metabolism
after G6PD deficiency
• affects thousands people
• autosomal recessive
• variable severity
• homozygotes have anemia and splenomegaly
• lower PK activity
• reduced ATP production
• energy deficit
•  resistance of membrane – rigid RBC
• diagnostics
• lower enzymatic activity
• 5 – 20 % in affected homozygotes
Ústav patologické fyziologie LF MU20
Hemoglobinopathies
• abnormalities occur in
• globin chain production
• thalassemia
• structure of the globin chain
• sickle cell disease
• change of amino acid composition
of globin chain or incorrect
proportion of subunits
• highly variable clinical
manifestations
• mild hypochromic anemia
• moderate hematological disease
• severe, lifelong, transfusiondependent
anemia with multiorgan
involvement
21
Sickle cell anemia
• common hereditary hemoglobinopathy
• point mutation in the codon 6
• valin instead of glutamic acid
• abnormal HbS
• 2 forms
• homozygous
• sickle cell anemia (HbSS)
• heterozygous
• sickle cell trait (HbAS)
• most common in
• Africa
• up to 25 % in some populations
• India, Middle East, Southern Europe
• HbF synthesis is normal
• manifestation when hbF decreases to adult levels
• approx. 6 months of age
Ústav patologické fyziologie LF MU22
Sickle cell anemia
• deoxygenated HbS
• polymerizes and becomes insoluble
• flexibility of RBC is decreased
• rigid, sickle appearance
• change of shape
• initially reversible
• after repeated sickening membrane loses
flexibility
• irreversibly sick cell
• due to dehydration
• sickling can produce
• shortened RBC survival
• impaired passage through microcirculation
• sickling precipitated by
• infection, dehydration
• cold, hypoxia
• clinical features
• vaso-occlusive crisis
• pain in the hands and feet
• pulmonary hypertension
• in 30 – 40 %
• NO deficiency?
• anemia
• stable Hb 60 – 80 g/l
• splenic sequestration
• long-term problems
• growth and development
• bones
• infections
• cardiac problems
• neurological complications
• liver
• pregnancy
23
Thalassemias
• normally balanced production of α and β
globin chains (1:1)
• defective synthesis of globin chains in
thalassemia
• imbalance
• precipitation of globin chains
• ineffective erythropoiesis
• Hemolysis
• mutations causing  synthesis of HbA
• heterogenous group
• endemic
• Middle East, tropic Africa, India, Asia
• one of the most common hereditary
diseases
• heterozygous forms
• protection from malaria
• α-talassemia
• deficit of α chain synthesis
• β-thalassemia
• deficit of β chain
• chromosome 11
Ústav patologické fyziologie LF MU24
β-thalassemia
• homozygous β-thalassemia
• β0 mutation
• β-chain is missing
• β+ mutation
• β-chain production is reduced
• heterozygous β-thalassemia
• usually symptomless
• microcytosis with or without mild anemia
• ↓ lifespan of RBC and their precursors
• precipitation of α-chains – membrane
damage
• ineffective erythropoiesis
• destruction of some RBC in bone marrow
• remaining RBC are prone to extravascular
hemolysis
Ústav patologické fyziologie LF MU25
Ústav patologické fyziologie LF MU26
β-thalassemia
• > 200 genetic defects
• mainly point mutations
• highly unstable β-chain
• clinical classification
• major
• 2 alleles
• severe anemia requiring regular
transfusions
• minor (thalasemia trait)
• 1 allele, heterozygous carrier
• without symptoms
• intermedia
• genetically heterogenous
• moderate anemia not requiring regular
transfusions
• serious β-thalassemia
• erythroid hyperplasia, extramedullar
hemopoiesis
• bone damage
• increased iron absorption
• supressed hepcidin synthesis
• iron from transfusions
Ústav patologické fyziologie LF MU27
α-thalassemia
• gene for α-globin chain is duplicated on
both chromosomes 16
• normal person has 4 α-globin genes
• deletion of 1 or both α-chain genes on each
chromosome may occur
• most common is deletion of 1
• decreased α-chain synthesis
• excess of unmatched chains
• less severe than β-thalassemia
28
Autoimmune hemolytic anemia (AIHA)
̶ Autoimmune hemolytic anemia (AIHA) is caused by
auto-antibodies directed against self red blood cell
(RBC) surface antigens
̶ intravascular hemolysis mediated by activated
complement or extravascular hemolysis
̶ By activating complement,
̶ to the destruction of erythrocytes with bound antibody in the monocytemacrophage
system
̶ Classification
̶ primary (idiopathic) and secondary
̶ According to the nature of the antibodies present
̶ AIHA with warm antibodies,
̶ AIHA with cold antibodies,
̶ AIHA with mixed antibody type and
̶ paroxysmal cold hemoglobinuria.
