It’s official, statins do not have any side effects - Kendrick

It’s official, statins do not have any side effects

"The reality is, that unless you have had a previous heart attack, statins have no effect on overall mortality. To put that another way, they don’t save lives. They don’t even prevent heart attacks or strokes in women with no previous history of heart disease.

The statistic you really want to know about statins is the following. If you have had a heart attack, or stroke, and take a statin for five years, you will increase your life expectancy by 4.2 days. Balance that against a twenty per cent chance of having side effects, some of which are very unpleasant and long-lasting, and you can see why I am not a fan of statins."
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"A number of things were found. The most important of which, is just how many people stopped taking their statins after one year. A pretty staggering 75%. Why did they stop?

‘More than six in ten respondents (62%) said they discontinued their statin due to side effects, with the secondary factor (17%) being medication cost. Only 12% of respondents cited lack of efficacy in cholesterol management as a reason for stopping their medication. On average, respondents who experienced side effects due to their statin stopped after trying two different statins.

Three out of ten respondents experienced side effects of muscle pain and/or weakness, and 34% stopped taking their statin because of these side effects without consulting with their doctor.'

Read the complete article by Dr Kendrick here.

How much longer will you live if you take a statin?

"Looking at the Heart Protection Study (HPS) done in the UK, we used a technique for analysing survival time called RMST (restricted mean survival time). I won’t go into the details. The HPS study lasted for five years, and we calculated that the average increase in survival time was 15.6 days. This was at the end of five years of treatment (with a confidence interval of 5 days either side). For 4S, the figure was 17 days."

"Framing this slightly differently, what this meant was that taking a statin for one year, in the highest risk group possible, would increase your life expectancy by around three days."

"However, more recently the BMJ did decided to publish another paper entitled: ‘The effect of statins on average survival in randomised trials, an analysis of end point postponement.’

Results: 6 studies for primary prevention and 5 for secondary prevention with a follow-up between 2.0 and 6.1 years were identified. Death was postponed between −5 and 19 days in primary prevention trials and between −10 and 27 days in secondary prevention trials. The median postponement of death for primary and secondary prevention trials were 3.2 and 4.1 days, respectively."

Conclusions: Statin treatment results in a surprisingly small average gain in overall survival within the trials’ running time. For patients whose life expectancy is limited or who have adverse effects of treatment, withholding statin therapy should be considered

Overall their findings were far less impressive, even, than ours. They calculated, approximately, a single day of increase in life expectancy for each year of taking a statin. Slightly more in secondary prevention, slightly less in primary (people who have not previously had a heart attack or a stroke).

The main take away message I believe, is the following. Statins do not prevent fatal heart attacks and strokes. They can only delay them. They delay them by about one or two days per year of treatment. For those who have read my books you will know that I have regularly suggested we get rid of the concept of ‘preventative medicine’. We need to replace it with the concept of ‘delayative medicine’.

Read Dr. Kendrick's complete article here.

Congenital abnormalities in baby born to mother using lovastatin

Thursday, 10 March 2016

Congenital abnormalities in baby born to mother using lovastatin

This study was published in the Lancet 1992 Jun 6;339(8806):1416-7

Study title and authors:
Congenital abnormalities (VATER) in baby born to mother using lovastatin.

Ghidini A, Sicherer S, Willner J.

This paper can be accessed at: http://www.ncbi.nlm.nih.gov/pubmed/1350826

This paper reports the case of an infant born with many malformations after the mother used a statin during pregnancy.

(i) A woman was treated for five weeks with lovastatin, starting approximately six weeks from her last menstrual period.
(ii) The statin was discontinued when her pregnancy was diagnosed at 11 weeks' gestation.
(iii) A female infant was delivered by cesarean section at 39 weeks' gestation. The infant had a constellation of malformations termed the VATER association (vertebral anomalies, anus not developed properly, an abnormal connection between the oesophagus and the trachea with part of the oesophagus missing, and kidney, forearm and wrist abnormalities).
(iv) Her anomalies included a deformed chest, spinal deformity, absent left thumb, foreshortened left forearm, shortened left elbow, fusion of the ribs on the left, anomalies in the spine, deformed left forearm, and a narrow lower oesophagus.

Statins, neuromuscular degenerative disease and an ALS-like syndrome

Statins, neuromuscular degenerative disease and an amyotrophic lateral sclerosis-like syndrome: an analysis of individual case safety reports from vigibase.

Edwards IR, Star K, Kiuru A.

Author information

• The WHO Foundation Collaborating Centre for International Drug Monitoring, the Uppsala Monitoring Centre (UMC), Uppsala, Sweden. ralph.edwards@who-umc.org

Abstract

BACKGROUND:

The WHO Foundation Collaborating Centre for International Drug Monitoring (Uppsala Monitoring Centre [UMC]) has received many individual case safety reports (ICSRs) associating HMG-CoA reductase inhibitor drug (statin) use with the occurrence of muscle damage, including rhabdomyolysis, and also peripheral neuropathy. A new signal has now appeared of disproportionally high reporting of upper motor neurone lesions.

AIM AND SCOPE:

The aim of this paper is to present the upper motor neurone lesion cases, with other evidence, as a signal of a relationship between statins and an amyotrophic lateral sclerosis (ALS)-like syndrome. The paper also presents some arguments for considering that a spectrum of severe neuromuscular damage may be associated with statin use, albeit rarely. The paper does not do more than raise the signal for further work and analysis of what must be regarded as a potentially very serious and perhaps avoidable or reversible adverse reaction, though it also suggests action to be taken if an ALS-like syndrome should occur in a patient using statins.

METHODS:

The 43 reports accounting for the disproportional reports in Vigibase (the database of the WHO Programme for International Drug Monitoring) are summarised and analysed for the diagnosis of an ALS-like syndrome. The issues of data quality and potential reporting bias are considered.

RESULTS:

'Upper motor neurone lesion' is a rare adverse event reported in relationship to drugs in Vigibase (a database containing nearly 4 million ICSRs). Of the total of 172 ICSRs on this reported term, 43 were related to statins, of which 40 were considered further: all but one case was reported as ALS. In 34/40 reports a statin was the sole reported suspected drug. The diagnostic criteria were variable, and seven of the statin cases also had features of peripheral neuropathy. Of a total of 5534 ICSRs of peripheral neuropathy related to any drug in Vigibase, 547 were on statins. The disproportional reporting of statins and upper motor neurone lesion persisted after age stratification, and such disproportionality was not seen for statins and Parkinson's disease, Alzheimer's disease, extrapyramidal disorders, or multiple sclerosis-like syndromes.

DISCUSSION:

Because the cases were sometimes atypical we propose the use of the term 'ALS-like syndrome' and speculate whether this is part of a spectrum of rare neuromuscular damage. The diagnosis of ALS is often problematic, and the insidiousness and chronicity of the disease make causality with a drug difficult to assess. The disproportionally high reporting makes this an important signal nevertheless, since ALS is serious clinically and statins are so widely used. Wide use of the statins also makes a chance finding more probable, but is unlikely to cause disproportional reporting when there are no obvious biases identified.

