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CURRENT STATUS & RECENT ADVANCES IN
DYSLIPIDEMIA TREATMENT
Dr. Jeffrey Pradeep RajPost-graduate
Dept. of Pharmacology – SJMC02-11-2015
OUTLINE• Introduction • Lipid handling in the body• Pathophysiology of atherosclerosis• Current Hypolipidaemic drugs• Newer Hypolipidaemic drugs• ACC/AHA Clinical guidelines 2013• Pipeline drugs• Summary
INTRODUCTION
DYSLIPIDEMIA• Disorder of Lipid & lipoprotein metabolism• 3 primary abnormalities
Elevated triglycerides Elevated LDL cholesterolReduced HDL cholesterol
• Most important modifiable risk factor for CAD• Causes – Primary / secondary
PRIMARY DYSLIPIDEMIATYPE LIPID LIPOPROTEIN OCCURRENCEI – Familial lipoprotein lipase deficiency
TG Chylomicrons Rare
IIa – Familial Hypercholesterolaemia
C LDL Common
IIb – Polygenic hypercholestrolaemia
C, TG LDL, VLDL Most common
III – Familial dysbetalipoproteinaemia
C,TG IDL Rare
IV – Hypertriglyceridemia TG VLDL CommonV – Familial combined hyperlipidaemia
TG VLDL, chylomicrons
Rare
SECONDARY DYSLIPIDEMIA LDL cholesterol Triglycerides HDL cholesterolDiabetes mellitusHypothyroidismNephrotic syndromeObstructive liver diseaseDrugs Anabolic steroidsProgestinsBeta blockersThiazides
AlcoholismDiabetes mellitusHypothyroidismObesityRenal insufficiencyDrugs Beta blockersBile acid resinsEstrogensTiclopidine
Cigarette smokingDiabetes mellitusHypertriglyceridemiaMenopauseObesityPuberty (in males)UraemiaDrugs Anabolic steroidsBeta blockers
LIPID HANDLING IN THE BODY
LIPID ABSORPTION• Bile emulsifies fat in
chyme• P. lipase coverts
Triacyl glyceryl into FFA + glycerol• Absorbed into
enterocyte rapidly
CHYLOMICRON ASSEMBLY
LIPOPROTEINS• 5 classes classified
based on the density• TG transported in
chylomicrons or VLDLs
• Cholesterol transported as cholesteryl esters in LDLs and HDLs
LIPOPROTEIN METABOLISM
PATHOPHYSIOLOGY OF
ATHEROSCLEROSIS
MECHANISM OF ATHEROSCLEROSIS
CURRENT HYPOLIPIDAEMIC
DRUGS
CLASSIFICATION – CURRENT DRUGS
• HMG – CoA reductase inhibitorsLovastatin, simvastatin, pravastatin, atorvastatin,
rosuvastatin, pitavastatin
• Bile acid sequestrants (resins)Cholestyramine, colestipol
• Lipoprotein lipase activators (PPAR alpha activators)Clofibrate, gemfibrozil, bezafibrate, fenofibrate
• Lipolysis and triglyceride synthesis inhibitorNicotinic acid
• Sterol absorption inhibitorEzetimibe
OVERVIEW OF CURRENT DRUGS (1/2)
DRUG CLASS MOA SIDE EFFECTSHMG CoA reductase inhibitorsLovastatin (10-80mg)Simvastatin (5-40mg)Atorvastatin (10-80mg)Rosuvastatin (5-20mg)
↓ CH synthesis by inhibition of rate limiting HMG-CoA reductase
Myositis, myalgia, Elevated hepatic transaminases, Sleep disturbance, Head ache, nausea
Bile acid sequestrantsCholestyramine (4-16g)Colestipol (5-30g)
↓ bile acid absorption, ↑ hepatic conversion of CH to bile acids, ↑ LDL receptors on hepatocytes
Unpalatability, bloating, constipation, heart burn
OVERVIEW OF CURRENT DRUGS (2/2)
DRUG CLASS MOA SIDE EFFECTSPPAR alpha activatorsGemfibrozil (1200mg)Bezafibrate (600mg)Fenofibrate (200mg)
↑ Activity of lipoprotein lipase, ↑ VLDL metabolism, ↑ oxidation of FA in muscle & adipose tissue, ↓ TG synthesis in liver
Nausea, skin rash, 1-2% ↑ incidence of gall stones