J. Clin. Med. 2020, 9(12), 3859; https://doi.org/10.3390/jcm9123859
Pathogenesis of AIHA
̶ consists of
̶ a defective antigen presentation to immunocompetent
cells,
̶ insufficient process of T-lymphocyte tolerance to
autoantigens and
̶ induction of autoantibody production by B-lymphocytes
̶ Abnormal antigen presentation or
processing leads to a defect in apoptotic
signals
Vnitř Lék 2018; 64(5): 514–519
Autoimmune hemolytic anemia (AIHA):
classification
Autoantibody Characteristics
Class
Optimal T of
Reaction (Range)
Specificity DAT Positivity
Warm AIHA (wAIHA)
IgG (possible
Complement fixation)
37 °C (0–40) Rh system IgG or IgG + C
Cold Agglutinin
Disease (CAD)
IgM (common
complement fixation)
4 °C (4–34) I/i system C
Mixed AIHA
warm IgG and cold
IgM
4 °C and 37 °C //
IgG + high titer cold
IgM
Paroxysmal Cold
Hemoglobinuria
(PCH)
IgG (common
complement fixation)
Reacts at 4 °C and
hemolyzes at 37 °C
P Antigen
Positive DonathLandsteiner
Test
Dsetruction of Ery
̶ IgG autoantibodies are monomers - weakly fix
the complement system;
̶ they cause RBC destruction via the antibody-dependent
cellular cytotoxicity (ADCC), -monocyte-macrophage system
that phagocyte RBCs. (Activated lymphocytes that express
receptors for the IgG Fc fragment and for C3b may also
mediate an ADCC.)
̶ Hemolysis is extravascular and occurs mostly in the spleen in
the case of macrophage-mediated ADCC, and in the liver in
the case of C3b-mediated ADCC.
̶ Spleen represents also a lymphatic organ, and therefore able
to contribute to autoantibody production.
̶ IgM autoantibodies are pentamers with high
avidity and ability to activate the complement
cascade until the final lytic complex (C5–C9).
̶ The lysis of RBCs directly in the circulation (intravascular
hemolysis) through the activation of “perforins” and other
cytotoxic factors.
̶ with a consequent greater clinical severity
J. Clin. Med. 2020, 9(12), 3859;
https://doi.org/10.3390/jcm9123859
Extracorpuscular hemolytic anemia
• mechanical damage to
erythrocytes
• damage by toxins or
parasites
• antibody and complement
damage
• damage by antibodies
against blood group antigens
33
https://www.kardiochirurgie.cz/
Production failure
Proliferation
disorder
Maturation
disorder
• Higher demands
• Growth, pregnancy
• Insufficient supply
• Vegetarianism, old age
• Loss
• Menorrhagia, GIT, …
Iron deficiency
• kidney damage
• hypometabolism
Decreased production
or effects of EPO
• Aplastic anemia
• Infiltrative diseases of bone
marrow
• Bone marrow irradiation, toxins
Bone marrow failure
• Severe iron deficiency
• Thalassemia
• Porphyrin metabolism
disorders
Cytoplasmic
maturation disorder
• Vitamin B12 deficiency
• Lack of folic acid
• Primary bone marrow defect
Nucleus maturation
disorder
Anemia of decreased RBC production
• nutritional deficiency
• iron
• vitamin B12
• folic acid
• aplastic anemia
• sideroblastic anermia
• secondary as a result of
• kidney failure
• chronic inflammation
Ústav patologické fyziologie LF MU35
Megaloblastic anemias
• erythroblasts with delayed nuclear
maturation in the bone marrow
• defective DNA synthesis
• abnormally large RBC and their
precursors
• immature nuclei
• deficit of vitamin B12 or folic acid
• thymidine synthesis
• defects in nucleus maturation
• delay or blockade of cell division
• morphology
• macrocytes or macroovalocytes
• central brightening is missing but MCHC is
not increased
• anisocytosis, poikilocytosis
