Annual Meeting
Curricular Track I—The Role of the Immune System in Disease Pathophysiology: Implications for Pharmacotherapy Activity No. 0217-0000-11-066-L01-P (Knowledge-Based Activity) Monday, October 17 9:15 a.m.–10:45 a.m. Convention Center: Spirit of Pittsburgh Ballroom A Moderator: Tien M.H. Ng, Pharm.D., FCCP, BCPS Associate Professor, Department of Pharmacy Practice, University of Southern California, Los Angeles, California Agenda 9:15 a.m. Overview of the Immune System and Application to Disease
Pathophysiology Val R. Adams, Pharm.D., FCCP, BCOP Associate Professor of Pharmacy Practice and Science, University of Kentucky College of Pharmacy, Lexington, Kentucky
9:45 a.m. Immunotherapy in Neurologic Disease Melody Ryan, Pharm.D., MPH, FCCP, BCPS, CGP Associate Professor, University of Kentucky, Lexington, Kentucky
10:15 a.m. PRO/CON Debate: Targeting Inflammation and the Prevention and Treatment of Cardiovascular Disease Sheila L. Stadler, Pharm.D., BCPS Clinical Pharmacy Specialist, Kaiser Permanente of Colorado, Aurora, Colorado; Clinical Assistant Professor, University of Colorado–Denver School of Pharmacy, Aurora, Colorado and Craig D. Williams, Pharm.D. Clinical Associate Professor, Department of Pharmacy Practice College of Pharmacy, Oregon Health & Science University, Portland, Oregon
Faculty Conflict of Interest Disclosures Val R. Adams: no conflicts to disclose Melody Ryan: no conflicts to disclose Sheila L. Stadler: no conflicts to disclose Craig D. Williams: no conflicts to disclose
Annual Meeting
Learning Objectives
1. Describe the key components of the innate immune system and acquired immune response. 2. Identify how components of the immune system can contribute to pathophysiologic processes of
disease. 3. Describe the current understanding of the pathophysiologic mechanisms of immune-mediated
neurologic disease. 4. Evaluate the evidence and controversies for the use of immunomodulating therapy in the
treatment of demyelinating neuropathies. 5. Discuss the evidence for inflammatory markers and their association with various cardiovascular
diseases. 6. Compare and contrast the evidence for treatment modalities targeting inflammation and their
effect on clinical outcomes.
Self-Assessment Questions Self-assessment questions are available online at www.accp.com/am
Val R. Adams, Pharm.D., FCCP, BCOPAssociate ProfessorAssociate ProfessorUniversity of Kentucky
Overview of the Immune System and Application to Disease PathophysiologyDisease Pathophysiology
Conflicts of InterestConflicts of Interest
I have no real or perceived conflict of interest to reportp
The Immune SystemAn Army Within A crucial component for survival A crucial component for survival Well coordinated system primarily focused on
killing foreign invading predators (but it does g g g p (much more)
If it becomes dysfunctional due to ycommunication errors, lack of soldiers, etc. the risk of damaging the nation goes up drastically
An overview of the ranks, their charges, and communications, and will be reviewed.
Objectives
1 Describe the key components of the1. Describe the key components of the innate immune system and acquired immune response.p
2 Identify how components of the immune2. Identify how components of the immune system can contribute to pathophysiologic processes of disease.pathophysiologic processes of disease.
Immune System
Protection against pathogens Allergic reactions to innocuous substances Organ graft rejection Organ graft rejection Autoimmunity Tumor immunity/surveillance Tumor immunity/surveillance Others
Atherosclerosis Atherosclerosis Neuronal protection Angiogenesis Lipid metabolism
Pathogen Response
Physical –biochemical –mechanical
Innate Response
Adaptive Response
barriersp p
Time
Innate Immunity:Soldier on Patrol (Phagocytes)
Macrophages First on the scene, resident in most tissues (skin, mucosal
surfaces vessels)surfaces, vessels) Recognize bacteria, fungus, virus via receptor(s) that recognize
common pathogen surface constituents (activate the macrophage)macrophage)
Pathogen is engulfed and degraded Communication to comrades via cytokines/chemokines Recruitment of other cells (neutrophils) and initiation of
inflammation
Janeway’s immunobiology 7th ed Garland Science
Innate Immunity: MØ Recognize Patterns
Scanvenger: e.g. SR-A or CD36
NK-like C-type lectin-like: e.g. Dectin-1
GPI anchored:Integrin e g CR3GPI-anchored:
e.g. CD14e.g. CR3 (CD18/11b
Ig Superfamily: e.g. FcR
Toll-like receptorse.g. TLR2, TLR4
g
Annu. Rev. Immunol. 2005. 23:901–44
Innate Immunity:MØ Activation Response
TNF- – Vascular effects - ↑ permeabilityTNF- – Vascular effects - ↑ permeability allowing cell, Ig, compliment access - ↑ lymph drainage, fever, shock
IL 1 V l ff t ti t L h
IL-6 – Lymph activation, ↑ Ig production,
IL-1 – Vascular effect, activates Lymphs, local tissue destruction, fever, ↑ IL-6
fever, acute phase protein production
IL-8 (CXCL8) – Chemotactic factor to attract neutrophils, basophils, and T-cells
IL-12 - Activates NK cells, induces differentiation of CD4 cells to TH1
a ac eu op s, basop s, a d ce sto site
Activated MØ engulfs pathogen andSecretes cytokines/chemokines
differentiation of CD4 cells to TH1
Janeway’s immunobiology 7th ed Garland Science
Innate Immunity: Complement
Classical Activation
Antigen: Antibody
Lectin ActivationLectin binding to Pathogen surface
Alternative ActivationCompliment bindingto pathogen surface
Activation of the Compliment Cascade
C3a, C5a C3b (opsonization) Formation of a membraneC3a, C5aInflammatory mediatorRecruitment of phagocytes
C3b (opsonization)Binds to complementReceptors on Phagocytes – leads toR l f th
Formation of a membraneAttach complex (MAC)Creates holes in cell Wall leading to death.