CONCLUSION:

We emphasise the rarity of this possible association, and also the need for further study to establish whether a causal relationship exists. We do advocate that trial discontinuation of a statin should be considered in patients with serious neuromuscular disease such as the ALS-like syndrome, given the poor prognosis and a possibility that progression of the disease may be halted or even reversed.
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Read the complete article here.

Beware: new cholesterol lowering drugs coming - Kendrick

Beware: new cholesterol lowering drugs coming

by Dr Malcolm Kendrick

‘…across the gulf of space, minds that are to our minds as ours are to those of the beasts that perish, intellects vast and cool and unsympathetic, regarded this earth with envious eyes, and slowly and surely drew their plans against us.’ War of the Worlds

An era is coming to an end. Statins, the world’s most widely prescribed and profitable drugs, have, with the exception of Crestor (rosuvastatin), all come off patent and their price has plummeted. Good news for NHS accountants: not so good for company profits.

So a supposedly new, improved, much safer and more effective generation of cholesterol lowering drugs will soon be available at a doctor’s surgery near you. At least that will be the general tone of the marketing. With 80% of the population suffering from “high” cholesterol, according to guidelines drawn up by consultants with links to drug companies, there is obviously a huge need. (For an account of how seriously we should take this “need” see Dr John Briffa’s post.)

This is obviously a great opportunity for the companies but it also faces them with a fascinating dilemma. Statins have been relentlessly promoted as the most beneficial l class of drugs ever, protecting not just against cardiovascular disease but also Alzheimer’s and Parkinson’s and being virtually side-effect free into the bargain.

An alarming press release

But if the companies are going to persuade those NHS accountants and cash-strapped GP commissioning bodies to start paying serious prices for the new drugs, they need to persuade them that statins actually had a serious problem all along but it is one that can be avoided by buying the new products.

Recently I received a press release by email that was the first sign that this process is already underway. It was a warning about something called P9 which, had I been a loyal statin believer, I would have found pretty alarming. After explaining how statins worked by targeting an enzyme known as HMG-CoA in the liver, the email went on to tell me this:

“However, statin treatments have been shown to actually stimulate the production of PCSK9, which is counterproductive, possibly damaging to the liver, and ultimately limits the treatment’s ability to lower LDL cholesterol levels.”

Why weren’t we told about this risk before?

What on earth is PCSK9, you and the medical statin believers might well ask. And if it is not only able to damage the liver but also render the whole purpose of taking a statin self-defeating, why haven’t we been told about it before?

Here was a classic marketing ploy; tell you about a problem and immediately offer a solution in the form of a drug that is able to block the production of damaging PCSK9. The full name of these new drugs is proprotein convertase subtilisin/kexin type 9 inhibitors.

And it’s not the only dauntingly high tech-new cholesterol lowering drug that could be coming your way in the not too distant future. For the sake of completeness here is a list of nearly all the new compounds waiting in the wings. Some will undoubtedly founder on the rocks of side effects that are just too dangerous, never to be seen again.

Other new drugs in the race

• Inhibitors of proprotein convertase subtilisin/kexin type 9 (PCSK9 inhibitors)
• Antisense oligonucleotides (ASOs) targeting the production of apolipoprotein B-100 (apoB-100)
• Microsomal triglyceride transfer protein inhibitors
• Squalene synthase inhibitors
• Peroxisome proliferator-activated receptor agonists
• Thyroid hormone receptor agonists

For the moment though my money for the first out of the gate are the PCSK9 inhibitors, which I will call P9 inhibitors. So what exactly are they? Well P9 is an enzyme that is found mainly in the liver. It binds to receptors that remove the “bad” LDL (low density lipoprotein) cholesterol and destroys them after they have taken just one LDL molecule out of circulation, meaning that they can’t be reused to remove more LDL.

But if you block P9, you allow LDL receptors to continue removing LDL merrily from the bloodstream, so LDL levels fall dramatically. In fact P9 inhibitors appear to lower LDL far more effectively than statins which, if you sign up to the belief that the lower your cholesterol goes the more protection you get, this can only be another major benefit.

The new statin combo

What’s clever about this is that it avoids taking on statins directly. Given how familiar doctors are with them, how most believe in them and how cheap they are, a head on attack would be doomed to failure.  The manufacturers know, damn well, that doctors are not just going to stop using statins, so their P9 inhibitors will be positioned to sit alongside statins, allowing them to work, supposedly, even more safely.  At first anyway.

But there is more to this press release and I could pick it apart for hours, marvelling at the ability to say so much – in so few words. But let’s just focus on the phrase…’possibly damaging to the liver’ in relation to statins. Now, I know that statins do damage the liver – to a greater or lesser degree. Liver enzymes in the blood (a sign of liver damage) are often raised to three times normal levels – sometimes more.

But why not focus on the side-effect that is most clearly recognised with statins?  Namely muscle damage and pain. This is the true Achilles heel of statins. Yet the press release talks about liver damage…

Danger to your liver

The most likely reason is that P9 inhibitors have been found to cause liver problems themselves in both animal studies and phase 1 studies on human volunteers. Knowing their mechanism of action, it is more than likely that PCSK9 blocking agents could damage the liver. If you over-ride negative feedback mechanisms, the body doesn’t like it very much, as you will be overloading cells with toxic waste products. Enzymes to break down LDL receptors are there for a reason.

So, we can expect P9 inhibitors are going to cause liver damage. However, by attacking statins for causing liver damage, the pharmaceutical companies will be hoping to mask the most serious adverse effect of the new drug. The words used to defuse concerns about this problem will be something along the lines of. ‘With our P9 inhibitor we have seen mild elevations of liver enzymes in clinical studies. However, they are similar to those caused by statins, are reversible and cause no long-term damage.’ Blah, blah….  ‘Move along, nothing to see here.’

This fear is not just based on a vague unease that if you block a feedback mechanism in the body you are probably heading for disaster. It is also based on the fact that, if the companies developing P9 inhibitors are already blaming statins for causing liver damage, they are doing to hide their own problems behind a smokescreen. You heard it here first.

I also predict that severe liver damage problems will take years to emerge. In most people the liver is pretty resilient – it takes a lot of alcohol and a lot of time to destroy it. I fear that clinical studies will not be long enough to demonstrate this effect –before the drugs are launched and widely prescribed. I can say all this because it is what has happened with damaging block buster drugs in the past, such as the anti-inflammatory Vioxx and and the diabetes drugs Avandia.

My predictions for P9 inhibitors:

• They will be widely promoted as the new statins
• Pfizer, or Merck, will buy out the patent to one of the new products (they may have already done this)
• They will be launched without any long-term studies to show they actually cut your chance of dying from a heart attack. They will be approved purely on the basis that they lower cholesterol/LDL cholesterol.
• They will make billions upon billions in the first two years and be hailed around the word as a new generation in cholesterol lowering. The chief executives of the companies selling these drugs will be paid massive bonuses
• Key Opinion Leaders (‘experts’) will promote them ruthlessly at major conferences and press launches
• Reports of a high level of liver damage/deaths will  start to emerge
• The companies will deny there is a problem and attack anyone who says there is one
• They will start to be withdrawn from the market two to three years after launch
• There will be lawsuits
• The companies will be fined a small fraction of the profits they made from hyping the drugs
• It will emerge that the problems with liver damage were known by the companies many years before the drugs were launched but not many people will be interested by then, as the next generation of lipid lowering agents will be arriving
• No-one will be held accountable

Yes, the great Nostrokendrickos has spoken.
In the meantime remember that ‘Something unpleasant this way comes’.
Disclosure: I do not believe that a raised LDL/cholesterol level causes heart disease.
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Read the complete article here.

