Post on 15-Jan-2016
Anaemia treatment in CKD, ESRD, and kidney transplant recipients
Iain C Macdougall BSc, MD, FRCP
Consultant Nephrologist and Honorary Senior Lecturer
Renal Unit, King’s College
Hospital, London, UK
Outline of presentation
Erythropoiesis in 2009
ESA therapy
Target Hb
Iron management
Anaemia management in kidney transplantation
The future
Hb
(g
/dL
)
15
10
5
Declining GFR (mL/min)
Development of renal anaemia prior to the availability of EPO therapy
DialysisCKD stages 1–2 Stage
3 Stage
4 Stage
5
120–60 59–30 29–15 < 15
NHANES data
Papayannopoulou T, et al. In: Hoffman R, et al., ed. Hematology: Basic Principles and Practice. 4th ed. 2005;267-288.
SCF, GM-CSF, IL-3
SCF, IL-1, IL-3, IL-6, IL-11
PluripotentStem Cell
Burst-Forming Unit-Erythroid Cells (BFU-E)
Colony-FormingUnit-ErythroidCells (CFU-E)
Reticulocytes RBCsErythro-blasts
Proerythro-blasts
About 8 Days
Iron
Erythropoietin
Erythropoiesis in CKDErythropoiesis in CKD in 2009
Pro-inflammatory cytokines (IL-1, TNFα, IL-6, IFNγ)
EPO production
EPO
+ +
Iron
Fas Ag
Apoptosis
─
hepcidin Fe absorption Fe transport Fe availability(EPO-R, Tf, TfR, Ferriportin, DMT-1)
─
Erythropoiesis in CKD in 2009
Papayannopoulou T, et al. In: Hoffman R, et al., ed. Hematology: Basic Principles and Practice. 4th ed. 2005;267-288.
SCF, GM-CSF, IL-3
SCF, IL-1, IL-3, IL-6, IL-11
PluripotentStem Cell
Burst-Forming Unit-Erythroid Cells (BFU-E)
Colony-FormingUnit-ErythroidCells (CFU-E)
Reticulocytes RBCsErythro-blasts
Proerythro-blasts
About 8 Days
Iron
Erythropoietin
Anti-Anaemic therapies in CKD
Outline of presentation
Erythropoiesis in 2009
ESA therapy
Target Hb
Iron management
Anaemia management in kidney transplantation
The future
Development of recombinant human EPO
1977 - human EPO isolated from 2,500 litres of urine
(Miyake et al)
1983 - gene for human EPO isolated and cloned
(FK Lin et al)
1986 - first clinical report in dialysis patients
1990 - r-HuEPO licensed for use in Europe
Epoetin alfa (Eprex)
Epoetin beta (NeoRecormon)
Hb
(g
/dL
)
15
10
5
Declining GFR (mL/min)
Development of renal anaemia prior to the availability of EPO therapy
DialysisCKD stages 1–2 Stage
3 Stage
4 Stage
5
120–60 59–30 29–15 < 15
Winearls CG, et al. (Lancet 1986; 2: 1175-8)
Eschbach JW, et al. (N Engl J Med 1987; 316:73-8)
Macdougall IC, et al. (Lancet 1990; 335: 489-93)
Macdougall et al., Lancet 1990; 335: 489-493.
0 2 4 6 8 10 12
6
8
10
12
14
Time (months)
Hb
(g
/dl)
EPO
Macdougall et al., Lancet 1990; 335: 489-493.
Mean baseline Hb = 6.3g/dl
Hb increment > 5g/dl
Strategies for treating renal anaemia
15
10
5
Time or creatinine
Prevention
Dialysis
Earlier start
Higher target
1990
19941998
2002
Hb (g/dl)
Anaemia therapy in CKD
Initially, Epoetin alfa (Eprex, Erypo) – 1990
Epoetin beta (NeoRecormon) – 1990
Epoetin alfaEpoetin beta
Anaemia therapy in CKD
Initially, Epoetin alfa (Eprex, Erypo) – 1990
Epoetin beta (NeoRecormon) – 1990
2nd generation ESA:-Darbepoetin alfa (Aranesp) – 2001
Epoetin alfaEpoetin beta
First extra N-linked
chain
Second extra N-linked
chain
Darbepoetin alfa: a molecule with two more N-linked glycosylation chains than r-HuEPO
Third-generation ESAs
C.E.R.A. (MIRCERA)Methoxy polyethylene glycol epoetin beta
– licensed 2007
C.E.R.A.