Removal of pathogens
Janeway’s immunobiology 7th ed Garland Science
Innate Immunity:Next to Arrive: Neutrophils Neutrophils (inflammatory cell responder)
Attracted to the infection via chemokines (e.g. IL-8)V l ff t ( t f i fl ti ) dil ti Vascular effects (part of inflammation): vasodilation (slow blood flow), increase endothelial adhesion and molecule expression; allowing neutrophils to adhere to the vessel at the infection site, then exit the circulation into the tissue (diapedesis), where they can identify pathogens via receptors (similar to MØ) andpathogens via receptors (similar to MØ) and phagocytize and destroy them.
Short lived and usually die after phagocytosis
Janeway’s immunobiology 7th ed Garland Science
Inflammatory Response
Normal Vessel w/ Neutrophilo a esse / eut op
Inflamed vessel w/ NeutrophilsExtravasating into the tissueExtravasating into the tissue
Innate Immunity:Natural Killer Cells Lymphoid cells that circulate in blood and are Lymphoid cells that circulate in blood and are
activated by IL-12 and IFN- and IFN- IL-12 synergistically w/ TNF- stimulate NK IL-12 synergistically w/ TNF- stimulate NK
cells to make and secrete INF- Recognize cells through (activating & Recognize cells through (activating &
inhibiting) surface receptors to help differentiate normal cells versusdifferentiate normal cells versus abnormal/infected target cells
Release cytotoxic granules that kill target cells Release cytotoxic granules that kill target cells
Innate Immunity: Inflammation
Ø Cytokines release initiated by MØ – then expanded Lipid inflammatory mediators: prostaglandins,
l k t i d l t l t ti ti f tleukotrienes, and platelet-activating factor are enzymatically produced by MØ 3 essential roles 3 essential roles Augment killing by front line cells
I d l l bl d l tti t t i f ti Induce local blood clotting to prevent infectious spread to the bloodPromote tiss e repair and healing Promote tissue repair and healing
Inflammatory Response
Activated monocytes differentiate into MØ d d d iti ll d
Inflamed vessel w/ MonocytesExtravasating into the tissue
MØs and dendritic cells and canbecome antigen presenting cells (APCs),which bridge the innate and adaptiveImmune systemg y
Antigen Presentation
Professional APCs Macrophages, dendritic cells, B cells
Present antigens in context of MHC molecules MHC – I: presents to CD8+ T cells
Expressed on all nucleated cells Present antigens from intracellular pathogens (virus) Present antigens from intracellular pathogens (virus)
MHCII—presents to CD4+ T cells Expressed mostly by lymphoid cells (APCs) Present antigens from extracellular pathogens (Bacteria)
Cell Mediated Immunity
APC
TrIL-10IL-1
Th B-cellIL-2
IL-10
IL-4, IL-5, IL-6
Tc NK
CytokinesIL-2 IL-8
M
IL 1 TNF
PMN
Antibody
IL-1, TNF-
All about the T-cell
CTLKill
TH
TH1 Stimulates MØProd. IL-2, INF-
CD8 + TcellMHC1 and antigen CD4 + Tcell
MHC2 and antigen
CD28B7
TH2
Stimulate B-cell (IL-4, IL-5) differentiation to
APCantigen differentiation to
plasma cells
Virally InfectedTH17
Stimulate Endothelial cells recruit PMNs early in adaptive Not pictured: T reg which suppressphaseThe immune system (IL-10)
T-cell activation/inhibition
CD28 (+)CD28 (+)B7B7
CD137CD137--LL CD137 (+)CD137 (+)
TT--CellCellSignal 2Signal 2 ( )( )
TCRTCRMHCMHC--AgAgSignal 1Signal 1
Signal 2Signal 2
CTLACTLA--4 (4 (--))B7B7
PDPD 11 LL PDPD 11 (( ))
Antigen Antigen Presenting Presenting
CellCell PDPD--11--LL PDPD--11 ((--))
CD40CD40 CD40CD40--L (+)L (+)
CellCell
Ag = Antigen; CTLA-4: Cytotoxic T-lymphocyte associated antigen 4; L = ligand; MHC = major histocompatibility complex; TCR = T-cell receptor; PD-1 = Program death 1. Seetharamu et al. Expert Rev Anticancer Ther. 2009;9:839-849.