The controversial study that started the War on Cholesterol - Watson

The controversial study that started the War on Cholesterol…

      

Alan Watson | June 14, 2012   

Revisiting the Coronary Primary Prevention Trial (CPPT) – 1973 to 1984

Using "relative risk statistics" and changing the study's design, the CPPT researchers declared success and the War on Cholesterol began in earnest

 

Launched in 1973 by the National Institutes of Health, the Coronary Primary Prevention Trial (CPPT) set out to prove that lowering blood cholesterol with a drug and a low cholesterol, low saturated fat diet would reduce the risk of coronary heart disease and extend the lives of the study participants.

(As part of the study, twelve new Lipid Research Clinics were set up by the Heart Institute at large universities throughout the country including Baylor, Stanford, Johns Hopkins and the University of Washington in Seattle.)

The researchers were looking for middle-aged men with total cholesterol levels exceeding those of 95 percent of Americans. (Only men with the highest 0.8 percent total cholesterol qualified.) The CPPT researchers screened 480,000 applicants in order to select 3,806 high risk men between the ages of 35 and 59.

This meant that many of the participants had familial hypercholesterolemia, a rare genetic defect in cholesterol metabolism present in about 1 percent of the population. The trials chance of success was therefore greatly increased by focusing on this particular group of presumably vulnerable men.
In their preliminary report, CPPT researchers announced that they would study two separate outcomes:  (1) Nonfatal heart attacks and (2) fatal heart attacks or deaths from coronary heart disease. The CPPT directors emphasized that they would be satisfied with nothing less than the strongest statistical proof of their findings; they had to be “99 percent certain that the results were not due to chance.”

The researchers also announced their goal of reducing blood cholesterol in the treatment group by 25 percent and reducing the risk of heart disease in the treatment group by at least 50 percent.
Approximately half of the 3,806 men were provided low cholesterol, low saturated fat dietary advice and were treated with cholestyramine, a cholesterol-lowering bile acid resin (Questran).

(Cholestyramine lowers cholesterol by interfering with digestion. Statins such as Lipitor, Mevacor and Zocor were not available yet.)

The control group was provided the same dietary advice and an unpleasant tasting placebo – an indigestible mixture of sand, sugar and food coloring. Both trial groups suffered with moderate to severe gastrointestinal distress. There were eight gastrointestinal cancer deaths in the treatment group (out of 21 cases) and one in the placebo group (out of 11 cases).

(There were more deaths from cancer, intestinal disease, stroke, violence and suicide in the group taking the cholesterol-lowering drug, and overall mortality was essentially the same for both groups.)

Disappointing Results

In 1984, the disappointing results were tabulated. Cholesterol levels in the treatment group had decreased by no more than 7 percent. Cholestyramine and the low cholesterol, low saturated fat diet had failed to lower cholesterol enough to prove that lowering cholesterol would reduce the risk of heart disease and extend the lives in the treatment group.

The difference in nonfatal heart attacks was not statistically significant. In the treatment group, 130 participants (6.8 percent) had a heart attack versus 158 in the placebo group (8.3 percent). After 7 years, the fraction of the treatment group that had benefited was less than 2 percent.

                                       Nonfatal heart attacks               Fatal heart attacks/coronary deaths
1,900 Control Group:         158 or 8.3 percent                               38 or 2.0 percent
1,906 Treatment Group:     130 or 6.8 percent                              30 or 1.6 percent

The difference in fatal heart attacks was not significant either. In the treatment group, 30 participants (1.6 percent) suffered a fatal heart attack compared to 38 in the placebo group (2.0 percent) Again – after 7 years of taking an unpleasant drug (and following a low fat diet), the fraction of the treatment group that benefited was less than 1 percent.

However, by applying relative risk statistics (a percentage of a percentage), the CPPT researchers improved their results. They took the number of people who presumably didn’t have a heart attack because of taking the drug (28) and looked at it as a percentage of the people who did have heart attacks (158) but didn’t take the drug:

The less than 2 percent absolute difference in nonfatal heart attacks rose to a reported 19 percent reduction in risk of a heart attack!

 

In similar statistical fashion, the researchers announced a 24 percent reduction in the risk of dying from a heart attack. The 8 men or 1.6 percent out of 1,900 who presumably did not have a fatal heart attack because they took the drug became the same 24 percent who reduced their risk of mortality compared to those in the control group who did die (38) but did not take the drug.

Additional study design changes

To prop up their victory, the CPPT researchers decided to exclude  “uncertain” nonfatal heart attacks from the treatment group while including  “uncertain” fatal heart attacks in the placebo group. Also, using the original 99 percent standard, the small favorable trend in either group could only be explained by chance (as defined by the researchers themselves at the start of the trial.)
By applying the less stringent 95 percent standard and by combining the two groups into one (nonfatal and fatal heart attacks), the CPPT researchers improved their results – declared victory – while the press responded with unbridled enthusiasm.

In 1984, the press and medical journals portrayed CPPT as the long sought proof that animal fats were the cause of heart disease. It was widely reported that for the first time:

“It had been proven that lowering cholesterol would reduce the mortality from heart disease and lower the risk of having a heart attack.”

 

Much of what we hear today about diet and heart disease can be traced back to this notorious failed study. When other scientists voiced their objections to the trial’s design changes, the CPPT directors simply denied that they had ever embraced the original more stringent standards.

In January 1984, the Journal of the American Medical Association (JAMA) dutifully reported:

“The trial’s implications…could and should be extended to other age groups and women, and to others with more modest elevations of cholesterol levels. The benefits that could be expected from cholestyramine treatment are considerable.”

 

George Mann, M.D., professor in medicine and biochemistry at Vanderbilt University, severely criticized the CPPT directors and the trial’s unsupportable results:

“The managers at the National Institutes of Health have used Madison Avenue hype to sell this failed trial in the way the media people sell an underarm deodorant…”

 

 Giving cholestyramine for over seven years to 1,906 middle age men – many with a genetic predisposition to atherosclerosis – had only saved the lives of eight but the Heart Institute was now recommending that cholesterol-lowering drug treatment be extended to patient groups that had not been part of the trial.

Even without the solid evidence they sought, the medical elite in the American Heart Association and the National Institute of Health decided to push ahead with cholesterol-lowering drugs and the still unproven low cholesterol, low saturated fat diet:

 “Now we have proved that it is worthwhile to lower blood cholesterol; no more trials are necessary. Now is the time for treatment.”

 

 The long War on Cholesterol had begun
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Read the complete article here.

The topic covered in this podcast concerns the use of the B vitamin , Niacin, when taking a statin. Is this a beneficial combination, or does it lead to an increased risk of stroke? We invite you to listen in with Lindsay and Dr. Blanchet.

http://tuesdaytalkshow.podomatic.com/entry/2013-09-19T12_12_40-07_00

Statin Therapy: Risks vs Benefit - Medscape

Statin Therapy: Risks vs Benefit: An Expert Interview With Eliot A. Brinton, MD

 

Editor's Note: Dr. Brinton is Director of the Metabolism Section of Cardiovascular Genetics, and Associate Professor at the University of Utah School of Medicine, Salt Lake City, Utah. He is board certified in internal medicine and endocrinology.
                       
