Theoretical basics of clinical medicine
- lipidology
Ondrej Kyselak, M.D.
Dept. of Clinical Biochemistry,
St. Anne's University Hospital Brno
Introduction, basic terms
Dyslipidemia = deviation (↓/↑) in blood lipid
values. General term, which includes:
• Hypercholesterolemia
• Hypertriglyceridemia
… and less often:
• Rare forms of dyslipidemia
– familial hypercholesterolemia (FH)
– dysbetalipoproteinemia (DBL)
– familial deficit of lipoprotein lipase (LPLD)
Part I.
Metabolism of cholesterol
Cholesterol
Cholesterol
• steroid structure
Sources in human body:
• own synthesis… enzyme HMG-CoA reductase
(3-hydroxy-3-methylglutaryl coenzyme A
reductase)
• food intake
Why do we need cholesterol?
Many substances in our body are derived from
cholesterol structure:
• steroid hormones
– androgens – testosterone
– estrogens – estradiol
– gestagens – progesteron
• corticoids
– mineralocorticoids (aldosterone)
– glucocorticoids (cortisol, corticosterone)
• vitamins (vit. D)
• bile acids (cholic acid, deoxycholic acid)
Cholesterol is a part of cell membrane as well.
Why can be cholesterol dangerous?
• atherosclerosis (complex process in
attendance of immune system – foam cells,
pro-inflammatory cytokines)
• vessel injury by atherosclerotic plaques
• CVD, MI, stroke, PAD
How is cholesterol transported in the
blood stream?
• … by lipoprotein particles
Depending on density we distinguish
these groups of lipoproteins
• Chylomicrons
• VLDL particles (Very Low Density Lipoproteins)
• IDL particles (Intermediate Density
Lipoproteins)
• LDL particles (Low Density Lipoproteins)
• HDL particles (High Density Lipoproteins)
LDL vs. HDL particles
LDL particles
• cholesterol rich ones
• distribution of cholesterol to peripheral tissues
• strongly proatherogenic – too much of LDL-C
causes endothelial injury
HDL particles
• cholesterol poor ones
• transport of cholesterol from periphery to liver,
where cholesterol is metabolised
Remember
… molecule of cholesterol is still the
same. Biological effect in organism is
determined by the transport form (it
depends in which type of lipoprotein
particles – LDL/HDL the cholesterol is
contained).
Degradation of cholesterol
Part II.
Hypercholesterolemia
Hypercholesterolemia
Prevalence of hypercholesterolemia in the Czech
Republic (T-CH ≥ 5,0 mmol/l) 53,9 % (without
reference to gender) *)
Cholesterol values are dependent on age and
gender
---
*) WHO: http://www.who.int/en/
Dyslipidemia in Czech population
0
20
40
60
80
100
25 - 34 35 - 44 45 - 54 55 - 64
0
20
40
60
80
100
25 - 34 35 - 44 45 - 54 55 - 64
Males Females
Age groupsAge groups
% %
T-CH. > 5.0 or HDL-ch. < 1.0 or LDL-ch. > 3.0 or TG > 2 mmol/l
or lipid - lowering treatment
Hypercholesterolemia
Sub-type of dyslipidemia
• pathologically increased blood level of
cholesterol
• risk factor of atherosclerosis and CVD
2 groups of dyslipidemia:
• Polygenic
• Monogenic (inherited) – severe DLP
Polygenic hypercholesterolemia
• the most common in population
• influence of many genes with a small effect =
genetic predisposition and environment
(lifestyle)
Reduce weight is sooo easy
Familial hypercholesterolemia
• monogenic type of DLP
• frequency in population = 1:200 – 1:500
• mutation in DNA leads to defects in structures, which
are responsible for cholesterol metabolism
• genes for LDL receptor, apoB, PCSK9
• severe hypercholesterolemia – strongly proatherogenic
• patients with these mutations reach cumulative dose
of cholesterol very early – fatal MI, strokes in early age
(-teens)
• premature CVD in family history
Defective LDLR / apoB in patients with
FH
Cumulative dose of LDL – C
Part III.
Triglycerides
Triglycerides
• Type of blood lipids
• TGs contains glycerol esterified by fatty acids
(FA)
What are TGs good for?
• energetic pool (FA are energy - rich
substances).
• the only way how to store FA (and energy
contained in their structure) are TGs.