T-cell signal transduction
APC
CD3CD4/CD8
Lck P ZAP-70
T cell
PP
P
Ca++ dependentCalcineurin
DAGPKC path
RAS, ERKJNK path
NFATNF-kBAP-1
B-cell Activation, Proliferation,ffand Differentiation
TH2 IL-4, IL-5, IL-6
CD40L
CD40 IL-4
B
B
B PlasmaCell
B
Antigen B
B
B
Surface IgB
Proliferation
Differentiation andAntibody Production
Proliferation
Antibody Q tit ti RQuantitative Response
Antibody MOA
IgG1IgG1
ADCC Complement ADCC
Complement
Bacteria
Complement
FCReceptorReceptor
Macrophage
Host Defense
Innate -Immediate0-4 hours
Infection recognized by preformed non-specific elements and effectors
DefeatPathogen
Innate –Early
Pathogen recognized by MØ through
Inflammation, recruitment and activation of effector
DefeatPathogen
4-96 hours microbial molecules cells
Ad tiInnate immune effector
ll ti t dAntigen recognition by B
d T ll ll D f tAdaptive Response 96 hours
cells activated, inflammation–
Dendritic cells present antigen
and T cells – cell expansion, differentiation, and activation of effector
functions
DefeatPathogen
g
When Things Go Wrong
Antigen Normal InappropriateAntigen NormalResponse
Inappropriate Response
Infectious Host Defense Recurrent/infectionInfectiousPathogen
Host Defense Recurrent/infection
Innocuous Allergy No responseSubstance
gy p
Grafted Organ Rejection Acceptance
Tumor Tumor Immunity Cancer
Normal No response AutoimmunityTissue/Organ
p y
The Army WithinThe Army Within 10,000 foot overview
Immunotherapy in Neurologic DiseaseDiseaseMelody Ryan, Pharm.D., MPHUniversity of Kentucky
Conflicts of Interest
Melody Ryan – nothing to declareMelody Ryan nothing to declare
Objectives
Describe the current understanding of the Describe the current understanding of the pathophysiologic mechanisms of immune-mediated neurologic diseaseg
Evaluate the evidence and controversies for the use of immunomodulating therapy in thethe use of immunomodulating therapy in the treatment of multiple sclerosis
Pathophysiology of MS
c 1995 c 2011c. 1995
It is an autoimmune disease
c. 2011
Inflammatory component Responsible for relapses
Something bad happens to the myelin
p p
Neurodegenerative component
R ibl f di bilit Responsible for disability
T Cells Adhesion molecule (α4β1-integrin)
on T cells allows binding to ICAM-1 gand VCAM-1 on vascular endothelial cells
T cell transmigrates through the cells and breaches the blood-brain barrier
T cell re-activated by an APC Activated T cell enters the Activated T cell enters the
parenchyma with help of matrix metalloproteinases 2 and 9e a op o e ases a d 9
Walter S, Fassbender K. Cell Physiol Biochem 2010;25:49-56.
Th17 Cells
IL-6 produced by activated T cells and IL 6, produced by activated T cells and macrophages, is important for generation of Th17 cells
Th17 cells produce IL-6, IL-17, IL-21, IL-22, and tumor necrosis factor-α (TNF-α)and tumor necrosis factor α (TNF α)
Codarri L, et al. Curr Opin Neurol 2010;23:205-11.
Beta Interferons
Suppress proliferation and migration of the T cells, particularly Th17 cells
Decreases antigen presentation by MHC g p yclass II molecules
Decreases integrin to prevent T cell migrationg p g Reduces matrix metalloproteinase 9 to
stabilize the blood-brain barrier Inhibit inflammatory cytokines increase anti-
inflammatory cytokinesinflammatory cytokines
Aktas O, et al. Trends Neurosci 2010;33:140-52.
Merson TD, et al. Neuromol Med 2010;17:99-132.Graber J, et al. Clin Neurol Neurosurg 2010;112:583-91.
Beta InterferonsLong-term Efficacy All forms effective against placebo All forms effective against placebo 16 years worth of data with interferon β-1b
Sustained 40% reduction in relapse rate and Sustained 40% reduction in relapse rate and slower rate of disease progression in patients taking continuously compared to placebo ortaking continuously compared to placebo or short-term use of interferon β-1b
Caveat: sustained reduction in relapse rate Caveat: sustained reduction in relapse rate not seen for IM interferon β-1a, but those treated earlier had better long-term outcomestreated earlier had better long term outcomes
Freedman MS. Neurology. 2011;76(1 Suppl 1):S26.Reder AT, et al. Neurology. 2010;74:1877.