Continuous Erythropoietin Receptor Activator
PEGylated Epoetin beta
CERA EPO
Epoetin delta (DYNEPOTM)
Biosimilar EPOs
First biosimilar epoetins licensed in Europe
– BinocritTM (Sandoz)
– RetacritTM (Hospira)
Epoetin alfa (Eprex)
Epoetin beta (NeoRecormon)
Darbepoetin alfa (Aranesp)
C.E.R.A. (MIRCERA)
Epoetin delta (Dynepo)
Biosimilar Epoetin alfa (Binocrit)
Biosimilar Epoetin zeta (Retacrit)
Current licensed ESAs in Europe
IV half-lives of ESA therapy
100
10
1
0.1
0.01
0 12 24 36 48 days
Epoetin (TIW)Plasma ESA (ng/ml)
*estimated values based on 6000 IU epoetin / week
Simulation of EPO kinetics for short-acting ESAs vs longer-acting ESAs*
100
10
1
0.1
0.01
0 12 24 36 48 days
Epoetin (TIW)
Darbepoetin (QW)Plasma ESA (ng/ml)
*estimated values based on 6000 IU epoetin / week
Simulation of EPO kinetics for short-acting ESAs vs longer-acting ESAs*
100
10
1
0.1
0.01
0 12 24 36 48 days
Epoetin (TIW)
Darbepoetin (QW)
C.E.R.A. (QM)
Plasma ESA (ng/ml)
*estimated values based on 6000 IU epoetin / week
Simulation of EPO kinetics for short-acting ESAs vs longer-acting ESAs*
ESAs
Short-acting
Medium-acting
Long-acting
Dosing frequency
x2 or x3 / week
x1/wk or x1/2wks
x1/2wks or x1/mth
Outline of presentation
Erythropoiesis in 2009
ESA therapy
Target Hb
Iron management
Anaemia management in kidney transplantation
The future
Ofsthun et al, Kidney Int 2003; 63: 1908-1914.
Hb predicts survival in observational studiesHD patients
Hb predicts survival in observational studiesND-CKD patients
Levin A. et al, Nephrol Dial Transplant 2006; 21: 370-377.
Months from Hg Result
Pro
ba
bili
ty o
f S
urv
iva
l
Survival of CKD Patients by Hemoglobin Level
0 3 6 9 12 15 18 21 24 27 30 33 36
0.70
0.75
0.80
0.85
0.90
0.95
1.00
Hemoglobin
>= 130 g/L
120-129 g/L
110-119 g/L
100-109 g/L
< 100 g/L Log-Rank Test: p =0.0001
US Normal Haematocrit Trial
Besarab A et al. N Engl J Med 339: 584-590, 1998.
Low-haematocrit group
Normal-haematocrit group
Pro
bab
ility
of
dea
th o
r M
I (%
)
Months after randomization
0 3 6 9 12 15 18 21 24 27 30
60
50
40
30
20
10
0
US Normal Haematocrit Trial- probability of death or first non-fatal MI
Besarab et al. NEJM 1998; 339: 584-90.
CREATE CHOIR
Primary endpointTime to first CV event (105 events)
Events: 58 vs 47HR=0.78 (0.53–1.14)Log rank test p=0.20
CHOIR Trial 125 vs 97 events;p < 0.03
Hb target ranges – the evidence
15
14
10
11
12
13
9
Hb
(g
/dl)
Sources:- – Lancet meta-analysis – K/DOQI Anemia Guidelines update
(evidence review by Boston Tufts University Evidence Rating Group)
Outline of presentation
Erythropoiesis in 2009
ESA therapy
Target Hb
Iron management
Anaemia management in kidney transplantation
The future
Why are CKD patients prone to develop iron deficiency?