Nicotinic acid (2-6g) ↓ Production of VLDL, ↓ lipolysis in adipocytes
Flushing, nausea, gluc intolerance, abnormal LFT, hyperuricemia
STATINS (1/3)Pleotropic effects: Non- lipid lowering, cardioprotective
STATINS (2/3)• Metabolized by microsomal enzymes except
pravastatin• CI: pregnancy, lactation• Potency : rosuvastatin > atorvastatin > simvastatin >
pravastatin & lovastatin• Lovastatin: First clinically used statin, prodrug
Extensive first pass metab; excreted in bile• Simvastatin: Greater rise in HDL, prodrug
Extensive first pass metab; Better oral absorption
STATINS (3/3)• Pravastatin: CH lowering effect is less; ↓ plaque
Decrease in fibrinogen level • Atorvastatin: Long acting (t ½ = 18-24 hr)
Highest LDL-C lowering Antioxidant & antiinflammatory
• Rosuvastatin: Most potent Greater LDL-C reduction
• Pitavastatin: Latest; no specific advantage
ASCOT-LLA TRIAL Sever PS, Dahlöf B, Poulter NR, et al. prevention of coronary and stroke events with atorvastatin in hypertensive patients who have average or lower than average cholesterol concentrations in the Anglo-Scandinavian cardiac outcomes trial – lipid Lowering arm (LLA): a multicentre randomised controlled trial. LANCET 2003; 361:1149
Participants 10305 hypertensive patients (aged 40-79 years; at least 3 CV risk factors) in ASCOT trial with non-fasting total cholesterol concentrations 6.5 mmol/L or less
Intervention Atorvastatin 10mg vs placeboEnd point non-fatal myocardial infarction and fatal CHDConclusions 100 events vs 154 in placebo (HR 0.64, p=0.0005).
Strokes, total CV events & coronary events were significantly lowered in statin arm
JUPITER TRIALRidker PM, Danielson E, Fonseca FA et al. Rosuvastatin to prevent vascular events in men and women with elevated C-reactive protein. N Engl J Med. 2008;359(21):2195
Participants 17,802 healthy pts with LDL-C < 130 mg/dl but hs-CRP of 2.0 mg/l or higher
Intervention rosuvastatin, 20 mg daily, or placebo End point Composite end point of MI, stroke, arterial
revascularization, hospitalization for unstable angina, or death from cardiovascular causes
Conclusions ↓ incidence of major CVS events. ↓ LDL-C 50% & ↓hs-CRP 37%
4S TRIALRandomised trial of cholesterol lowering in 4444 patients with coronary heart disease: the Scandinavian Simvastatin Survival Study. Lancet 1994; 344 (8934): 1383
Participants 4444 patients with angina pectoris or previous MI & serum cholesterol 5.5-8.0 mmol/L on a lipid-lowering diet
Intervention Simvastatin or placeboEnd point Lipid profile improvement and CVD outcomesConclusions mean changes in TC, LDL-C, HDL-C of -25%, -35%, and
+8%, resp. 37% reduction (p<0.00001) in the risk of undergoing myocardial revascularisation procedures. Improved survival in CHD patients
PROVE-ITCannon CP, Braunwald E, McCabe CH et al. Intensive versus moderate lipid lowering with statins after acute coronary syndromes N Engl J Med. 2004;350(15):1495
Participants 4162 patients hospitalized for ACS within the preceding 10 days
Intervention 40 mg pravastatin OD (std therapy) vs 80 mg atorvastatin OD (intensive therapy)
End point Composite of death from any cause, MI, documented unstable angina requiring rehospitalization, revascularization (at least 30 days after randomization), & stroke