Beta InterferonsControversy Neutralizing antibodies Neutralizing antibodies Develop in up to 44% of patients on β interferons Least frequent in lowest dose and lowest Least frequent in lowest dose and lowest
frequency administered β interferons If persistent, higher relapse rateg With time, may disappear Presence correlates with reduction in MxA
induction assay which also predicts relapse rates
Goodin DS, et al. Neurology 2007;68:997.Polman CH, et al. Lancet Neurol 2010;9:740.
Glatiramer Acetate
Suppress proliferation and migration of the T Suppress proliferation and migration of the T cells
Induces apoptosis of T cells Induces apoptosis of T cells Induces a shift from Th1 to Th2 cells
Aktas O, et al. Trends Neurosci 2010;33:140-52.
Glatiramer AcetateLong-term Efficacy Approximately 12 years of follow-up data Approximately 12 years of follow up data 80% reduction in relapse rate compared to
baseline databaseline data Disability scores also improved/remained
stable in patients continuously treatedstable in patients continuously treated compared to those withdrawn
Freedman MS. Neurology. 2011;76(1 Suppl 1):S26.
ControversyBest TreatmentInterferon vs InterferonInterferon vs. InterferonTrial Design Results
EVIDENCE INF β-1a 44 μg SQ 3x/wk vs. INF β-1a 30 μg IM 1x/wk; 24 weeks
Decreased relapse rate and active lesions on MRI with INF β-1a 44 μg SQ 3x/wk
INCOMIN INF β-1b 250 μg SQ QOD vs. INF β-1a 30 μg IM 1x/wk; 2 years
Decreased relapses and active lesions on MRI with INF β-1b 250 μg SQ QOD
Cl l INF β 1 30 IM 1 / k N diff bClanet, et al. INF β-1a 30 μg IM 1x/wk vs. INF β-1a 60 μg IM 1x/wk; 36months
No difference between treatments in disability or rate of progression
Panitch H, et al. Neurology 2002;59:1496-506.Durelli L, et al. Lancet 2002;359:1453-60.Clanet M, et al. Neurology 2002;59:1507-17.
ControversyBest TreatmentInterferon vs Glatiramer AcetateInterferon vs. Glatiramer AcetateTrial Design Results
BEYOND INF β-1b 250 μg SQ QOD vs. INF β-1b 500 μg SQ QOD vs. glatiramer acetate 20 mg QD; 2
No difference
2 yearsREGARD INF β-1a 44 μg SQ 3x/wk vs.
glatiramer acetate 20 mg QD; 96 weeks
No difference
96 weeks BECOME INF β-1b 250 μg SQ QOD vs.
glatiramer acetate 20 mg QD; 2 years; MRI study
No difference
2 years; MRI study
O’Connor P, et al. Lancet Neurol 2009;8:889-97.Mikol DD, et al. Lancet Neurol 2008;7:903-14.Cadavid D, et al. Neurology 2009;72:1976-983.
Check-in Question 1
Which is the best first-line treatment for MS?Which is the best first line treatment for MS?a. Interferon β-1a SQ 3x/weekb Interferon β 1b SQ QODb. Interferon β-1b SQ QODc. Glatiramer acetate 20 mg QDd. One of these is not better than the others
Mitoxantrone
Eliminates and deactivates monocytes and Eliminates and deactivates monocytes and macrophages
Inhibits T cell proliferation and migration Inhibits T cell proliferation and migration Inhibits B cell activation
C d t l b d d b f Compared to placebo, decreased number of exacerbations and improved MRI parameters
Aktas O, et al. Trends Neurosci 2010;33:140-52.Hartung HP, et al. Lancet 2002;360:2018.Coyle PK. Am J Manag Care 2010;16(6 Suppl):S164.
Mitoxantrone - Controversy
Cardiotoxicity Cardiotoxicity Dose-limiting to 140 mg/m2/lifetime May not be dose-related May not be dose related May have late-onset New FDA guideline for LVEF evaluation prior to New FDA guideline for LVEF evaluation prior to
each dose
Kingwell E, et al. Neurology 2010;74:1822-6.www.fda.gov
Check-in Question 2
Why is there a lifetime maximum dose forWhy is there a lifetime maximum dose for mitoxantrone?a. There is a risk of leukemiab. There is a permanent discoloration of
the sclerac. There is a risk of cardiotoxicityd. There is a risk of allergic reactiong
Natalizumab Humanized monoclonal IgG4-antibody Binds to α4β1-integrin so the T cell cannot Binds to α4β1-integrin so the T cell cannot
bind Prevents the migration of the T cell into the Prevents the migration of the T cell into the
CNSReduced relapse rates by 68% (0 23/y v Reduced relapse rates by 68% (0.23/y v. 0.73/y)Reduced disability progression by 42% over Reduced disability progression by 42% over 2 yearsR d d l i MRI b 83% Reduced new lesions on MRI by 83%
Coyle PK. Am J Manag Care 2010;16:S164-70.Polman CH, et al. N Engl J Med 2006;354:899-910.
