Pericardium is a tough double layered membrane which covers the heart. The space between these two layers is filled with pericardial fluid which protects the heart from any kind of external jerk or shock. There are two layers to the pericardial sac: the outermost fibrous pericardium and the inner serous pericardium. The serous pericardium, in turn, is divided into two layers, the parietal pericardium, which is fused to and inseparable from the fibrous pericardium, and the visceral pericardium, which is part of the epicardium. The epicardium is the layer immediately outside of the heart muscle proper (the myocardium.The visceral layer extends to the beginning of the great vessels, becoming one with the parietal layer of the serous pericardium. This happens at two areas: where the aorta and pulmonary trunk leave the heart and where the superior vena cava, inferior vena cava and pulmonary veins enter the heart.In between the parietal and visceral pericardial layers there is a potential space called the pericardial cavity. It is normally lubricated by a film of pericardial fluid. Too much fluid in the cavity (such as in a pericardial effusion) can result in pericardial tamponade (compression of the heart within the pericardial sac). A pericardiectomy is sometimes needed in these cases
3. Rule of Two’s
Double-layered: visceral=epicardium & parietal
Thickness=2 mm
Fibroblastic Parietal =Meshwork of 2 fibres
collagen (types I and III) and elastic.
Pericardial fluid volume=2x10 ml=20-30ml
Two sinuses=Oblique(4PV AND IVC-SVC)
& Transverse=AO and PA
Pressure in pericardium 2mmHg lower than
intrathoracic pressure.
Innervation :2=ANS(parasympathetic
( vagus)/sympathetic ( stellate ganglia) and somatic=
the phrenic nerve.
4. Embryology
From mesoderm (the pleuropericardial membranes)
that divide the primitive thoracic cavity of the
intraembryonic coelom into pericardial and pleural
compartments. The endocardial heart tube
invaginates into the developing pericardial cavity,
whereby the innermost serosal layer adheres to the
myocardium and then folds back onto itself to create
visceral and parietal layers.This process of
invagination eventually results in suspending the adult
heart within the developing pericardial cavity by blood
vessels at its cranial and caudal attachments.The
pericardium receives its blood supply via the internal
mammary artery. Phrenic nerves are enveloped in the
pleuropericardial membranes, and in the adult, reach
the diaphragm by traveling through the fibrous
pericardium .
5. Physiology
Pericardial fluid act as lubricant between visceral and parietal
layers to facilitate frictionless beating of the heart. The
intrapericardial fluid function as a reservoir of paracrinemodulators,
notably compounds such as prostanoids, natriuretic peptides, and
endothelins, that may regulate sympathetic tone, coronary
vasomotor tone, heart rate, and bloodpressure, but also
immunologically active moieties, such as complement factors.
Pericardial fluid is in equilibrium with pleural fluid, as there is
hydraulic conductance across the parietal pericardium when
intrapericardial pressures exceed pleural pressures.Numerous
attachments from the pericardium to other thoracic structures
secure the heart in place within the chest cavity. Cranially, the
reflections on great vessels interdigitate with vascular adventitia to
fasten the superior borders of the pericardium; a diaphragmatic
tendon anchors the caudal end.Ventrally the pericardium connects
with the interior of the sternum (superior and inferior
pericaridosternal ligaments), and dorsally it affixes to the
esophagus and spine.
6. Contd
The fibrous nature of the pericardium likely also serves as a
barrier to insulate the heart from exogenous tumors and spread
of infections.Despite its fibrous character, the pericardium rests
at slightly lower pressures (_3 to _6 mm Hg) compared to the
rest of the intrathoracic cavity and is able to transmit hanges in
intrathoracic pressures with respiration.Intact pericardium is
rather nondistensible and provides a strong mechanical
constraint on overall heart volume and chamber enlargement.
Important consequences of nondistensibility are equalizing
compliance of right and left ventricles as well as
interdependence of the cardiac chambers.Interdependence
occurs because total intrapercardial volume (namely pericardial
cavity and cardiac chamber volume) is fixed in the short term,
and expansion of 1 chamber necessarily impedes expansion of
another.
7. Contd.......
Especially as regards ventricular interdependence,acute
expansion of either right or left ventricular volume will impair
filling of the other chamber, at the limit resulting in signs such
as the pulsus paradoxus. The same principles apply in acute
pericardial effusion and tamponade physiology, because
there is very little reserve volume for expansion in the
pericardial space before intrapericardial pressure rises
Sharply. In situations where pericardial effusion develops
gradually,pericardial compliance can increase to
accommodate significant fluid volumes, often a liter or more.
Efferent painful stimuli (eg, inflammation, distention) are
carried via phrenic nerves and stellate ganglion; however, not
every surface of the pericardium is innervated. The
pericardium appears insensate to temperature and vibration.