Conclusions 16% reduction in the hazard ratio in atorvastatin. Intensive lipid-lowering statin regimen greater survival
BILE ACID SEQUESTRANTS• Secondary effect on cholesterol synthesis actually
VLDL • Hyper- TG may limit use• Used in combination with a statin• Important interactions – bind polar drugs such as
warfarin, digoxin, thyroxine and statins • Colesevelam (625mg 3 tab BD) – newer drug; better
tolerated
FIBRATES (1/2)• Most effective at reducing VLDL (TG); smaller in
LDL-C ; useful in HDL-C• Less favourable effect on clinical outcomes• Improvements in microvascular outcomes• Important interactions
Increased risk of myositis on a statinreduction in dose requirements (~30%) for patients on
warfarin
FIBRATES (2/2)• Fenofibrate: prodrug – t ½ 20 hr
Reduce fibrinogen levelsCommonly used in combination with statins (minimally
affects statin metab & ↓ myopathy)
• Gemfibrozil: Reduces TG & CHIncreased risk of myopathy with statin
• Bezafibrate: No myopathy
FIELD TRIALKeech A, Simes RJ, Barter P et al. Effects of long-term fenofibrate therapy on cardiovascular events in 9795 people with type 2 diabetes mellitus (the FIELD study): randomised controlled trial. Lancet 2005, 366:1849-61Participants 9795 pts (2131 with previous CVD & 7664 without)
aged 50-75 years, with type 2 diabetes mellitus not taking statin therapy
Intervention Micronised fenofibrate 200 mg OD vs PlaceboEnd point Coronary events (CHD death or non-fatal MI). For
subgroup analysis - Total cardiovascular events (CVD death, MI, stroke, coronary & carotid revascularisation)
Conclusions Significant reduction in TGs. Reduction in total CV events. No significant reduction in coronary events
ACCORD TRIALGinsberg HN, Elam MB, Lovato LC et al. Effects of combination lipid therapy in type 2 diabetes mellitus. N Engl J Med 2010, 362:1563-74Participants 5518 pts - type 2 diabetes on simvastatin treatmentIntervention Fenofibrate vs placebo. End point First occurrence of nonfatal MI, nonfatal stroke, or
death from CV causes.Conclusions Combination therapy did not reduce the rate of fatal
CV events, nonfatal MI, or nonfatal stroke. 30% ↓ in TG. ↓ progression in Retinopathy
NICOTINIC ACID• VLDL & fibrinogen; ↑ HDL 30-35%; TGs ~ 40%• Usually employed in combination with fibrate, resin
or statin – this avoids side effects of higher doses
AIM – HIGH TRIALBoden WE, Probstfield JL, Anderson T et al. Niacin in patients with low HDL cholesterol levels receiving intensive statin therapy. N Engl J Med 2011; 365:2255-2267Participants 3414 established CVD, low HDL-C, high TG Intervention ER niacin 1.5 – 2.0g vs placebo. All patients received
simvastatin 40-80mg/d ± ezetimibe 10mg/dEnd point 1st event of the composite of death from CHD,
nonfatal MI, ischemic stroke, hospitalization for ACS or symptom-driven coronary or cerebral revascularization
conclusions Among ASCVD pts with LDL <70mg/dl – no benefit despite Improvements in HDL-C and TG
HPS-2 THRIVE TRIALLandray MJ, Haynes R, Hopewell JC et al. Effects of extended-release niacin with laropiprant in high-risk patients. N Engl J Med 2014; 371:203-212Participants 25,673 adults with vascular disease.