Natalizumab - Antibodies
9% of patients develop antibodies at some 9% of patients develop antibodies at some point during treatment; 6% have persistent antibodies
82% with persistent antibodies develop them within the first 12 weeks of therapywithin the first 12 weeks of therapy
Causes decreased efficacy
Foley J. Am J Manag Care 2010;16:S178-83.
Natalizumab – Progressive Multifocal Leukoencephalopthy Opportunistic infection caused by reactivation Opportunistic infection caused by reactivation
of the JC DNA virus 50-86% of adults have antibodies to JCV 50 86% of adults have antibodies to JCV
Rapid progression and often causes death or severe disabilitysevere disability
Shortly after marketing, 3 cases reported and natalizumab was suspendednatalizumab was suspended
Re-introduced in 2006 with a restricted distribution and extensive monitoring programdistribution and extensive monitoring program
Clifford DB, et al. Lancet Neurol 2010;9:438-46.Miravalle A, Corboy JR. Neurol Clin Pract 2010:75(Suppl 1):S22-7.
PML after Re-introduction
Exposure of 65 000 MS patients with 28 new Exposure of 65,000 MS patients with 28 new cases of PML
Reporting rate = 1-2/month Reporting rate = 1-2/month Risk is proportional to exposure duration
S t b h i l t Symptoms: neurobehavioral, motor, language, cognitive, or vision changes, seizures hemiparesis tremorseizures, hemiparesis, tremor
Clifford DB, et al. Lancet Neurol 2010;9:438-46.
Treatment of PML
Withdrawal of natalizumab Withdrawal of natalizumab Aggressive immune reconstitution Plasma exchange Plasma exchange Immunoabsorption
Immune reconstitution inflammatory Immune reconstitution inflammatory syndrome High dose steroids High-dose steroids
Only 8 fatalities
Clifford DB, et al. Lancet Neurol 2010;9:438-46.
Sphingosine 1-phosphate
Sphingolipids are structural components of cell membranes
Sphingomyelin is metabolized to sphingosine 1-phosphate (S1P)
There are 5 receptors for S1P S1PR1-3 are widespread in CNS, vascular, and
immune systems S1P4 is in lymphoid tissue S1P5 is on natural killer cells and in oligodendrocytes
Hla T, Brinkmann V. Neurology 2011;76(suppl 3):S3-8.
Sphingosine 1-phosphate
S1P and S1PR1 controls entry and exit of naïve B d T ll i t th l h ti tB and T cells into the lymphatic systems
S1P regulates heart rate, vascular tone, and bl d d h ff tblood pressure and may have effects on pulmonary functionS1P promotes the survival of oligodendrocytes S1P promotes the survival of oligodendrocytes and oligodendrocyte precursor cells (OPC) and OPC differentiationOPC differentiation
S1P is involved with neurite extension and retraction
Hla T, Brinkmann V. Neurology 2011;76(suppl 3):S3-8.Soliven V, et al. Neurology 2011;76(suppl 3):S9-14.
Fingolimod S1PR modulator
Binds to all S1PR except S1PR Binds to all S1PR except S1PR2
Prevents the exit of naïve T cells and central memory T cells (TCM) from the lymphoidmemory T cells (TCM) from the lymphoid tissues
TCM include Th17 cells TCM include Th17 cells Increases the number of progenitor and mature
oligodendrocytes and protects them from celloligodendrocytes and protects them from cell deathIncreases brain derived neurotrophic factor Increases brain-derived neurotrophic factor
Chun J, Hartung HP. Clin Neuropharm 2010;33:91-101.
Fingolimod - Efficacy
Study n Relapse Rate Relapse-free New or Enlarged MRI Lesions (mean)
Fingolimod 1033 F 0 18/ F 74 7% F 2 5 P 9 8Fingolimod v. Placebo; 2-year study
1033 F=0.18/yP=0.40/y
F=74.7%P=45.6%
F=2.5 P=9.8
Fingolimod v. Interferon β-1a IM
1153 F=0.16/yI=0 33/y
F=82.6% I=69 3%
F=1.7 I=2.6Interferon β-1a IM Qweek; 1-year study
I=0.33/y I=69.3%
Kappos L, et al. N Eng J Med 2010;362:387-401.Cohen JA, et al. N Eng J Med 2010;362:402-15.
Check-in Question 3
SP is started on fingolimod She has a CBC 1SP is started on fingolimod. She has a CBC 1 week after beginning therapy. What do you expect the results to show?pa. Increased WBCb. Decreased WBCc. Increased plateletsd. Decreased plateletspe. No change
Controversy -Treatment Escalation vs. Induction Escalation algorithms begin with the safest Escalation algorithms begin with the safest
treatments and move on to more aggressive therapies only in the event of treatment p yfailure
Induction algorithms concentrate all Induction algorithms concentrate all therapeutic efforts on the early phases of the disease, which ultimately defines prognosis , y p g
Edan G, et al. J Neurol Neurosurg Psychiatry 2011.Boggild M. J Neurolog Sci 2009;277(Suppl 1):S50-4.