Typical patients with
hypertriglyceridemia are…
Poorly compensated diabetics and patients with affected glucose
metabolism – increased pool of glucose
Patients with increased alcohol consumption
• increased pool of acetyl-CoA = basic substance for lipid synthesis
• high concentration of FA (used for synthesis of TGs)
• alcoholic beverages (beer, wine) – highly caloric, provide
substrate for synthesis of TGs.
Patients with polygenic dyslipidemia
Obese patients (abundance of energetic substrates)
Clinical correlations of
hypertriglyceridemia
• slightly increased value of TGs (up to 10 - 11
mmol/l) = risk factor for CVD
• very high serum TGs > 11 mmol/l = RF for
acute pancreatitis*)
• incidence of AP caused by hyperTG 40 cases /
100 000 adults and year (data from US)**)
---
*) Kota SK, Jammula S. et al. Hypertriglyceridemia-induced recurrent acute pancreatitis: A case-based
review Indian J Endocrinol Metab. 2012 Jan-Feb; 16(1): 141–143.
**) Granger J, Remic k D., Acute pancreatitis: models, markers, and mediators. Shock. 2005 Dec;24
Suppl 1:45-51.
Acute pancreatitis
• very serious and acute situation!
• strict diet without any lipids!
• requires hospitalisation!
Acute pancreatitis
- Cullen´s sign
- Grey-Turner´s sign
Take home message
Hypercholesterolemia
• independent risk factor for
CVD (MI, stroke, PAD)
Hypertriglyceridemia
• mild = RF for CVD
• severe = RF for acute
pancreatitis
Part IV.
Fatty acids
FA – fatty acids
• mostly part of triglycerides
• source of energy
• substrate for synthesis of many other
substances
FA can be divided into many groups
Length of carbonaceous chain:
• short chain FA
• long chain FA – 12 and more carbons in chain
Number of double bonds in chain:
• SAFA (saturated FA)
• MUFA (monounsaturated FA)
• PUFA (polyunsaturated FA)
Configuration of FA chain
cis FA – plant lipids, oils
trans FA – less often, milk lipids
• toppings, chocolates , butter, beef.
• strongly proatherogenic
Cis x trans FA
Synthesis in organism
Essential FA:
• we´re not able to synthetize
• PUFA
• fish, plant oils
Non – essential FA
• we can synthetize
• SAFA, MUFA
• animal lipids
Sources of FA
Sources of FA
Part V.
Atherosclerosis, CV risk
Atherosclerosis
• vessel disease
• complex pathophysiological process (with
participation of immune system, proinflammatory
cytokines)
Storage of cholesterol
↓
Calcification
↓
Increases rigidity of arterial wall
Atherosclerosis
Arterial obliteration by atherosclerotic plaques
↓
Plaque rupture, thrombocyte activation, thrombus
↓
Arterial occlusion
↓
Ischemia of tissues behind the occlusion
↓
Tissue infarction if the blood stream is not restored
immediately
Atherosclerosis
Risk factors for atherosclerosis
Bad lifestyle:
• smoking
• alcohol consumption
• obesity
• kidney disease
• diabetes mellitus
• hypertension
• hypercholesterolemia
Estimation of Cardiovascular risk
• probability of fatal MI or stroke in 10 years
• SCORE charts (Systematic COronary Risk
Evaluation)
• need to know: sex, smoking habits, age,
systolic BP, T-CH value + other RF (individually
adjusting CV risk)
CV risk categories
• Low CV risk (up to 1 %)
• Intermediate CV risk (1-5 %)
• High CV risk (5 – 10 %)
• Very high CV risk (more than 10 %)
The higher CV risk, the lower value of cholesterol is
needed to be reached to protect arteries from the
damage by atherosclerotic plaques.
Smoking as a RF of CVD
• Smoking is a psychiatric diagnosis (ICD,
International Classification of Diseases: F17)
• Health problem (CVD, lung cancer, infection of
respiratory system, COPD, mental and physical
addiction
• Economic problem (price of cigarettes, costs
for treatment of one smoker)
• Social problem (smell, acceptation by non-
smokers)
Smoking and CV risk
• Smokers have a double CV risk compared to
non-smokers!
• Abandon smoking is the basic key to lower the
CV risk!
Hypothyreosis and DLP
Hypothyreosis can cause secondary DLP
• Thyroidal hormones are involved into
metabolism of nutrients in our body
• Low values of thyroidal hormones can slow
down metabolism of lipids.
Part VI.