Occult G-I losses
Peptic ulceration
Blood sampling
Dialyser losses
Concurrent meds.
– e.g. aspirin
Heparin on dialysis
INCREASED LOSSESREDUCED INTAKE
Poor appetite
Poor G-I absorption
Concurrent medication
– e.g. omeprazole
Food interactions
Iron metabolism
PLASMA
Iron stores
Ferritin
Serum iron/TIBC
TSAT
CHr% hypochromic RBC
Marrow stainable iron
Serum TfR
RBC ZPP
Minimum ranges:
Serum ferritin > 100 g/l
Hypochromic RBC < 10%
TSAT > 20%
Aim for :
Serum ferritin 200-500 g/l
Hypochromic RBC < 2.5%
TSAT 30-40%
Monitoring iron status
IV Iron Agents are Spheroid Particles with an IV Iron Agents are Spheroid Particles with an Iron Core and a Carbohydrate ShellIron Core and a Carbohydrate Shell
ironironoxyhydroxideoxyhydroxide
corecore
carbohydratecarbohydrateshellshell
DOPPS III: Type of IV Iron Prescribed in HD patientsP
ati
en
ts (
%)
DOPPS III data (2005-07), among prevalent cross-section of HD patients using IV iron.
2
99
62
99
100
9992
1
9
82 99
1
36
94
29
7 81
40
50
91 1 0.3 13 1 0.3 1
63
98
0
20
40
60
80
100
ANZ BE CA FR GE IT Jpn SP SW UK US
n = (393) (396) (333) (339) (419) (304) (566) (469) (449) (334) (1327)
- Sucrose
Fe-Oxide SaccharatePolymaltose Dextran
Chondroitin SO4
GluconateCideferronOther
Benefits of IV iron in CKD patients
IV iron can improve the anaemia of CKD even in the absence of ESA therapy
IV iron can significantly enhance the response to ESA therapy, even in iron-replete patients
Short-term
Anaphylactic reactions (iron dextran only; dextran Abs)
“Free iron” reactions (all IV iron preparations)
Potential dangers of IV iron ?
Long-term
Increased susceptibility to infection
Increased oxidative stress
Iron overload
Balance of benefits vs. risks of IV iron
Mortality risk
Oxidative
stress
Infection
risk
Anaphylaxis
Benefits of IV iron
Outline of presentation
Erythropoiesis in 2009
ESA therapy
Target Hb
Iron management
Anaemia management in kidney transplantation
The future
Y Vanrenterghem et al., For TRESAM, Am J Transplantation 2003
Hb < 12 g/dl : 28.4% Hb < 12 g/dl : 22.7%
Hb < 12 g/dl : 25.5% Hb < 12 g/dl : 24.4%
Overall 24.5 % were anaemic
n = 4263 - 76 centres, 16 countries
Prevalence of anaemia in European kidney transplant recipients
Hb < 11 g/dl Hb < 10 g/dl
Y. Vanrenterghem et al., for TRESAM, Am J Transplantation 2003.
Among 8.5% patients with severe anaemia, 18% were on EPO therapy
Prevalence of severe anaemia in Europe
Overall 8.5% with severe anaemia
Post-transplantation anaemia
Causes – iron deficiency – infections (CMV)– immunosuppresssive therapy– ACE-I / ARB therapy – impaired renal function ( EPO) – failing graft (pro-inflammatory cytokines)
ESA hyporesponsiveness in renal transplantation
Iron deficiency
Infection/inflammation
Underdialysis
Hyperparathyroidism
Aluminium toxicity Carnitine
deficiency PRCA
Blood loss
Haemolysis
B12/folate deficiency
Marrow disorders
Haemoglobinopathies
ACE inhibitors
Viral
(CMV, EBV, Parvovirus)
Malignancy
(e.g. lymphoma)
Immunosuppression
(Aza, MMF, SRL)
Outline of presentation
Erythropoiesis in 2009
ESA therapy
Target Hb
Iron management
Anaemia management in kidney transplantation
The future
Clin J Am Soc Nephrol, 2008
Hematide
EPO-mimetic peptide, now in Phase III clinical trials
Amino acid sequences completely unrelated to native EPO
Shows same functional / biological properties as EPO
What is different about Hematide?