Conclusion
Much is now known but much is left to learn Much is now known, but much is left to learn about the role of the immune system in MS
Several therapies are now available for Several therapies are now available for treatment of MS; however, there is no consensus on the best therapyconsensus on the best therapy
There is controversy regarding the place in therapy of all currently available medicinestherapy of all currently available medicines
PRO: Targeting inflammationPRO: Targeting inflammation should be a goal for the
prevention and treatment of cardiovascular diseasecardiovascular disease
Monday, October 17, 2011y, ,Sheila L. Stadler, Pharm.D., BCPS (AQ Cardiology) Clinical Pharmacy Specialist, Kaiser Permanente of
Colorado, Aurora, Colorado; Clinical Assistant Professor University of Colorado Denver School ofProfessor, University of Colorado–Denver School of
Pharmacy, Aurora, Colorado
ObjectivesObjectives
• Discuss the evidence for inflammatoryDiscuss the evidence for inflammatory markers and their association with various cardiovascular diseasescardiovascular diseases
• Compare and contrast the evidence for treatment modalities targetingtreatment modalities targeting inflammation and their effect on clinical outcomesoutcomes
BackgroundBackground
• Cardiovascular disease (CVD) is abnormalCardiovascular disease (CVD) is abnormal function of the heart and blood vessels
• CVD is the leading cause of death world• CVD is the leading cause of death world wide
NEJM, 2005
JACC, 2009
Inflammation in Early AtherosclerosisInflammation in Early Atherosclerosis
• Triggers of atherosclerosis can initiateTriggers of atherosclerosis can initiate expression of adhesion molecules by endothelial cells which allows attachment of leukocytes to arterial wall
• Likely culprit: vascular cell adhesion y pmolecule-1 (VCAM-1)
• Proinflammatory cytokines provide a y y pchemotactic stimulus to adherent leukocytes to migrate into the intima
Macrophage and InflammationMacrophage and Inflammation
• Monocytes transform into macrophagesMonocytes transform into macrophages, express scavenger receptors, engulf lipid particles and become foam cellsparticles, and become foam cells
• Macrophages multiply and release proinflammatory growth factors andproinflammatory growth factors and cytokines
T-cells and Plaque InflammationT cells and Plaque Inflammation• Antigens presented by macrophages andAntigens presented by macrophages and
dendritic cells trigger the activation of antigen-specific T cells in the artery
• Activated T cells produce Th1 cytokines (e.g., interferon-γ), which activate macrophages and
l ll l di t i fl tivascular cells, leading to inflammation• Regulatory T cells modulate the process by
secreting antiinflammatory cytokinessecreting antiinflammatory cytokines (interleukin-10 and transforming growth factor β)β)
Cytokine CascadeCytokine Cascade
• Activated immune cells in the plaqueActivated immune cells in the plaque produce inflammatory cytokines (interferon-γ, interleukin-1, and tumor ( γnecrosis factor), which induce the production of interleukin-6
• Interleukin-6 stimulates the production of large amounts of acute-phase reactants, i l di C ti t i (CRP)including C-reactive protein (CRP), serum amyloid A, and fibrinogen
Lipoprotein-associated h h li A (L PLA )phospholipase A2 (Lp-PLA2)
• Lp-PLA2 is an inflammatory biomarker and is directly related to propensity of plaqueis directly related to propensity of plaque rupture
• Lp PLA is an enzyme that hydrolyzes• Lp-PLA2 is an enzyme that hydrolyzes oxidized phospholipids and releases lysophosphotidylcholinelysophosphotidylcholine
Lp-PLA2 in Unstable PlaqueLp PLA2 in Unstable Plaque
Journal of Clinical Lipidology. 2009;3:85-93.
So inflammation is a key factor inSo….inflammation is a key factor in atherosclerosis.
Does that mean we should target i fl ti f th ti dinflammation for the prevention and treatment of CVD?
Biomarkers of Inflammationd f di tiproposed for diagnostic use
• VCAM-1• IL-6• hsCRP• Lp-PLA2
hsCRP for Risk PredictionhsCRP for Risk Prediction
• 40-50% of those at intermediate risk according to ATP III ere reclassified baccording to ATP III were reclassified by the addition of hsCRP and family history to clinically relevant higher or lower riskclinically relevant higher or lower risk groups
JAMA. 2007;297:611-619.
hsCRP as a Potential Therapeutic Goal
• Clinical outcomes best among statin-treated patients who not only p yachieved LDL-C <70 mg/dL, but also achieved hsCRP <2 mg/Lg
• 28% lower chance of recurrent MI or vascular deathdeath
J Am Coll Cardiol. 2005;45:1644-8. Circulation. 2006;114:281-288.
hsCRP to Target TherapyhsCRP to Target Therapy
• JUPITER trial enrolled 17 802 without CVD withJUPITER trial enrolled 17,802 without CVD with LDL-C < 130 mg/dL and hsCRP ≥2 mg/L
• Randomized to rosuvastatin 20 mg or placeboRandomized to rosuvastatin 20 mg or placebo• 44% reduction in primary endpoint of all vascular
events
N Engl J Med 2008;359:2195-207.