How to diagnose DLP
How to make a diagnosis
• Anamnesis (premature CVD in family history)
• Clinical examination (presence of clinical sings
typical for DLP)
• Laboratory exams (+DNA analysis)
• Other methods (ultrasound of carotid arteries,
ergometer, calcium score, coronarography)
Anamnesis
• Focused on premature CVD in family history
(CVD in first – degree relatives before 55 years
of age in males and before 60 years of age in
females)
Clinical signs of HLP
Laboratory exams
• fasting: 12 hrs. prior examination without meal, drink
pure water
• 3 days prior examination stop drinking alcohol, stop with any
physical exercise
• don´t smoke before taking the blood samples
• use the pills (except of insulin → risk of hypoglycaemia)
• first examination – patient should be without hypolipidemics to
know origin values of lipids,
• control examination – patient should take prescribed lipid
lowering therapy regularly to see the effect of therapy
• avoid to examine lipid values during acute disease
Chylous serum
Which parameters to examine
• fasting plasma glucose
• kidney parameters (urea, creatinine)
• liver enzymes (AST, ALT, ALP, GGT)
• lipid spectre (TCH, LDL-CH, HDL-CH, TG,
apolipoprotein A, apolipoprotein B, non-HDL
CH)
• thyroidal parameters (TSH, peripheral
hormones)
DNA analysis
In case of suspiction of an inherited DLP:
• FH (genes for apoB, LDLR, PCSK9)
• familial dysbetalipoproteinemia (apoE)
• familial defective lipoprotein lipase (LPLD)
Lipoprotein ultracentrifugation
• enables to separate lipoprotein particles depending on
different density given by lipid/protein ratio
• with increasing density the size of lipoprotein particles is
getting smaller
• for this type of analysis is used very high gravity acceleration
• used as a diagnostic method for dysbetalipoproteinemia
Carotid ultrasound
• carotid arteries are well accessible, it is not invasive
• intima/media thickness, presence of atherosclerotic plaques
(detection of subclinical atherosclerosis)
• velocity and direction of the blood stream
Ergometer
• bicycle exercise
• monitoring of ECG, BP
• if ECG changes are present (arrhythmia, changes in ST
segment), than arterial coronarography should be performed
Selective coronarograpy
• detecting occlusions / obstructions in coronary arteries, which
can lead to coronary ischemia or myocardial infarction
• with contrast liquid
Advanced diagnostic technologies -
IVUS
• intravascular ultrasound
• direct exploration of coronary arteries with using ultrasound
probe
• evaluating lumen of arteries, presence of atherosclerotic
plaques, quality of coronary arteries
Part VII.
Target levels of cholesterol
Guidelines
Target levels of LDL-C
• recommended by ESC/EAS guidelines 2016
• „safe“ values of LDL-C when progression of
atherosclerosis is slowed down or stopped (in
optimal case)
LDL-C target levels
The higher CV risk
↓
the higher probability of acute CVD (MI, stroke)
↓
more aggressive hypolipidemic treatment is
needed to reach the low levels of LDL-C to
protect arterial damage
LDL-C goals (simplified)
Low + intermediate CV risk
• LDL-CH < 3,0 mmol/l
High CV risk
• LDL-CH < 2,6 mmol/l
Very high CV risk
• LDL-CH < 1,8 mmol/l
Concept of treatment
LDL-C:
The lower, the better
Part VIII.
Therapeutic options, modifying CV
risk, elimination of RFs
Changes in lifestyle only
(without LLT – lipid lowering therapy)
• ESC/EAS guidelines: patients with CV risk
< 5 % (without any other RFs, which would
rise up the CV risk)
• diet + physical activity, weight reduction
Modifying CV risk, elimination of RFs
We can affect:
• Smoking – decrease CV risk up to 50 %
• Hypertension (can be treated)
• Cholesterol (can be decreased – with or without
LLT)
Other RFs:
• DM (can be treated)
• Hypothyreosis (can be treated)
We can´t affect
• Sex
• Age
• DNA (not yet)
Smoking
Why do I want to stop smoking?
• because of me (health risk, social handicap,
social isolation from non-smokers, financial
burden)
• because of the others (smell, health risk –
passive smoking)
Abandonment of smoking has usually higher
impact than making cholesterol levels lower.
Social isolation –
„cage“ for smokers?
Just chose your own way
Diet recommendations
Diet recommendations
Reduce intake of:
• saturated lipids (FA) (fried food, butter,
chocolate topping, sweet creams, cakes…) …it
contains lot of saturated FA, which are
strongly proatherogenic
• sugar (sweet bakery products, cookies,
sweetened beverages!)