Prerandomization run-in phase to standardize the background statin-based LDL-C lowering therapy
Intervention ER Niacin 2g + 40mg Laropiprant vs placeboEnd point First major vascular event (nonfatal MI, death from
coronary causes, stroke, or arterial revascularization)Conclusions In ASCVD, no significant reduction in major vascular
events but increased serious ADE
EZETIMIBE-STEROL ABSORPTION INHIBITOR
• Inhibits CH absorption from intestine• Novel inhibitor of intestinal cholesterol transporter
(NPC1C1)• No important adverse effects or significant drug
interactions• Statins decrease liver CH synthesis but increase
intestinal absorption. Ezetimibe vice versa (synergistic)• Unlike resins, it causes fall in TG
IMPROVE – IT TRIALCannon CP, Blazing MA, Giugliano RP et al. Ezetimibe Added to Statin Therapy after Acute Coronary Syndromes. N Engl J Med. 2015;372(25):2387Participants 18,144 pts hospitalized for ACS in last 10 days
LDL-C 50-100mg/dl if receiving lipid-lowering therapy or 50-125mg/dl if not receiving
Intervention Simvastatin 40 mg + ezetimibe 10 mg vs simvastatin 40 mg + placebo
End point Composite of CVD, nonfatal MI, unstable angina requiring rehospitalization, coronary revascularization, or nonfatal stroke
Conclusions Lowering of LDL-C and improved CV outcomes
NEWER HYPOLIPIDAEMIC
DRUGS
CLASSIFICATION - NEWER DRUGS
• Proprotein convertase subtilisin/kexin type 9 (PCSK9) inhibitors – Evolocumab, bococizumab, Alirocumab• Apolipoprotein B synthesis inhibitor – Mipomersen • Microsomal triglyceride transfer protein (MTTP)
inhibitor – Lopitamide • Thyromimetic – Eprotirome • Cholestryl ester transfer protein (CETP) inhibitors –
Torcetrapib, dalcetrapib
PCSK9 INHIBITORS• Inhibit proprotein convertase subtilisn/kexin type 9• Increases LDLR density on hepatocytes• Prevents LDLR degradation
PSCK9 - PHYSIOLOGY
PCSK9 ACTION
APPROACHES TO PCSK 9 INHIBITION
• Monoclonal antibodies: RG-7652 and LY3015014• Peptide mimics - Peptides that mimic the EGFA
domain of the LDLR that binds to PCSK9 (1D05-IgG2 )• Gene silencing:
PCSK9 antisense oligonucleotide, increases expression of the LDLR
Locked nucleic acid – reduced PCSK9 mRNARNA interference (ALN PCS02)
• Naturally occurring inhibitors: Plant alkaloid berberine & endogenous Annexin A2
ALIROCUMAB – PRALUENT• First drug of PCSK9I to be approved (July24, 2015)• Second line treatment for adults next to diet &
statin for clinical ASCVD & FH• Side effects -
Nose & throat irritationInjection site reactions and bruisingFlu-like symptomsDiarrhoeaBronchitis and coughMuscle pain, soreness, and spasms
ODYSSEY TRIALRobinson JG, Farnier M, Krempf M et al. Efficacy and Safety of Alirocumab in Reducing Lipids and Cardiovascular EventsParticipants 2341 patients at high risk for CVD. LDL-C of 70 mg/dl or
more + receiving rx with statins at the maximum tolerated dose, +/- other lipid-lowering therapy
Intervention Patients randomly assigned in a 2:1 ratio to receive alirocumab (150 mg) or placebo as a 1-ml S/C every 2 weeks for 78 weeks
End point Percentage change in calculated LDL cholesterol level from baseline to week 24
Conclusions At 24 weeks % change from baseline was 64% (p<0.001) Over 78 weeks significant ↓ LDL-C. In a post hoc analysis, evidence of ↓cardiovascular events
EVOLOCUMAB - REPHATHA • PCSK9 inhibitor from Amgen• FDA approval – 27 Aug 2015 (RUTHERFORD 1, 2 &
GAUSS trials)• Pts with uncontrolled LDL-C on current Rx options• Side effects:
Nasopharyngitis / URTI / fluBack painInjection site reactions
• Ongoing trials GAUSS – 2,3 in Statin Intolerant & FOURIER
APO B INHIBITOR – MIPOMERSEN (KYNAMRO)• Antisense oligonucleotide binds to mRNA; prevents translation
to form apolipoprotein-B • Decreased formation of apoB-containing lipoproteins,
including LDL cholesterol (40-50%). • Also decrease Lp(a) concentrations.• Side effects:
Injection-site reactions in almost all Influenza-like illness in many, andhepatic steatosis with elevated liver enzymes in up to 15% of
patients
• Approved for homozygous familial hypercholesterolemia, minimising apheresis need
MTTP INHIBITOR – LOMITAPIDE (JUXPID)
• Inhibit TG transfer to apoB-48 or apoB-100 in intestinal & liver cells respectively; decrease formation of chylomicrons & VLDL. • VLDL inhibition leads to LDL inhibition.• Side effects: Increased stool frequency, hepatic
steatosis & increase in serum transaminase levels. • FDA approval in Dec 2012 for homozygous familial
hypercholesterolemia.