Peptide-based (epoetin, darbepoetin, CERA – all protein-based)
Not genetically-engineered in cells (unlike epoetin, darbepoetin, CERA)
Manufactured by synthetic peptide chemical techniques
? More stable at room temperature
? less immunogenic
Does not cross-react with antibodies against EPO – should not cause PRCA; can be used to treat
Ab+PRCA
First ESA to be tested de novo once-monthly in CKD patients
Jak2Jak2P P
P P
EPO,rHuEPO
EPO-mimetic peptide
Darbepoetinalfa
membrane
C.E.R.A.Peg-rHuEPO
Signal Transduction
Survival, differentiation, proliferation, and maturation of RBC progenitors and precursors
Gene Activation
Jak2Jak2P P
P P
Jak2Jak2P P
P P
Jak2Jak2P P
P P
Anti-EPO antibodies do not neutralise Hematide
Anti-EPO Antibodies
58
Hematide in the Treatment of Antibody-Mediated Pure Red Cell Aplasia I C Macdougall et al, ASN 2007 (updated in 2008)
n = 13 13 13 11 11 10 9 8 7 8 6 7 7 6 6 7 6 6 6 6 6 6 6 6 6 5 6 6 5 4 3 2
(Data from three subjects were censored due to kidney transplantation)
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0000
10
20
30
40
50
60
BL 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32
Study Months
Per
ce
nt
Pa
tien
ts R
ec
eiv
ing
RB
C T
ran
sfu
sio
ns
D
uri
ng
Ea
ch
Stu
dy
Mo
nth
8.0
9.0
10.0
11.0
12.0
13.0
14.0
Me
an
(SD
) Hb
Co
nc
entra
tion
(g/d
L)
HIF stabilisers
HIF is the hypoxic sensor that upregulates EPO gene expression
HIF is broken down by a prolyl hydroxylase enzyme
An inhibitor of HIF hydroxylase has been synthesised (FibroGen)
It causes an increase in EPO levels, even in CKD patients
Upside
This enzyme inhibitor is orally-active
Downside
>100 other genes (e.g. VEGF) also turned on Rare development of severe liver toxicity (may be fatal)
New IV irons pending…….
2 new IV irons forthcoming:-– Ferumoxytol (US)
– Ferric carboxymaltose – FerinjectTM (Europe)
Advantages – ? safer
– no need for test dose – more rapid high-dose
bolus injection – main benefits in the pre-ESRD population
Ferric carboxymaltose (Ferinject)
Licensed in Europe
Stable iron complex
Low immunogenic potential – dextran-free
Minimal detectable and releasable free iron
Ferric hydroxide molecules Ribbon-like carboxymaltose
No test dose required
Rapid administration
– 200mg push
– 500mg in 6 mins
– 1000mg infusion in 15 mins
Ganz, 2006.
Ganz, 2006.
Iron transport
Savino R, Ciliberto G. Cell Death Differ. 2004;11 Suppl 1:S2-4.
EPO: an all-purpose tissue-protective agent?
EPO therapy: beyond Hb
Mediated via the anti-apoptotic action of EPO on non-erythroid cells
Relevant for acute cardiac, renal, and cerebral ischaemia
? Therapeutic benefit in :-– Acute MI
– Acute stroke– Reperfusion injury
– Post-transplantation
Conclusions
Our understanding of erythropoiesis in 2009 has advanced to include the role of hepcidin and pro-inflammatory cytokines
Until further evidence is forthcoming, we should generally target an Hb of 11–12 g/dl
Even in 2009, there is still a need for additional grade A level evidence in the management of anaemia in CKD
Several new ESAs and IV iron preparations are appearing, and the non-erythropoietic effects of ESAs are being explored