Lipids in nutrition
FA are rich of hydrogen (a lot of energy can be
released from their structures)
• need to receive essential FA from plant oils,
which we are not able to synthetize by
ourselves
• reduce intake of animal lipids in general
Sources of essential FA
Plant oils:
• flaxy
• rapeseed
• olive
• others (sunflower, soya…)
Olive oil is not so rich about essential FA.
Physical activity
Diet is very important part of lifestyle, but only
diet is not enough. It is better to combine it with
physical activity.
Diet + physical activity = weight reduction,
changing muscle/fat ratio in body
Part IX.
Lipid lowering therapy (LLT)
LLT
It doesn´t matter which kind of LLT is chosen,
healthy diet and lifestyle + physical activity is
essential for every patient with HLP.
LLT is recommended for patients with CV risk
(SCORE) ≥ 5 %, or in case of severe HLP (FH).
Statins
Fundamental drug for patients with
hyperlipidemia
• inhibitors of HMG-CoA reductase
• decreasing own production of cholesterol in
liver
• many data about statins from clinical trials
• effective and safe
Statins
Statin therapy, which makes LDL-C levels 1
mmol/l lower, decreases the CV risk in average
by 20 - 25 %.*)
---
*) Baigent C., Blackwell L., Emberson J. et al. Efficacy and safety of more
intensive lowering of LDL cholesterol: a meta-analysis of data from 170
000 participants in 26 randomised trials. Lancet 2010; 376: 1670 - 81.
Statin group of LLT
• Atorva - statin
• Simva - statin
• Fluva - statin
• Rosuva - statin
• Prava - statin
• Pitava - statin
Ezetimibe
Ezetimibe (Ezetrol®)
• inhibitor of absorption of cholesterol from
intestinal lumen to blood stream
• can be used in patients who don´t tolerate statins
• weak effect in monotherapy (cholesterol
synthesis in liver is compensatory increased)
• synergistic effect with statins (blocking two
metabolic ways of cholesterol – synthesis +
resorption from food)
Ezetimibe
IMPROVE-IT study
• patients with acute coronary syndrome in personal
history
• by adding ezetimibe to statin, the level of LDL-C was
decreased in average by 24 %. *)
• combination of simvastatin + ezetimibe significantly
decreased the risk of CV events *)
---
*) Cannon CP., Blazing MA., Giugliano RP. et al. Ezetimibe Added to Statin
Therapy after Acute Coronary Syndromes. N Engl J Med 2015;372:2387 - 97.
Resins
• bad taste
• weak hypolipidemic effect
• only for pregnant women and children with
severe HLP (FH)
• Cholestyramin (Vasosan P®)
PCSK9 inhibitors
PCSK9 = proprotein convertase subtilisin kexin
type 9. Fully humanised antibodies against
PCSK9
• evolocumab (Repatha®)
• alirocumab (Praluent®)
How does it work?
PCSK9 inhibitors
• decreasing LDL- C in average by 50 – 60 % *)
• used in combination with statins
• no adverse events known yet
---
*) Whayne TF. Jr. PCSK9 inhibitors in the current management of
atherosclerosis. Arch Cardiol Mex. 2016 Dec 27.
How to use it?
• subcutaneous injection once per 2-4 weeks
• prefilled pen
LLT for hypertriglyceridemia
• fenofibrate
• activator of PPAR – α (peroxisome proliferatoractivated
receptor-alpha)
• decreases levels of TGs by inhibition of their synthesis
and increasing of their clearance
• induces β – oxidation of FA and decreases their
availability for synthesis of triglycerides and for VLDL
particles
• stimulates activity of LPL, which attacks TGs.
• decreases risk of diabetic microangiopathy – benefit
for patients with DM
Polypills
• 2 or more drugs in one pill
• comfortable for patient, increases adherence
to therapy
Statins are available in combination with these
drugs:
• antihypertensives
• fibrates
Development of new drugs
• Modifying production of LDL particles on the
genetic level (silencing RNA – siRNA)
Part X.
Nutrition supplements
Nutrition supplements
• ω - 3 unsaturated FA
• red yeast rice
• plant sterols and stanols
Part XI.
The MedPed project
MedPed project
• Make early diagnosis to Prevent early deaths
in MedicalPedigrees
• active searching for patients with inherited
HLP. Making diagnose, perform treatment
• prevention of premature deaths due to acute
cardiovascular events
Thank you for your attention!
Ondrej Kyselak, M.D.
Dept. of Clinical Biochemistry,
St. Anne's University Hospital Brno
ondrej.kyselak@fnusa.cz