CETP INHIBITORS• Inhibit transfer of cholesterol from anti-atherogenic
apolipoprotein A – containing particles to atherogenic apolipoprotein B particles
DRUG NAME TRIAL REMARKSTorcetrapib(with statins, ↑ HDL 60%, ↓ LDL 25%)
ILLUMINATE (Terminated - ADR )
↑ all-cause mortality & cardiovascular events, ↑ Sys BP by 5-6 mm Hg, ↑ aldosterone & cortisol, ↑ endothelial NO synthase & endothelin I
Dalcetrapib(↑ HDL 30%, LDL no effect)
Dal-OUTCOMES (Terminated - futility)
↑ Sys BP , smaller but significant↑ CRP (inflammation)
THYROMIMETICS - EPRORITOME
• Thyroid hormone analog with minimal non-hepatic tissue uptake• No long term or large studies done so far• No clinical hyper/hypo-thyroidism• Side effect: elevated transaminases
MISCELLANEOUS DRUGS• Probucol – ↓ LDL-C and HDL-C; facilitate resorption
of cutaneous & tendon xanthomas• Neomycin – ↓ LDL-C & Lp(a) 25%; similar in action
to bile acid sequestrants• Oestrogen Replacement therapy in post-
menopausal women - ↓ LDL-C ↑ HDL-C• Tamoxifen - ↓ LDL-C & tot. CH. No effect on HDL
CLINICAL GUIDELINES
EVOLUTION OF NHBLI SUPPORT GUIDELINES
Current guidelines ACC/AHA 2013
NCEP ATP III vs ACC/AHANCEP ATP III AHA/ACC – ATP IV
Year 2001 (updated in 2004) 2013
Focus Reducing CHD risk Reducing risk of atherosclerotic CV disease (ASCVD) – includes CHD + TIA/stroke, PAD or revascularisation
Risk assessment
Framingham 10 yr risk score (CHD death + non fatal MI
Pooled cohort equations* (fatal & nonfatal CHD + fatal & nonfatal stroke
*Developed by the Risk Assessment Work Group to estimate the 10-year ASCVD risk (defined as first-occurrence nonfatal and fatal MI and nonfatal and fatal stroke) for the identification of candidates for statin therapy
NCEP ATP III vs ACC/AHANCEP ATP III AHA/ACC – ATP IV
Risk Categories
3 main risk categories:CHD / CHD risk equivalent (DM, Clinical CHD, symptomatic CAD, PAD)2+ risk factors & 10-yr risk ≤ 20%0-1 risk factors & 10-yr risk <10%
4 statin benefit groups: Clinical ASCVDPrimary LDL-C elevations ≥190 mg/dlDM without clinical ASCVDNo DM/CVD with 10-yr ASCVD risk ≥7.5%
Rx targets LDL-C primary target<100mg/dl<130mg/dl (<100 if risk 10-20%)<160mg/dl(in the order of categories mentioned above)
Intensity of statin therapyHigh intensity statin therapy (LDL-C reduction ≥50%) recommended for most patients in 4 statin benefit groups
Rx recommendations
Statin (or bile acid sequestrants or nicotinic acid) to achieve LDL-C goal
Maximally tolerated statin first-line to reduce risk of ASCVD events
CLASS OF RECOMMENDATION LEVEL OF EVIDENCE
AHA/ACC GUIDELINE 2013 (1/2)
AHA/ACC GUIDELINE 2013 (2/2)
CV RISK CALCULATOR
HIGH INTENSITY THERAPY
MODERATE INTENSITY THERAPY
LOW INTENSITY THERAPY
Daily dose lowers LDL-C on avg ~ ≥50%
Daily dose lowers LDL –C on avg ~ 30-50%
Daily dose lowers LDL –C <30%
Atorvastatin (40*) 80 mg
Atorvastatin 10 (20) mg
Simvastatin 10 mg
Rosuvastatin 20 (40) mg
Rosuvastatin (5) 10 mg
Pravastatin 10-20 mg
Simvastatin 20-40 mg
Lovastatin 20 mg
Pravastatin 40 (80) mg
Fluvastatin 20-40 mg
Lovastatin 40 mg Pitavastatin 1 mgFluvastatin XL 80 mg
* Only one RCT Fluvastatin 40 mg bidPitavastatin 2-4 mg
STATIN THERAPY
MONITORING THERAPY
ACC/AHA COR LOE1.Creatine Kinase, routinely not needed III (No benefit) A2.Baseline CK in pts at risk of events IIa C3.Baseline ALT before initiating statins I B4.Decreasing the statin dose, if 2 consecutive values of LDL-C <40 mg/dl.