• ↓ reticulocytes
• neutrophils
• larger and hypersegmented
• hypercellular bone marrow
• maturation of cytoplasm and Hb
accumulation is normal
• ↑ growth factors
• apoptosis of precursors in the bone
marrow
• mild hemolysis
36
Metabolism of vitamin B12
37
• vitamin B12 = cobalamin
• essential
• animal sources
• meat, fish, egg, milk
• not in plants
• usually not destroyed by cooking
• stores in the liver
• alternative resorption
• without IF
• up to 1 % of its content in the diet
Functions of vitamin B12
38
• 2 reactions dependent of B12
• methionine production
• methyl group acceptor
• formation of TH4
• generation of sukcinyl CoA from
methylmalonyl CoA
• ↑ methylmalonyl acid in plasma and
urine
• abnormal fatty acids in neuronal lipids
• neurologic complications
B12 deficit = pernicious anemia
• autoimmune gastritis
• intrinsic factor deficit
• occurrence
• all races
• older people (median 60 years)
• pathogenesis
• autoimmunity
• chronic atrophic gastritis
• parietal cells loss
• autoantibodies are not specific
• autoreactive T cells
• achlorhydria, ↓ pepsine
• gastrectomy
• exocrine pankreas dysfunction
• ileum resection
• tapeworm
• ↑ demands on B12
• relative deficit
• diagnostics
• megaloblasts
• leucopenia
• hypersegmented granulocytes
• ↓ level of B12
• ↑ homocysteine and methylmalonyl acid
• gastritis
• ↑ risk of gastric carcinoma
• homocysteine
Ústav patologické fyziologie LF MU39
Folic acid deficiency anemia
• tetrahydrofolate (FH4)
• transfer of 1 C groups
• methyl, formyl
• processes dependent on these transfers
• purines synthesis
• homocysteine → methionine
• synthesis of deoxythimidylate
monophosphate
• etiology
• decreased intake
• essential, heat inactivation
• small stores (weeks)
• increased demands
• pregnancy, growth, cancer
• disturbed utilization
• methotrexate
• folic acid antagonist
• dihydrofolate reductase
• distinction from pernicious anemia
• ↓ folates in the blood
• ↑ homocysteine but not methylmalonic acid
Ústav patologické fyziologie LF MU40
Iron deficiency anemia
• inadequate iron for haemoglobin
synthesis
• cause
• blood loss
• increased demands
• growth, pregnancy
• decreased absorption
• post-gastrectomy
• poor intake
• etiology
• food deficiency
• infants
• developing countries
•  absorption
• absorption is supported by
• ascorbic acid
• supressed by
• oxalates, phosphates, tanins
• malabsorption syndrome
• diarrhea
• gastrectomy
•  demands
• growth, pregnancy
•  losses
• chronic
• GIT bleeding
Ústav patologické fyziologie LF MU41
Iron deficiency anemia
• hypochromic microcytic anemia
• after depletion of stores
•  serum iron, ferritin and transferin
saturation
• absence of stainable iron in the
macrophages from bone marrow
• diagnostics
•  hemoglobin, hematocrit
•  iron, ferritin and transferrin
saturation (< 15 %)
• iron supplementation
•  reticulocyte count after 5 – 7 days
Ústav patologické fyziologie LF MU42
Sideroblastic anemia
43
https://www.osmosis.org/learn/Sideroblastic_anemia
• inherited or acquired disorder
• inadequate use of iron
• accumulation in mitochondria of erythroblasts
• ring sideroblast
• an erythroblast with stainable iron granules in its
cytoplasm
• defect of ALA-synthase
• inherited form
• excess iron in bone marrow
• acquired
• alcohol, drugs
• mutations
• protoporphyrine production is slow
• variable number of hypochromic microcytes
Diagnostics (Basel). 2023 Jan; 13(2): 304.