Dr. Brinton's areas of clinical interest include the management of dyslipidemia and prevention of atherosclerosis and the treatment of diabetes mellitus and metabolic syndrome. He also has research interests in lipoprotein metabolism and HDL-cholesterol metabolism in vivo and in vitro, including the effects of estrogen and other agents.
                       
The author of numerous original scientific studies, Dr. Brinton has received many peer-reviewed research grants, and has held numerous leadership and advisory positions in scientific and governmental organizations, and in the pharmaceutical industry. He is a founding board member of the National Lipid Association. Dr. Brinton was interviewed for Medscape by Linda Brookes, MSc.
                       
Medscape: Why is the safety of statins such a widely discussed issue at the moment?
                       
Dr. Brinton: The safety of statins is of great interest to the public, as well as to clinicians and policy makers, in part because of the problems with the safety of cerivastatin (Baycol, Bayer), which ultimately led to its withdrawal from the market. With the recent advent of a new statin, rosuvastatin (Crestor, AstraZeneca), these concerns have resurfaced. Medication safety is always an issue, but especially so with the statins, for several reasons. First, and perhaps most importantly, they are prescribed frequently. Statins are the single most prescribed category of agents, in dollar value, in the United States today. Second, they are prescribed for long periods of time. Over the many years that a typical patient takes a statin, there are many chances for adverse events, including unforeseen changes in the patient's health status. A third and very important factor is that statins are most commonly used in middle-aged or elderly patients, who tend to be taking many other medications for other problems. This heightens safety concerns, both because the polypharmacy typical of these age groups greatly increases the overall risk of drug-drug interactions and because many of the diseases common in older patients contribute to drug safety concerns, and finally, because advanced age itself, even with excellent health, probably increases the risk of drug toxicity.

Medscape: There has been much discussion about myopathy in relation to statins. What is the difference between myopathy, myalgia, and rhabdomyolysis?
                       
Dr. Brinton: There are 4 interrelated terms for muscle problems that can occur with statins. Unfortunately, they are often confused even by healthcare professionals.

Myopathy is a general term for disease of the muscles, and it is usually characterized by weakness. In the setting of statin treatment, myopathy is used to describe any muscle problem, whether or not it is actually related to the statin use.

Myalgia refers specifically to pain in the muscles. Muscle pain is often seen with statin-based myopathy; however, painless myopathy from statin therapy is also quite common and may be rather dangerous because it is often ignored. If the healthcare provider has not instructed the patient to look for this, the patient may not report it or, if the patient reports weakness without pain, the healthcare provider may not recognize it as constituting a true myopathy.

Myositis is inflammation of the muscle confirmed by histologic findings of muscle biopsy. We rarely know whether the patient has myositis because we rarely perform muscle biopsies. These are very accurate and, in many ways, they are the gold standard for diagnosing a statin-induced myopathy; however, the pain, inconvenience, and cost of biopsies make them impractical for most clinical and research settings. Since the word myositis is probably best reserved for biopsy-proven myopathy, it is not of much use. A recent study^[1] showed that patients without an elevation of their serum creatine phosphokinase (CPK) level can nevertheless have myositis on biopsy. Thus, we need to have a fairly high index of suspicion for myopathy, realizing that it may be more common than we think, especially if we are looking only for myalgia or only for an elevated CPK.

Finally, rhabdomyolysis is the extreme type of myopathy, in which the muscle tissue is so inflamed that it breaks down in large quantities. It brings large amounts of myoglobin, the predominant muscle protein, to the circulation from which it then has to be removed by the kidney. Since the kidney is not well equipped to handle large amounts of myoglobin, it can become overwhelmed and damaged. Although the kidney usually recovers over time, rhabdomyolysis may be fatal due to acute renal failure and sequelae to other organs. Thankfully, most cases of rhabdomyolysis do not result in death, although they usually require hospitalization. Due to its seriousness, rhabdomyolysis is better prevented than treated, so we must do our best to see that myopathy does not progress to rhabdomyolysis.

Medscape: How often does myopathy occur?
                       
Dr. Brinton: In most clinical trials involving statins, less than 1% of subjects are reported to develop myopathy. In clinical practice, however, far more than 1% of patients will experience at least 1 symptom of myopathy. The much lower rate reported in clinical trials may be because eligibility criteria usually exclude patients with significant potential for drug-drug interactions or concurrent health problems, whereas healthcare providers cannot usually exclude those patients in clinical practice. Some studies have suggested that a quarter or even upwards of a third of patients who take statins will sooner or later develop a clinically significant myopathy.

Medscape: What are the risk factors for myopathy?
                       
Dr. Brinton: The main risk factors for myopathy are: female gender, advanced age (> 60 years) dehydration, underlying renal or liver disease, and concomitant medications. There is a fairly long list of medications that increase the risk of myopathy. Some of these are relatively specific for one statin vs another, but most of them appear to apply to all statins.

Medscape: How do you monitor patients for myopathy?
                       
Dr. Brinton: The first and best step is to ask about symptoms, but we have to be careful to ask about the right ones. We must ask not only about muscle pain, but about weakness and stiffness. Sometimes there can be stiffness without identifiable weakness or pain. When I start patients on a statin, I mention that they may experience any 1 or a combination of these 3 symptoms. I always make it a point to ask my patients about those 3 symptoms as I follow them in the clinic.

I measure CPK prior to starting statin treatment, and then, rather than measuring follow-up CPK levels routinely, I do so only when a patient presents with symptoms suggestive of myopathy. The reason for this is that CPK levels vary tremendously from day to day, and one may see a spurious elevation of CPK that has nothing to do with statin-based myopathy. If a patient has convincing myopathic symptoms but a normal CPK, I will defer to the patient and treat it as a true case of myopathy. If, in contrast, the CPK is clearly elevated but the muscle symptoms are somewhat equivocal, then the CPK elevation can be helpful to determine whether or not the patient has a true myopathy. Also, the degree of CPK elevation can be useful in estimating the severity of a myopathy.
Some physicians and lipidologists do not measure CPK at all, because the correlation is fairly poor between CPK levels and symptoms, but I find it useful for the above reasons. In any case, however, one should not rely on the CPK level to diagnose myopathy, because even a relatively severe case of myopathy may have normal or minimally elevated CPK.

Medscape: Can CPK be used to exclude patients from starting a statin?
                       
Dr. Brinton: A patient with a very high CPK elevation initially should not be started on a statin. This is another reason to measure CPK at baseline. The upper threshold for a clinically significant CPK is quite high, 10 times the upper limit of normal, because CPK levels are so variable. If a patient develops a CPK over 10 times the upper limit of normal on statin use, you should stop statin therapy, at least temporarily, and consider either lowering the dose or switching to a different statin. In rare cases, for example, in a patient with a history of rhabdomyolysis, one may need to abandon the statin class altogether, even perhaps without trying other available statins.