IIb C
5.Simvastatin at 80 mg daily harmful III (Harm) A6.New onset diabetes on statin therapy, continue statins & lifestyle management
I B
7.If muscle symptoms develop, discontinue, use again
II a C
8.Confusional state, evaluate non-statin causes II b C
SAFETY RECOMMENDATION OF
STATINS
NIACIN RECOMMENDATIONS
Baseline liver enzymes, FBS/HBA1c/uric acid
AST/ALT >2-3ULN
Persistent severe cutaneous symptoms,hyperglycemia,
acute gout
New onset AF,weight loss
Start at low dose
Take niacin with food or aspirin 325mg ½ hr BF
Uptitrate 500 mg ER to 2000mgER over 4-8 weeks
(or)Plain niacin 100mg TID to
3g/day
BILE ACID SEQUESTRANTS
Baseline fasting TG>300 mg/dl
caution if TG 250-299 mg/dl. 4-6 weeks later if TG >400 -discontinue
STEROL ABSORPTION INHIBITORS
Baseline hepatic transaminases
Discontinue if ALT>3 times occur
FIBRATES OMEGA 3 FATTY ACIDS
If used in TG >, evaluate GI disturbances,
Evaluate GI disturbances
Gemfibrozil + statin therapy (causes muscle
symptoms)
If TG>500mg/dl and benefit>risks -Fenofib
GFR<30 ml/min
PIPELINE DRUGS
BOCOCIZUMAB (Pfizer) • PCSK9 inhibitor• Phase 2b - Monthly or bimonthly injections ↓ LDL-
C at 12 weeks. *• SPIRE trials (Phase 3) - plans to enrol 17,000 pts.
Intolerant to statinsHereditary heterozygous hypercholesterolemiaPrimary hyperlipidemia/mixed dyslipidemia (3 trials)At highrisk CVD (2 trials)
* Ballantyne CM, Neutel J, Cropp A et al. Results of Bococizumab, A Monoclonal Antibody Against Proprotein Convertase Subtilisin/Kexin Type 9, from a Randomized, Placebo-Controlled, Dose-Ranging Study in Statin-Treated Subjects With Hypercholesterolemia. Am J Cardiol. 2015 May 1;115(9):1212-21.
RG7652 (Roche)• Monoclonal antibody – PCSK9 inhibitor• July 2013: Phase II EQUATOR trial completed
(unpublished)• July 2014:
Discontinued - Phase-I; Metabolic disorders (Switzerland)
Discontinued - Phase-II; Coronary disorders & Hyperlipidaemia (USA, Canada, Czech Republic, Germany, Hungary, New Zealand, Norway, Slovakia and South Africa)
LY3015014 (Eli Lilly)• Monocloncal antibody – PCSK9 inhibitor• 3 Phase 2 trials completed by June 2014 • No liver / muscle safety issues• Upto 51% ↓ in LDL-C, significant ↓ non-HDL-C,
ApoB and Lp(a)*
* Kastelein J, Nissen S; Rader D et al. Safety and Efficacy of LY3015014, a New Monoclonal Antibody to Proprotein Convertase Subtilisin/Kexin Type 9 (PCSK9) with an Inherently Longer Duration of Action, in Patients with Primary Hypercholesterolemia: A Randomized, PlaceboControlled, Dose-Ranging, Phase 2 Study. J Am Coll Cardiol. 2015;65(10_S)
1D05-IgG2• Fragment antigen-binding (Fab) protein that mimics
EGFA domain of LDLR• Current status: Preclinical studies• Ts mouse model LDL-C ↓ 40% & ↑ hepatic LDLR
protein levels 5 fold. • In healthy rhesus monkeys, LDL cholesterol ↓
20%–50% for over 2 weeks
*Ni YG, Di Marco S, Condra JH et al. A PCSK9-binding antibody that structurally mimics the EGF(A) domain of LDL-receptor reduces LDL cholesterol in vivo. J Lipid Res. 2011 Jan;52(1):78-86
ALN-PCS02 (Alnylam Pharma)
• siRNA against PCSK9 gene• Phase 1 trail completed• IV infusion for 32 patients• Results officially not published • However, significant impact on lipid management