Causes of Iron Deficiency Anemia
1. Anemia due to martial deficiency
(a) insufficient reserves: prematurity, twinship, neonatal hemorrhages, maternal anemia
(b) insufficient food intake: diet with excess flour, exclusive diet with goat’s milk, protein and vitamin deficiencies, vegetarian diet
(c) deficient absorption:
presence of inhibitory factors (phytate, phosphates, carbonates), lack of reducing factors (vitamin C,
hydrochloric acid, bile acids), celiac disease, gastrectomy, Helicobacter Pylori infection, intestinal
resections, bacterial overgrowths
2. Iron-loss anemia
(a) gastro-intestinal hemorrhages:
esophageal varices (liver cirrhosis), diaphragmatic hernia, esophagitis, gastro-duodenal ulcer, cancer
of the digestive tract (esophageal, gastric, colonic cancer), tumors of the small intestine, Vaterian
ampulloma, hemorrhoids, rectal polyps, intestinal parasites, celiac disease, Crohn’s disease,
ulcerative colitis, colonic angiodysplasia, bariatric surgery, NSAIDs consumption
(b) hemorrhages of respiratory origin:
epistaxis, pulmonary tuberculosis, lung cancer, bronchiectasis, pulmonary microinfarcts, alveolar
hemorrhage
(c) genito-urinary hemorrhages:
prolonged menstrual cycle, metrorrhagia, renal tuberculosis, renovesical cancer, hemorrhagic
nephritis, hemodialysis
(d) hemorrhagic diathesis: alteration of the capillary wall, alteration of platelets, combined alterations
(f) hypersplenism:
(g) genetic causes: iron-refractory iron deficiency anemia
(h) mechanical fragmentation of RBCs: prosthetic valves
(i) endocrine diseases: hypothyroidism, pituitary insufficiency, autoimmune polyglandular syndromes
(j) autoimmune diseases: scleroderma, rheumatoid arthritis, lupus
(k) drugs: anticoagulants, antiaggregants, NSAIDs
(l) CHF, CKD.
Iron metabolism
̶ The iron metabolism involves absorption from the
duodenal enterocytes, usage in the erythroid
precursors, and storage and reutilization in the
hepatocytes and tissue macrophages
̶ Hepcidin is the key regulator of iron homeostasis,
as its synthesis is inhibited to facilitate iron efflux in
the circulation during increased erythropoiesis
̶ Hepcidin is produced in the liver and degrades the
ferroportin transport channel, reducing the ability
of macrophages to recycle the iron and thus iron
availability
̶ Nevertheless, hepcidin expression is increased by
stress and inflammation
̶ Exercise-induced changes in hepcidin and IL-6 are
similar in resistance and endurance training
Life 2021, 11(9), 987; https://doi.org/10.3390/life11090987
Iron metabolism in the cell
̶ (1)-iron uptake - Iron-bound transferrin (TF-Fe3+) and NTBI (nontransferrin-bound
iron) are taken up into the cell by the iron importers
DMT1 and ZIP14. STEAP3 is a ferrireductase which reduces Fe3+ to Fe2+,
which can then be imported.
̶ (2)-utilization - bioavailable and more soluble Fe2+ is used for various
biological processes– DNA replication, ROS production via
Fenton/Haber-Weiss (F/H-W) chemistry, mitochondrial bioenergetics, FeS
and heme biosynthesis, as well as a plethora of proteins which utilize
the metal to carry out their functions.
̶ (3)-storage - Excess Fe2+ iron is dangerous - it needs to be stored but, at
the same time, be readily available for use: ferritin proteins designated
the “ferritin cage” which stores the more inert, insoluble Fe3+ form of iron.
̶ (4)-export - If intracellular iron levels are saturated. This is achieved by
the iron exporter ferroportin (FPN). Once outside the cell the Fe2+ iron is
oxidized to Fe3+.
̶ (5)-Fe3+ iron is then bound to transferrin (Tf-Fe3+) and enters the
circulation to begin the cycle again.
Front. Mol. Biosci., 22 November 2019
Tissue macrophage metabolism
̶ A Splenic red pulp macrophages scavenge
defective erythrocytes for iron recycling.
̶ B Large peritoneal macrophages adapt their
bioenergetics after detection of different
microenvironmental factors, such as yeast,
oxLDL or IL-4, to facilitate the respiratory
burst.
̶ C Osteoclasts shift their cellular metabolism
when exposed to bone, promoting bone
resorptive activity.