Medscape: Are there other signs that would exclude a patient from treatment with a statin?
                       
Dr. Brinton: Individuals with chronic active hepatitis are not good candidates for statin therapy. But one subset of patients with hepatitis -- those with nonalcoholic steatohepatitis (NASH), where the hepatitis is due to fatty infiltration of the liver -- may actually improve with a statin or other lipid-lowering agent.

Medscape: If CPK levels become elevated once a patient has started on a statin, do you always stop the drug?
                       
Dr. Brinton: There are several different levels of action one can take if one suspects myopathy. If the myopathy appears to be mild or equivocal, the best action may simply be to continue the statin and monitor the patient without reducing the dose.

A second option, for slightly more severe but still relatively mild cases, is to stop the statin temporarily and allow the symptoms to resolve. This also will allow a CPK elevation, if present, to normalize. Later one can rechallenge the patient at the same dose of the same drug. This approach can be useful in cases where the statin may not have been responsible for the myopathy.

In a third scenario, where the symptoms are more severe and the case is more troubling biochemically and/or clinically, one may conclude that the particular dose of that particular statin is no longer tenable. If this occurs at a high statin dose, one can consider giving a lower dose of the same statin or switching to a different statin. There are few published data about switching statins in this way, and most of our experience is anecdotal, but I can say that switching to a different statin often resolves the symptoms.

Finally, as I mentioned earlier, there are cases of myopathy so severe that one does not dare go back to any dose of any statin.

Medscape: How often are the symptoms of myopathy simply due to negative expectations on the part of the patient?
                       
Dr. Brinton: One very interesting aspect of statin therapy is that physicians are pretty much required to create an adverse expectation, or negative placebo effect, when initiating statin therapy. This is true primarily for myopathy but can occur with other safety questions as well. Most of our patients know already that statin safety is an issue, but whether they do or not, as we start a patient on a statin for the first time, we are obligated to point out its possible adverse symptoms and effects. We must describe the symptoms of myopathy and ask patients to watch out for them. We also need to inform the patient of the possibility of liver dysfunction and perhaps other potential adverse events. Such warnings give patients the expectation that they are going to have a problem, and probably make it more likely that they will have adverse symptoms.

Patients' heightened awareness of the risks of statin therapy is good in the sense that if something truly bad happens, they are more likely to notice it early and contact us promptly. But it also means that when a patient reports muscle symptoms, we do not always know if myopathy is really present. Everyone has aches and pains; and so their association with drug treatment is often open to question. So we are setting up our patients to find something that may not truly exist. The good news, however, is that we can turn the effects of our suggestions to our advantage when and if a patient reports symptoms of myopathy. We do this by explaining that the myopathy often resolves with whatever course of action we have chosen from the several options I mentioned earlier. Whether we have the patient continue, temporarily stop, reduce the dose, change drugs, or stop statins altogether, we suggest that his/her symptoms will improve soon. We thus create a positive placebo situation. When the patient hears from his trusted healthcare provider that his symptoms are likely to get better, it becomes much more likely to occur.

Obviously we will not ignore a true myopathy, but it is reasonable to try to reverse any negative anticipation on the part of the patient, which may worsen any symptoms otherwise present.

Medscape: How do the statins compare in their propensity for inducing myopathy?
                       
Dr. Brinton: First, we have to acknowledge that despite the clinical importance of statin-induced myopathy, we understand very little about its causes, which makes it hard to develop good treatments or preventive strategies.

Statin-induced myopathy is strongly dose related, so low doses of a given statin are usually much less likely to cause myopathy than high doses. For this reason, and perhaps because muscle benefits from statin-free periods of recovery, every-other-day dosing of a statin can be helpful in reducing muscle symptoms. This dosing regimen may be especially attractive for a statin with a longer half-life, or for a sustained-release formulation, where the longer dosing interval may still provide relatively continuous suppression of hepatic cholesterol synthesis, and hence still provide effective cholesterol lowering.

There are differences among the statins in terms of their propensity to cause myopathy. The statins that carry a higher than average overall risk are among the more potent: lovastatin (Mevacor, Merck; Altocor, Andrx; and generic) and simvastatin (Zocor, Merck). Myopathy risk is not, however, simply directly proportional to cholesterol-lowering efficacy, since it appears to be relatively low with atorvastatin (Lipitor, Pfizer), and may not be elevated with rosuvastatin (Crestor, AstraZeneca), which are the most effective for LDL cholesterol lowering. By contrast, the 2 statins that appear to have lower-than-average risk of myopathy are fluvastatin (Lescol, Reliant) and pravastatin (Pravachol, Bristol-Myers Squibb). These can be especially useful in patients with symptoms or risk of myopathy.

Pravastatin has been considered by many as the only safe statin with regard to myopathy. Evidence in the scientific literature, however, is actually stronger for fluvastatin as having the lowest myopathy risk. There are few comparative data between fluvastatin and pravastatin, but in the Assessment of Lescol in Renal Transplantation (ALERT)^[2] study, fluvastatin passed perhaps the most severe test of myopathy risk. That trial included more than 2000 patients who had undergone renal transplantation and were taking cyclosporine. Half of these, or about 1000 patients, also took fluvastatin.
Surprisingly, over several years of follow-up, the patients receiving both cyclosporine and fluvastatin were at no higher risk for myopathy than those on placebo. This is impressive evidence for a low myopathy risk with fluvastatin. We are often looking to use statins in such high-risk patients, and so the ALERT data are very encouraging with regard to the use of full-dose fluvastatin for atheroprevention when the risk of drug-drug interaction is high.

Medscape: What about other drug interactions?
                       
Dr. Brinton: Fluvastatin and pravastatin each appears to have fewer drug-drug interactions than other statins. Although some clinicians have felt that the safety of pravastatin was primarily due to its water solubility, the other water-soluble statin, rosuvastatin, has yet to be fully proven as safe. Moreover, fluvastatin, which is not water soluble, has excellent safety data, few potential adverse drug-drug interactions, and appears to be as safe as, or even safer in many contexts than pravastatin.
Mention has been made in the scientific literature about the risk of myopathy when the dosage of a statin is increased in patients concurrently receiving niacin. Interestingly, however, there is a Food and Drug Administration (FDA)-approved tablet (Advicor, Kos) that combines extended-release niacin (Niaspan, Kos) and generic lovastatin, and appears to carry no excess myopathy risk. Use of any combination therapy for lipid disorders should not be done in a cavalier manner, but the added risk of myopathy with niacin plus a statin appears to be at least as low as it is for fenofibrate.
Gemfibrozil is a very commonly used fibrate that is inexpensive and well proven to reduce coronary heart disease (CHD) events. However, it increases circulating statin levels and possibly CPK levels and muscle symptoms when administered with all the statins except fluvastatin. So fluvastatin is particularly useful in this situation. By contrast, the other fibrate available in the United States, fenofibrate, appears to be safe in combination with all statins. Unfortunately, it is more expensive and less widely available on managed care formularies. Also, its ability to reduce CHD events is not as well proven.