Lp-PLA2 as a Therapeutic TargetLp PLA2 as a Therapeutic Target
• Darapladib is a direct inhibitor of Lp-PLA2Darapladib is a direct inhibitor of Lp PLA2
• Shown to prevent necrotic expansion of human coronary atherosclerotic plaquehuman coronary atherosclerotic plaque
• Phase III study currently recruiting: The t bili ti f l i d l dibstabilization of plaques using darapladib-
thrombolysis in myocardial infarction 52 t i l (SOLID TIMI 52)trial (SOLID-TIMI 52)
ConclusionConclusion• There is evidence that numerousThere is evidence that numerous
inflammatory markers are associated with CVD
• Strongest evidence lies with utilizing hsCRPfor risk prediction, to identify patients who
b fit f t ti d t ti lmay benefit from statins, and as a potential dual goal along with LDL-C
• Lp PLA may provide information about• Lp-PLA2 may provide information about plaque inflammation and stability and as a direct target for treatmentg
RebuttalRebuttal
1 Proof of concept1. Proof of concept2. Prospective validation3 Incremental value3. Incremental value4. Clinical utility5 Clinical outcomes5. Clinical outcomes6. Cost-effectiveness
Circulation. 2009;119:2408-2416.
Cost-Effectiveness for hsCRPCost Effectiveness for hsCRP• 5 year NNT for JUPITER was 25 for5 year NNT for JUPITER was 25 for
primary trial end point and 32 for “hard” end point of MI, stroke, or death.end point of MI, stroke, or death.
• Comparable 5 year NNT values between 86-140 have been reported as cost-86-140 have been reported as cost-effective for treatment of hypertension
• Recommendations for measurement of CRP• Class IIa
– In men ≥ 50 years or women ≥ 60 years with LDL-C < 130 mg/dL; not on lipid-lowering, hormone replacement or immunosuppressant therapy; withoutreplacement, or immunosuppressant therapy; without CHD, diabetes, chronic kidney disease, severe inflammatory conditions, or contraindications to statins measurement of CRP can be useful in thestatins, measurement of CRP can be useful in the selection of patients for statin therapy.
– Level of Evidence: B
Circulation. 2010;122:2748 –2764.
• Recommendations for measurement of CRP• Class IIb
– In asymptomatic intermediate-risk men < 50 years of age or women <60 years of age measurement ofage or women <60 years of age, measurement of CRP may be reasonable for cardiovascular risk assessment
– Level of Evidence: B
Circulation. 2010;122:2748 –2764.
CVD continues to be the leading cause ofCVD continues to be the leading cause of death world wide
Even with treating to patients to goal for traditional risk factors, there is still residual risk
We need to explore beyond the traditionalWe need to explore beyond the traditional risk factors and target inflammation for the prevention and treatment of CVDprevention and treatment of CVD
ACCP Pro CoACCP Pro-Co
Targeting inflammation should NOTargeting inflammation should NOtreatment of card
Craig D. WilliClinical Associate ProfessPractice College of PharmacPractice College of Pharmac
University, Po
on debate 2011:on debate 2011:
OT be a goal for the prevention andOT be a goal for the prevention and diovascular disease
iams, Pharm.D.sor, Department of Pharmacy cy Oregon Health & Science cy, Oregon Health & Science ortland, Oregon
I accept, as should we all, timportant role
that inflammation plays a very in atherosclerosis
NEJM, Jan 14th, 1999
While hs-CRP gets most attention, tatherosclerosis clearly involves muly
Circulation, 2000
the inflammatory process in ltiple lines of inflammation
JCI, 2001
p
JACC 2002JACC, 2002
But……..the question is what to doinflammation to prevent and treat Cp
Two potential areas to target:1. Directly target inflammation with an a2. Use of inflammatory biomarkers to be2. Use of inflammatory biomarkers to be
“mean IMT was correlated with a highe
“There are conflicting data regarding the ef
o about it: “Should we target CAD?”
anti-inflammatory approachtter target anti-atherogenic therapytter target anti atherogenic therapy
Scand J Rheumatol 2010;39:485-89
er cummulative corticosteroid intake…”
Contem Chall Autoimmun 2009;1173:814-21
ffect of biologics on atherosclerosis”
Non-steroidal, anti-inflammatory agents CAD and appear to be associated with ri
Conclusions: “Even short-term treatment wirisk of death and recurrent MI…..any NSAIDsafety point of view.”
And we all know the story of Vioxx y
also clearly offer no benefit for isk
Circ 2011;123:2226-35th NSAIDs was associated with increased D use should be limited from a CVD
and selective COX2 inhibitors….