̶ CI-III, complex I-III; FA, fatty acid; Gln, glutamine; IRP1, ironresponsive
element-binding protein; PKC, protein kinase C;
SO, superoxide; SZ, sealing zone. Solid lines: direct
relationships; dashed lines: indirect relationships. Purple
circles: cytokines; brown circles: bound holesterol/LDL/oxLDL;
red and orange stars: ROS, SO and H2O2 Cellular & Molecular Immunology volume 19, pages384–408 (2022)
Iron macropahge
̶ Iron is a growth factor for many microbes, and its availability is
critical for the course of infections
̶ Extracellular vesicles released by macrophages withdraw iron
from the blood, limiting iron access for bacteria and improving
outcomes from sepsis.
Nature Metabolism volume 5, pages10–12 (2023)
Assessing iron status
• Serum iron
 Measures ferric iron (Fe3+), subject
diurnal variation
• Total iron-binding capacity (TIBC)
 TIBC measures the amount of iron
binding sites available on serum
transferrin.
• Transferrin saturation (TSAT)
 Generally reflects iron available for
transport to the bone marrow
 Calculated as serum iron/TIBC x 100 =
TSAT
• Serum ferritin
 Ferritin in the liver reflects stored iron,
however, serum ferritin may not be as
robust in reflecting stored iron
 Acute phase reactant and will be
elevated in acute & chronic
inflammation
Nutrients 2015, 7(4), 2324-2344
Anemia of chronic disease
vs. iron deficiency anemia
Anemia of chronic disease Iron deficiency anemia
Serum Iron Reduced Reduced
Transferrin Reduced to normal Increased
Transferrin Saturation Reduced Reduced
Ferritin Normal to increased Reduced
Soluble transferrin receptor Normal Increased
Cytokine level Increased Normal
Hepcidin Increased Reduced
Bone marrow iron stores Normal to increased Reduced
Erythrocytes Normal, microcytes Microcytes
J Clin Invest. 2007;117(7):1755-1758. https://doi.org/10.1172/JCI32701.
Anemia of chronic disease
̶ common
̶  proliferation of RBC precursors
̶ deteriorated utilization of iron
̶ causes
̶ chronic microbial infection
̶ autoimmune disease
rheumatoid arthritis
̶ cancer
lung cancer
̶ systemic inflammation
̶ hepcidin stimulation (IL-6)
suppression of iron release from macrophages
 supplementation of RBC precursors
defence from bacteria that utilize iron (H. influenza)
structural similarity between hepcidin and defensins
̶ production of EPO is supressed
anemia
mild
normochromic and normocytic or hypochromic
microcytic
 serum ferritin,
 iron in macrophages
treatment
correction of the cause
possibly EPO
Anemia in RA
̶ mostly immune-driven,
̶ typical features that
include
̶ iron retention in the
reticuloendothelial system,
̶ impaired erythropoiesis,
̶ shortened erythrocyte half-life
and
̶ blunted erythropoietin activity
Nature Reviews Rheumatology volume 9, pages205–215 (2013)
Anemia in CKD
Anemia
of CKD
 Erythropoietin (EPO)
production/ Decreased
responsiveness to EPO
 GI absorption
of iron
Poor nutrition
Blood loss
(phlebotomy,
dialysis)
Inflammation/infectio
n
( hepcidin)
 Erythrocyte half-life
 Iron demands
Anemia may develop as eGFR declines
Anemia in CKD may:
• Result from inadequate erythropoietin synthesis.
• Develop early and worsen as CKD progresses.
• Occur earlier in people with diabetes.
• Involve inadequate iron intake, impaired iron absorption and chronic inflammation.
6.3
17.4
50.3
53.4
0
10
20
30
40
50
60
No CKD eGFR 30-59 eGFR 15-29 eGFR <15
Percent
Hemoglobin
Women < 12 g/dL
Men < 13 g/dL
Adapted from Stauffer PLoS ONE 2014
NHANES 2007-2010
Journal of the Formosan Medical Association, Volume 117, Issue 11, 2018
Question
Slide 12 of 68
A 66 year old patient with an eGFR of 20 mL/min/1.73m2
presents with symptoms of anemia. The patient has been
taking ferrous sulfate orally and currently has a diabetic
foot infection being treated with antibiotics. Which of the
following is likely contributing to the patient’s anemia?
a) Decrease in EPO production
b) Decrease in iron absorption in GI tract
c) Infection
d) All of the above
Answer
Slide 13 of 68
A 66 year old patient with an eGFR of 20 mL/min/1.73m2
presents with symptoms of anemia. The patient has been
taking ferrous sulfate orally and currently has a diabetic
foot infection being treated with antibiotics. Which of the
following is likely contributing to the patient’s anemia?
a) Decrease in EPO production
b) Decrease in iron absorption in GI tract
c) Infection
d) All of the above
Answer: D
Anemia in CKD is often multi-factorial.