I should also mention that the bile acid sequestrants have a likely adverse interaction with statins in that if they are taken at the same time as the statin, they may reduce its absorption. This is also true of many other medications. Otherwise, however, there are no safety or toxicity issues surrounding the concurrent use of bile-acid sequestrants and statins. The intestinal cholesterol absorption inhibitor ezetimibe (Zetia, Merck/Schering Plough) has no adverse interaction with statins. Specifically, the likelihood of statin myopathy is not increased by concurrent ezetimibe use and any effects on liver dysfunction are very small. If anything, ezetimibe may reduce myopathy risk by allowing a reduction in the statin dose needed for a given patient.

Medscape: How do you follow transaminases in patients on statins?
                       
Dr. Brinton: We measure transaminases at baseline, either alanine aminotransferase or aspartate aminotransferase or both. If one reading is > 3 times the upper limit of normal, a statin should not be started except to treat NASH. Follow-up usually consists of another transaminase at the next visit, usually after 2 or 3 months. If a transaminase elevation occurs, it usually happens early in the course of the statin use, so a single measurement after starting the statin is usually sufficient. The one exception to this rule is a patient with underlying liver disease or a high risk of it, such as a binge drinker. In lower-risk patients, transaminases need be measured in follow-up primarily only if the statin dose is increased, if the patient is switched to another statin, or if another medication like niacin, a fibrate, or ezetimibe is added.

Medscape: Which patients are more likely to have elevations of transaminases while on statins?
                        
Dr. Brinton: Risk factors for transaminase elevation are advanced age, female gender, alcohol use, and prior history of hepatitis.

Medscape: What do you do in a case of transaminase level elevation?
                       
Dr. Brinton: The approach is much the same as it is for myopathy. One has several options. If the elevation is minor, one can continue the statin and check the transaminase levels again. If the elevation is more significant, one can stop the drug and then consider rechallenging the patient at the same dose. If it is more severe, one can lower the dose of the same statin since transaminase elevations are usually dose-related. Finally, one can switch to a different statin. Of course, one can always try to reduce or eliminate the adverse effects of other hepatically adverse factors, such as other hepatotoxic drugs. There does not appear to be any large difference among statins in terms of risk of transaminase elevations.

Medscape: What are the properties of statins that affect their safety profile?
                       
Dr. Brinton: The statins that are metabolized through the cytochrome P450 3A4 systems are more prone to drug-drug interactions because so many medications use the same pathway. Other cytochrome P450 pathways are much less problematic. Two statins are available in extended-release formulation: fluvastatin (Lescol XL, Reliant) and lovastatin (Altocor, Andrx). Both probably reduce the tendency for systemic complications of the drug, such as myopathy and possibly other drug-drug interactions. This is especially important when choosing a statin for a patient who may be at elevated risk of 1 or more drug-drug interactions, due to polypharmacy, frailty, or advanced age.
Both fluvastatin and rosuvastatin are metabolized primarily by the cytochrome P450 2C9 pathway, yet they appear to have different safety profiles. We do not know why this might be. We have much safety evidence for fluvastatin, but little so far for rosuvastatin. Recent concerns about an apparent excess of myopathy induced by high-dose rosuvastatin have prompted the European Union (EU) to make its label for rosuvastatin more conservative regarding the recommended starting doses. Although this only brings the EU label closer to the existing US label for this agent, the FDA has felt the need to alert healthcare practitioners to carefully follow US label instructions to reduce myopathy risk.

Medscape: Are there other safety concerns with the statins?
                       
Dr. Brinton: Just about any drug can cause headache, skin rash, fatigue, and malaise, but statins do not cause these any more than placebo. One or two earlier studies suggested that statins increase the risk of cancer, but more recent reviews show no increase in any cancer with any statin.^[3]
                       
Medscape: What is the rationale for combination therapy in treating dyslipidemia?
                       
Dr. Brinton: Combination therapy is, I believe, the wave of the future for the management of dyslipidemia. First, we are learning more and more about the benefits of LDL-cholesterol lowering. We have long known that LDL-cholesterol levels strongly predict CHD risk, but we are continually seeing new data suggesting that the lower the level of LDL-cholesterol, the better. Which is not to say that we should treat every patient to lower his or her LDL-cholesterol to, say, 40 or 50 mg/dL, but in patients at unacceptably high risk, more aggressive LDL-cholesterol lowering can be useful.
Even with more effective statins, cost, safety, and logistical concerns often make it impossible to attain the desired level of LDL cholesterol with statin monotherapy. The problem is that doubling the dose of any statin gives only about an additional 6% LDL-cholesterol-lowering effect, while that same doubling may bring a significant increase in cost, and a geometric rise in potential toxicity. An exception to these rules about uptitration is fluvastatin in the extended-release formulation (Lescol XL) at the 80-mg dose, which is the dose and formulation of this agent most often used. In this one case, you actually pay less to uptitrate a statin. Second, there is no increase in safety concerns with this dose and formulation compared to lower doses of fluvastatin or other statins. It may, in fact, be the safest statin of all. Third, as an extended-release formulation, it has more LDL-cholesterol-lowering efficacy than the immediate-release form.

Medscape: Are there benefits of statin combination therapy beyond greater LDL-cholesterol lowering?
                       
Dr. Brinton: There are other, independent benefits of combination therapy in terms of atheroprevention. For example, we know that niacin lowers lipoprotein (a) and that statins do not. So adding niacin to a statin will give that added dimension that you cannot get from a statin. In addition, niacin would be much more effective in raising HDL cholesterol than any statin. For triglyceride lowering, a fibrate is more effective than a statin. Even though niacin is comparable with statins in terms of its triglyceride lowering, adding niacin to a statin will give more triglyceride lowering than a statin alone. Ezetimibe, which is a not a very potent HDL-cholesterol-raising or triglyceride-lowering drug, will add to the HDL-cholesterol-raising effect and the triglyceride-lowering effect of statins, just as it adds to the LDL-cholesterol lowering.

Another advantage for combination treatment is in atheroprevention. Most statins reduce cardiovascular events by 20% to 35%. Studies of combination therapy have generally shown an event reduction of 70% to 90%, and even though we cannot extrapolate directly from this, clinical data strongly suggest that combination therapy is much more efficacious in reducing cardiovascular events, which is not surprising given that the lipid-lowering effect is much greater. Thus, almost without exception, adding an agent to a statin will give at least additive lipid benefit, and in some cases an additional benefit that a statin cannot give. As we learn more and more about atheroprevention and have more targets for therapy and more aggressive goals with those targets, combination therapy will become more and more appealing, not only in terms of efficacy with regard to lipids and atheroprevention, but also from a safety standpoint.

Combination therapy has not been widely used in the past, but it is increasing and I anticipate that it will continue to increase. Only 1 combination tablet is currently available in the United States, lovastatin plus extended-release niacin (Advicor, Kos), which produces more LDL-cholesterol lowering and a greater increase in HDL-cholesterol than either agent alone. There is indirect evidence that it may be effective in terms of event reduction. Another combination tablet that will be available soon in the United States, simvastatin plus ezetimibe (Vytorin, Merck/Schering Plough), is very promising.

Not every patient who needs to be treated for dyslipidemia should get 2 or more drugs, but in general we are undertreating our patients. Combination therapy is often a much better way to increase treatment benefit than uptitration of statin monotherapy.

Medscape: With safety in mind, what is your opinion about the possibility of statins being made available over the counter (OTC)?
                       