Atherosclerosis is a lipBasic Science
Subendothelial Lipoprotein Retention asUpdate and Therapp p
Ira Tabas, MD, PhD; Kevin Jon Williams, MD; Jan Borén, MD, PhD
hCirculation, October 16th, 2007
poprotein driven processfor Clinicians
s the Initiating Process in Atherosclerosispeutic Implicationsp p
So, the inflammation in atherosclerosd l i di hi h i b dunderlying disease which is subendot
Treating atherosclerosis with anti-infpneumonia with prednisone. p p
There may even be some benefit of vasc
Ci l iCirculation 2007;115:548
“local arterial inflammation signals the rcells…that participate in the healing resp
One area where ‘smart’ targeting of ng gthe elevation of HDL to retard athero
sis is a RESPONSE to the h li l i f li ithelial retention of lipoproteins.
flammatory agents is akin to treating
cular inflammation:
release of bone marrow-derived stem ponse of the injured blood vessel”
native immunity has been tried is in yosclerosis.
Immunology and Cell Biology Jan 2010Immunology and Cell Biology, Jan 2010
HDL is a particle which did not evolve as part of the traditional lipoprotein p p ppathway but rather as part of our innate immune system (note its completely separate lifecycle from the atherogenic, apoB-containing lipoproteins)
Tr in Endo Metab, Jan 2011
CETP inhibition with torcetrapib in 15,067 hiand increaseed total mortality by 58%and increaseed total mortality by 58%
igh risk patients increased HDLc by 72%
2. Use of inflammatory biomarkers a
A word of caution:
“It remains to be proven that any of incremental information over and ab
as prognostic factors to direct therapy
PK Shaw, Circulation, 2000
the inflammatory markers provide bove traditional risk stratification.”
New England JouApril 1
“C R i P i d O h Ci“C-Reactive Protein and Other Circthe Prediction of Cor
To minimize confounding from fluctuations inyear period on 2,459 case patients who had anremained disease free.
urnal of Medicinest, 2004
l i M k f I fl i iculating Markers of Inflammation in ronary Heart Disease”
n hs-CRP, this analysis performed over 12 n MI compared to 3,696 controles who
The story of inflammatory cytokines i
Inflammatory cytokines clearly play an imp
May 200
……but VCAM-1, like others has an unclear
“no meaningful, predictive benefit of VCAM-1”benefit of VCAM-1
Lancet; Sept., 2001
in CAD is long and tortuous:
portant role in atherosclerosis……
01
r role in predicting events
Sept 2001
TTrue-positive
NEJM December 21stNEJM, December 21st
2006
Framingham: Many CHD PatieNear AverageNear Average
40
30
20
%)
10
pu
lati
on (
%
0150 200 250
Pop
TC (mg/dL)
150 200 250
Castelli WP. Am J Med. 1984;76(2A):4-12.
ents Have TC Below or
Non-CHD 1378 219 41No. Mean (mg/dL) SD
CHD 193 244 51
300 350300 350
To determine if biomarker add utility to clinical risk prediction: Ten commonly cited biomarkers (including hs-CRP, fibrinogen and PAI-1) were applied to the Framingham database
C l i N dd d di tiConclusion: No added predictive benefit
NEJM; Dec 2006
Conclusion:
1. So while hs-CRP, VCAM-1, IL-6inflammatory markers have beenatherosclerosis, their role in prac, por predictors of events in individ
2 Atherosclerosis induces an inflam2. Atherosclerosis induces an inflamdisease process is accumulation wall and the appropriate treatmenatherogenic lipoprotein (e.g. LDLtreatment for pneumonia is antib
6, IL-8, WBC and other n found to be associated with ctice as targets of drug therapy g g pydual patients is suspect at best
mmatory response but themmatory response but the of lipoproteins in the arterial nt strategy is lowering of those L) particles (just like the
biotics, not prednisone)
Rebutttal
Absolute Risk Reduction (ARR) from 0.8
I have no complaint with the ‘cost-effectivpopulation but traditional risk factors are amore generic statin could you use at your
5 to 0.40 gives an annual NNT of 250.
veness of generic statins in a “JUPITER-like” as prognostic as an hs-CRP and how much institution for the cost of an hs-CRP test?
What really predicts CVD? CRP (Ca
20
25
or C
AD <1.0
1.0-3.03 0
5
10
15
Rel
ativ
e R
isk
fo >3.0
0
R
0-1% 2-4% 5-9% > 10%
Framingham Estimate of 10-year Risk (%)
15
20
25
or C
AD
5
10
15
Rel
ativ
e ri
sk f
o
Donald Lloyd-Jones; NLA ti 2007
0
5
hs-
meeting, 2007
ash in Ridkers Pocket) or Framingham risk?
Ridk NEJM 2002 347 1557Ridker, NEJM 2002;347:1557
0-1%2-4%5-9%>10%
CRP < 1.0 hs-CRP 1.0-3.0 hs-CRP > 3.0
Rebuttal Conclusion:
Our job as clinicians is to understand andatherosclerosis, that includes lipid lowerincessastion, antiplatelet therapy and glycem
Anti-inflammatory agents have no provenCAD d i i fl bi k hCAD and anti-inflammatory biomarkers hprognostic value to traditional risk scorin
d treat the causes of disease. For ng, BP control, smoking mic control where appropriate.
n role in treating or preventing h b ddhave not been proven to add g tools.