The principal cause of anemia in CKD
is decreased EPO production but, in
this patient decreased iron absorption
in GI tract and current infection are
also contributors.
Anemia and Iron Deficiency in Heart Failure
̶ Iron deficiency is present in approximately 30% of heart failure
patients, usually classified as chronic normocytic anemia.
Functional iron deficiency occurs in about one third of patients
̶ a negative prognostic factor
Causes and Etiopathogenic Mechanisms of Iron
Deficiency and Anemia in Chronic Heart Failure
̶ iron deficiency,
̶ excessive secretion of cytokines,
̶ hemodilution by sodium retention,
̶ cardiac cachexia,
̶ the use of angiotensin II converting
enzyme inhibitor (ACEI) drugs,
̶ chronic kidney pathology associated with
decreased levels of EPO, which
characterizes the anemic cardio-renal
syndrome, in which failure of a single
organ (heart or kidneys) determines the
alteration of the function of the other
Life 2021, 11(9), 987; https://doi.org/10.3390/life11090987
Physiopathology of cardio-renal anemia
syndrome
̶ cardio-renal syndrome failure
of one organ (heart
or kidneys) determines a
change in the function of
another
GIT
̶ HF patients have an altered
intestinal morphology, permeability
and absorption
̶ HF patients with venous congestion
have reduced blood to the intestine,
causing intestinal hypoperfusion
and consequently nonocclusive
bowel ischemia, increased mucosal
permeability, bowel edema,
cachexia and altered composition of
mucosal bacteria
̶ Collectively, all of this might
culminate in the malabsorption of
micronutrients, including iron
HF therapy
̶ Therapeutical agents
used in CHF management
and their pathogenic
mechanisms.
̶ ARB, angiotensin receptor
blockers. ACE, angiotensinconverting
enzyme. AcSDKP,
N-Acetyl-Seryl-Aspartyl-Lysyl-
Proline.
Iron deficiency
Nature Reviews Cardiology volume 8, pages485–493 (2011)
Aplastic anemia
• chronic failure of hematopoiesis
• etiology
• idiopathic (65 %)
• chemicals
• benzene
• alkylation agents
• antimetabolites
• viral infection
• hepatitis, CMV, EBV
• radiation
• hereditary defects
• Fanconi anemia
• DNA reparation disorder
• defects of telomerase
Ústav patologické fyziologie LF MU63
Aplastic anemia
• pathogenesis
• extrinsic cause
• change of stem cells‘ antigens
• activation of Th1
• cytokines, destruction of progenitors
• up-regulation of proapoptotic genes
• immunosuppressive therapy
• intrinsic cause
• karyotype changes
• short telomeres
• morphology
• hypocellular bone marrow
• common infection, bleeding
• signs
• pancytopenia
• anaemia, petechia, infection
• reticulocytopenia
• treatment
• transplantation
64
Anemia in cancer
̶ Anemia occurs in
more than 50% of
cancer patients
̶ It is therefore
considered a
"paraneoplastic
symptom"
KLENER P. - Anémie u nádorových onemocnění a jejich léčba. Remedia 2011; 22.
Thank you for attention
Zápatí prezentace 66
Iron metabolism in the CNS
The role of iron in Parkinson's disease.
̶ Iron accumulation is found in the substantia nigra
(SN). With PD, divalent metal transporter 1 (DMT1)
expression is increased in the SN contributing to the
increased iron uptake into the cell.
̶ Iron also directly interacts with α-synuclein, which acts
as a ferrireductase converting Fe3+ to Fe2+.
̶ Furthermore, excess iron has been shown to promote
aggregation of α-synuclein by promoting posttranslational
modifications.
̶ Mitochondrial dysfunction is another key feature of PD
pathology. Iron overload promotes mitochondrial
fragmentation and disrupt mitochondrial fission.
Molecular Aspects of Medicine, Volume 75, 2020, 100867