Dr. Brinton: The FDA is currently considering whether statins should be made available without a prescription in the United States. OTC status would make statins more widely accessible and more widely used, which would address one of the biggest single problems with statins in this country, which is that they tend to be underutilized.

Despite that major advantage, however, there are a number of serious objections to making them available over the counter, the first of which is the safety issue. Although statins are quite safe, the safety issues are best addressed by a physician or other licensed healthcare provider. Even though I am confident that the vast majority of patients would have no safety problems with OTC statins, I believe that many significant and even severe safety problems would arise that could not be handled by laypersons. Another disadvantage is that statin use is always based on baseline lipid levels and the availability of OTC lipid testing is somewhat limited and problematic. I am certain that cholesterol testing performed by regular laboratories in a controlled setting with proper standards and controls is far superior to the type of testing that a patient could do at home.

Other issues that would arise with OTC status are related to coordination of treatment of dyslipidemia with other atheropreventive measures. I believe that there is much benefit in having healthcare professionals involved in issues such as diet and exercise, smoking cessation, treatment of obesity, insulin resistance, diabetes, and hypertension, and in the screening for progression of disease. Other serious concerns would be that statins might be used inappropriately, such as by someone who does not need them, or there could be overtreatment or inappropriate choice of a statin. This currently happens only rarely.

And so there are many reasons why the movement to make statins available over the counter is a bad idea. I am very much in favor of patient empowerment and involvement, but I believe that because of the complexities of atheroprevention in general and lipid treatment in particular, we are ill-advised to make these very powerful medications available to the general public without proper supervision by a physician.

Conclusion

As a class, the statins are remarkably safe and their use in patients who need LDL lowering for atheroprevention has a very high benefit/risk ratio. But because they are most commonly used in older patients with complicated health histories, and because of heightened public concerns, we must always remember to address several safety issues when prescribing statins. Although there is increasing impetus toward more and more aggressive lipid-lowering therapy, we need to keep the following always in mind:

Safety, cost, and efficacy considerations often point to: Use of lower doses of a given statin and/or Use of safer statins such as fluvastatin and pravastatin; and Use of other agents (ezetimibe, niacin, fibrates, and/or sequestrants) in combination with statins for greater LDL-lowering and/or other lipid benefits When starting statins, patients must always be informed of potential safety risks, and any symptoms or signs of adverse effects must be taken seriously and handled properly. ===================================================================== Read the complete article here.

So is niacin a dead drug? Dayspring

Commentary on Niacin’s Effect on Lp(a) in AIM HIGH

Here are my thoughts as a clinical lipidologist (By: Thomas Dayspring, MD, FACP, FNLA, NCMP)

We must get apoB (LDL-P) to goal in all at-risk patients. Lifestyle therapies and statins are the mainstay of therapy. However residual risk is high if apoB (LDL) remains elevated despite at-goal LDL-C, non-HDL-C), any level of HDL-C or if Lp(a) mass is elevated.

So I would have no hesitancy in adding niacin to high and very high risk patients who have not achieved apoB (LDL-P) goals with whatever therapies they are using or using niacin as a monotherapy in those intolerant of other apoB lowering meds.

Data from HPS THRIVE 2 (discussed in a recent commentary) suggested statin plus ezetimibe was better at event reduction than statin plus niacin [9]. In view of that and the very significant side effects reported in HPS THRIVE 2 [bleeding (GI, intracranial, other) in the niacin group: 326 (2.5%) to 238 (1.9%) and infection 1031(8%) to 853 (6.6%)] [3] makes niacin a tertiary or quaternary add-on drug (some may prefer the bile acid sequestrant colesevelam as an apoB lowering medication).
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Niacin’s Effect on Lp(a) in AIM HIGH - Dayspring

Commentary on Niacin’s Effect on Lp(a) in AIM HIGH
    

By: Thomas Dayspring, MD, FACP, FNLA, NCMP

 

In 2013 we have already published two commentaries on niacin (Commentary on Niacin vs Ezetimibe as add on to Statin) and (Examination of the Recently Announced Preliminary Results of the HPS2-THRIVE Study), specifically extended release available as Niaspan, a seemingly potent lipid- and lipoprotein-modulating drug that dates back to the 1960’s. Initially it was used to reduce elevated cholesterol levels but eventually it was found to also raise HDL-C which for a variety of reasons was assumed to be very desirable (thought being that if low HDL-C is a strong CV risk factor, then raising it must be beneficial).  Also of interest was niacin’s ability to significantly reduce lipoprotein (a) mass [Lp(a)]. Indeed, a group entitled European Atherosclerosis Society Consensus Panel issued a statement strongly advising niacin be used for CV benefits in patients with elevated Lp(a) [1]. Interestingly that panel noted there was virtually no clinical trial support for this recommendation other than the fact that niacin does indeed reduce Lp(a) mass. Most lipidologists agreed with the belief that even if reducing Lp(a) does not matter, niacin would at least reduce apolipoprotein B (apoB) which is seemingly always desirable. NCEP ATP-III simply advocated achieving LDL-C goals in persons with risk related to Lp(a) issues. 

 

 

 

 

Recent trials [The Atherothrombosis Intervention in Metabolic Syndrome with Low HDL/High Triglycerides: Impact on Global Health Outcomes (AIM HIGH) and large Heart Protection Study 2: Treatment of HDL to Reduce the Incidence of Vascular Events  (HPS THRIVE 2)] have not shown additional event reduction in well-treated patients with stable CHD related to adding niacin to a statin or statin/ezetimibe regimen [2,3]. To say the results of those studies were a shock to the lipidology community is an understatement. AIM HIGH (all of the patients had low HDL-C at baseline) was published first and for those who believed niacin’s benefit was related to raising HDL-C, the results were a punch to the jaw. Despite a substantial (25%) HDL-C increase (remember the old well accepted but never proven caveat that for every 1% rise in HDL-C there is a 3% event reduction) there was no CV outcome improvement. The usual side effects associated with niacin were present including a questionable nonsignificant rise in ischemic stroke. Then along came the still not published HPS THRIVE 2 (baseline HDL-C was not an enrollment criteria) where again the addition of niacin to a statin or statin/ezetimibe regimen provided no additional outcome benefit. Common to both AIM HIGH and HPS THRIVE 2 was the fact that the lifestyle with statin or statin/ezetimibe had normalized LDL-C, non-HDL-C and apoB. Thus niacin was being added to patients who were at those goals (keeping in mind that there is no NCEP ATP-III goal for HDL-C). Should we really have expected niacin, whose primary mechanism of action is to lower apoB (or its lipid surrogates) to do anything to CV events in persons with normal apoB?  The answer is yes if raising HDL-C or lowering Lp(a) mass is critical to event reduction (well accepted concepts that have never ever been proven in any type of trial). Well we may have those answers now and at this point one has to reasonably conclude the evidence is strong that in patients on LDL-receptor inducing drugs (statins or statin + ezetimibe) raising HDL-C (note – niacin also raises apoA-I, but not apoA-II or total HDL-P) [4] or reducing Lp(a) mass with niacin provides no benefit in folks who are at apoB (LDL-C, non-HDL-C) goal.