PCSK9 VACCINE• Virus like particle (VLP) – immunogenic carrier of PCSK9
antigenic peptide• VLP – virus without DNA – no replication. External
structure – antigen display• Animal studies showed high titre IgG antibodies• Significant ↓ total cholesterol, TG & PL
* Crossey E, Amar MJ, Sampson M, Peabody J, Schiller JT, Chackerian B, Remaley AT (2015). "A cholesterol-lowering VLP vaccine that targets PCSK9". Vaccine 33(43): 5747–55
EVACETRAPIB – CETP inhibitor
• ACCELERATE trial – 12095 high risk CVD patients; stopped prematurely (Oct 2015) for lack of efficacy• ACCENTUATE trial – pts with hyperlipidemia or DM
ANACETRAPIB – CETP INHIBITOR
• DEFINE – Phase III trial*1623 pt with CHD or at high risk on statins100mg anacetrapib vs placebo↑ HDL 138.1%, ↓LDL-C 36%, ↓Lp(a) 36.4% in
comparison with placebo by 24 weeksNo change in BP, Electrolyte or aldosterone by 76wNo ↑ in CVD events
• REVEAL – Phase III trial (ongoing) 30,000 pts with occlusive arterial disease
* Cannon P, Shah S, Dansky HM et al. Safety of Anacetrapib in Patients with or at High Risk for Coronary Heart Disease. NEJM 2010; 363:2406-2415
IMPLITAPIDE – MTTP INHIBITOR
• Two phase 2 trial terminated (2005)• 80mg/160 mg doses caused unacceptable rise in liver
enzymes & GI disturbances *• Trials with lower doses suggested• No further details obtainable
*Dam MV, Farmer M, Stein EA et al. Efficacy an d safety of implitapide (bayy 13-9952), a microsomal triglyceridee transfer protein inhibitor,, in patients with primary hypercholesterolemia-accessed on 1/11/15 from http://dare.uva.nl/document/2/14716
OTHER MTTP INHIBITORSDRUG (status as of year)
REMARKS
CP346086(2003)
Phase 2: 47% ↓total cholesterol, 72% ↓LDL-C, 75% ↓ TG
AEGR733 ↓LDL-C by 51% from baseline at the highest dose. ↑ Liver aminotransferase & hepatic fat accumulation
JTT130 Animal study: 25% ↓ LDL-C & 30% ↓ TG & No hepatic steatosis. Current status – phase 2 trials
SUMMARY• Lipid handling in the body & pathophysiology of
dyslipidemia & atherosclerosis• Current hypolipidemic drugs – statins, BAS, fibrates
niacin, sterol absorption inhibitors• Newer agents – PCSK9 inhibitors, MTTP inhibitors,
apo B inhibitor, CETP inhibitor, thyromimetics• ACC/AHA 2013 guidelines - LDL-C targets are not
absolute as in ATPIII• Drugs in the making
REFERENCES• Tonkin A, Byrnes A. Treatment of dyslipidemia. F1000Prime Reports.
2014;6:17• Robert SR. Lipid lowering with drugs other than statins and fibrates
(accessed on 15/09/2015) http://www.uptodate.com/contents/lipid-lowering-with-drugs-other-than-statins-and-fibrates
• Robert SR. Lipid lowering with fibric acid derivatives. (accessed on 15/09/2015) http://www.uptodate.com/content/lipid-lowering-with-fibric-acid-derivatives
• 2013 ACC/AHA Guideline on the Treatment of Blood Cholesterol to Reduce Atherosclerotic Cardiovascular Risk in Adults A Report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines. (accessed on 22/10/2015)
• Sahebkar A, Watts GF. New LDL-Cholesterol Lowering Therapies: Pharmacology, Clinical Trials, and Relevance to Acute Coronary Syndromes. Clin Ther. 2013 Aug;35(8):1082-98• For pipeline drugs status
(http://adisinsight.springer.com/drugs )• For various trial details (https://clinicaltrials.gov)