 

In AIM HIGH baseline apoB and apoA-I levels were low and baseline Lp(a) was elevated at 33.8 nmol/L [using Caucasian adult data from Framingham as a comparator, Lp(a) averaged 20 nmol/L]. Nearly 30% of AIM HIGH patients had severe Lp(a) elevations > 100 nmol/L compared to 20% of Framingham cohort. The addition of niacin to statin or statin + ezetimibe raised HDL-C by 25%, apoA-I by 7% and reduced LDL-C by 12%, TG by 30% and apoB by 13%. [5]

 

Lp(a) as expected was significantly associated with CV events despite the fact that LDL-C was at goal and thus elevated Lp(a) is associated with residual risk. A one standard deviation of Lp(a) was associated with a 21% increase in CV risk. There was a 21% overall reduction [but with a 20%, 39% and incredible 64% decreases in patients at the 50^th, 75^th and 90^th percentile cut points] in Lp(a) in the niacin group compared to 6% in placebo group. So the higher the Lp(a) level, the more dramatic was niacin’s ability to lower it.  Here is the shocker: there was no difference in event rate between those on or not on niacin (remember all were statin or statin + ezetimibe) DESPITE GREATER DECREASES in Lp(a) for those using niacin. Even in those in the highest Lp(a) quartile (> 125 nmol/L) there was no reduction in events when niacin was added.

 

So where do we stand with niacin? There is no level one evidence anywhere supporting the use of niacin to reduce clinical events: The Coronary Drug Project (CDP) is often quoted as proof of niacin’s efficacy but few realize that niacin monotherapy (high dose of immediate release preparation) had no impact on the primary endpoint of the study (mortality): thus the benefit of reducing non-fatal myocardial infarction (a secondary endpoint) makes this benefit hypothesis generating [6].Of course there is the famous 15 year follow up of CDP which encompassed 6 years of the trial where niacin was used and then a subsequent 9 year period off niacin. Mortality was significantly reduced in that post hoc analysis (data derived not from examination or in person review but questionnaires sent to participants): this is the weakest data imaginable [7]. So this supposedly late benefit of niacin is in fact analysis of post hoc follow data up from a trial where niacin failed to reduce the primary endpoint. If niacin was a new drug, it would have no prayer of gaining FDA approval based on the CDP. Several subsequent trials using angiographic or CIMT endpoints showed niacin monotherapy or combination with bile acid sequestrants or statins showed imaging benefit. One small (~500 patients) open-label outcome trial (Stockholm Ischemic Heart Disease Secondary Prevention Trial), combining clofibrate and IR niacin did reduce clinical events with statistical significance [8].

 

In my opinion niacin became a major lipid drug because of its ability to raise HDL-C and to lower Lp(a) and not for what is likely its real mechanism of action, namely lowering LDL-C and apoB and LDL-P. After extended-release niacin (Niaspan) hit the market, it was also heavily promoted because of its ability to increase both HDL and LDL size. KOS made a fortune by promulgating those messages as it seemingly made so much sense. Of course over time, we have learned that influencing LDL or HDL particle size or raising HDL-C and apoA-I has no effect on outcomes. Looking at lipid/lipoprotein risk factors in 2013 the outcome evidence only supports lowering apoB (LDL-P) or perhaps raising total HDL-P. At this time unfortunately, there is no support for reducing Lp(a) with niacin: admittedly the Lp(a) data from the much larger HPS THRIVE 2 study of 25,000 patients is pending.  

 

So is niacin a dead drug? Here are my thoughts as a clinical lipidologist: We must get apoB (LDL-P) to goal in all at-risk patients. Lifestyle therapies and statins are the mainstay of therapy. However residual risk is high if apoB (LDL) remains elevated despite at-goal LDL-C, non-HDL-C), any level of HDL-C or if Lp(a) mass is elevated. So I would have no hesitancy in adding niacin to high and very high risk patients who have not achieved apoB (LDL-P) goals with whatever therapies they are using or using niacin as a monotherapy in those intolerant of other apoB lowering meds. Data from HPS THRIVE 2 (discussed in a recent commentary [ADD LINK]) suggested statin plus ezetimibe was better at event reduction than statin plus niacin [9]. In view of that and the very significant side effects reported in HPS THRIVE 2 [bleeding (GI, intracranial, other) in the niacin group: 326 (2.5%) to 238 (1.9%) and infection 1031(8%) to 853 (6.6%)] [3] makes niacin a tertiary or quaternary add-on drug (some may prefer the bile acid sequestrant colesevelam as an apoB lowering medication).

 

What about our patients with elevated Lp(a) mass or Lp(a)-P? The only therapy that has so far shown an inkling of success is LDL apheresis. For now we should all try to lower apoB (LDL-P as aggressively as possible and that often requires multiple combination therapies. What about future drugs: just published is the  data the PCSK9 monoclonal antibody AMG 145 reduces Lp(a) by 32% in patients on statins [10]. There is also promising data that the remaining CETP inhibitors also reduce Lp(a) but the reality is that until such reductions by these drugs are linked to outcome benefit they are of hypothetical interest. Hopefully in the future there will also be development of an apoprotein (a) antisense oligonucleotide inhibitor. 

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References:

[1] European Atherosclerosis Society Consensus Panel. Lipoprotein(a) as a cardiovascular risk factor: current status. European Heart Journal 2010;31:2844–2853.

[2] The AIM-HIGH Investigators Niacin in Patients with Low HDL Cholesterol Levels Receiving Intensive Statin Therapy. N Engl J Med 2011;365:2255-67.
[3] Presentation by Jane Armitage on behalf of the HPS2 THRIVE group to the National Lipid Association Annual Scientific sessions, Las Vegas NV June 2013.

[4] Otvos, JD.The surprising AIM-HIGH results are not surprising when viewed through a particle lens. Journal of Clinical Lipidology (2011) 5, 368–370.

[5] John J. Albers, et al. Relationship of Apolipoproteins A-1 and B, and Lipoprotein (a) to Cardiovascular Outcomes in the AIM-HIGH Trial in press JACC 10.1016/j.jacc.2013.06.051

[6] Coronary Drug project group. Clofibrate and Niacin in Coronary Heart Disease. JAMA 1975;231:360-381.
[7] Fifteen Year Mortality in Coronary Drug Project Patients: Long Term Benefit with Niacin. JACC 1986;8:1245-55.
[8] Reduction of Mortality in the Stockholm Ischaemic Heart Disease Secondary prevention Study by Combined Treatment with Clofibrate and Nicotinic Acid. Acta Med Scand 1988;223:405-418.[9] Masana, A. Cabré, N. Plana. HPS2-THRIVE results: Bad for niacin/laropiprant, good for ezetimibe? Atherosclerosis 2013;229:449-450.

[9] Masana, A. Cabre, N. Plana. HPS2-THRIVE results: Bad for Niacin/laropiprant, good for ezetimibe? Atherosclerosis 2013; 229:449-450.

[10] Nihar R. Desai, et al. AMG145, a Monoclonal Antibody Against Proprotein Convertase Subtilisin Kexin Type 9, Significantly Reduces Lipoprotein(a) in Hypercholesterolemic Patients Receiving Statin Therapy. (Circulation. 2013;128:962-969.)

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