8. Contd
Interdependence occurs because total intrapercardial volume
(namely pericardial cavity and cardiac chamber volume) is
fixed in the short term, and expansion of 1 chamber
necessarily impedes expansion of another. Especially as
regards ventricular interdependence,acute expansion of
either right or left ventricular volume will impair filling of the
other chamber, at the limit resulting in signs such as the
pulsus paradoxus. The same principles apply in acute
pericardial effusion and tamponade physiology, because
there is very little reserve volume for expansion in the
pericardial space before intrapericardial pressure rises
Sharply. In situations where pericardial effusion develops
gradually,pericardial compliance can increase to
accommodate significant fluid volumes, often a liter or more.
Efferent painful stimuli (eg, inflammation, distention) are
carried via phrenic nerves and stellate ganglion; however, not
every surface of the pericardium is innervated. The
pericardium appears insensate to temperature and vibration.
9. Congenital defects
Abse nce : “stabbing” chest pains with “heart
shifting
RBBB/Clo ckwise lo o p, levoposition and posterior
rotation,of the cardiac apex, as well as
pathognomonic interdigitation of lung tissue
between the inferior heart surface and diaphragm
as well as between the aorta and pulmonary
artery. “teardrop” shaped, because of atrial
elongation and ventricle widening in the absence
of typical pericardial tethering.
Pe ricardialMasse s(e m bryo nic co e lo m ic cavity. )
13. Pe ricardialEffusio ns
Mild:<5mm
Moerate:5-10mm
Severe(Tamponade)>10mm
In acute situation even mild may cause
tamponade
14. Pe ricarditis
Infiltration is the sine qua non of pericarditis
self-limited(mostly)
80-90% of cases are idiopathic,
“bread-and-butter pericardium”=supporation
Peri-infarction - 5%(TLT+) vs 10-20%(TLT-
Ve), Dressler’s < 1%
Dx:At least 2 of 4 cardinal features
16. The pericardial friction rub
A triphasic(50%) cadence with a discrete
“sandpaper” sound occurring with atrial
systole, ventricular systole, and early
ventricular diastole. 100% specific but
evanescent ,less sensitive.
19. Recurrent orRelapsing
Pericarditis
Latent periods of up to 6 weeks
12 weeks of therapy of NSAID in tappering
CORE trial:Colchicine (1-2 mg followed by 0.5 mg daily or twice
daily for 6 months; addition to high-dose aspirin therapy for first
recurrence of idiopathic,viral, or autoimmune pericarditis,24%
recurrence at 18 months as compared to 51% in the control, a two-
thirds reduction (10% vs 31%) in symptoms at 72 hours(CLASS I-
EHA)
Steroid for auto immuno causes-0.5mg-1mg/Kg
Intrapericardial corticosteroids(A single instillation of triamcinolone
(300
mg/m2 to 600 mg/m2 in 100 mL isotonic saline) over 24 hours on the
background of maintenance colchicine therapy prevented 84%
recurrences
at 1 year
Immunosuppresants:Cyclosporine /Azathioprine, remains
investigational.
20. Hemodynamic Consequences
Claude Schaeffer Beck (1894 – 1971) was
a pioneer American cardiac surgeon,
famous for innovating various cardiac
surgery techniques, and performing the
first defibrillation in 1947.[ He was the first
American professor of cardiovascular
surgery, from 1952 through 1965.
1930
21. Tamponade physiology
Resting intrapericardial pressure is 3 to 6 mm Hg
less than the diastolic pressures in the cardiac
chambers and thus does not affect intracardiac
blood flows with 2-4 mmHg respiratory variation.
Pericardial pressure at which the point where
cardiac filling is compromised.
Pericardial fluid becomes like a fifth cardiac
chamber, occupying space within the pericardium
and thus limiting the ability of atria and ventricles
to expand and fill appropriately ( impaired diastolic
compliance).
23. Contd........
Chamber-filling pressure is the ∆ between
intracardiac and intrapericardial pressures
Mean diastolic pressures equalize across cardiac
chambers as they need to exceed the increased
pressures in the intrapericardial space
Physiologicalventricular interdependence
becomes magnified due to isolation of the heart
from normal respiratory ∆
Inspiration will increase right-sided flows at the
expense of the left-sided chambers, thus reducing
left-sided flow
25. Contd....
Left- and right-ventricular filling pressures are usually elevated at 15-
20 mm Hg in tamponade. However, so-called low-pressure
tamponade with much lower ventricular filling pressures can occur in
patients with reduced blood volume, eg, dehydration, overdiuresis, or
hemorrhage.
26. A pulsus paradoxus ≥10 mm Hg a likelihood
ratio of 3.3 for the presence of tamponade
Value ≤10 confers a negative likelihood ratio
of
0.03
PP= 20 mm Hg ≥75% Tamponade
Palpable pulsus (or “total paradox”) in almost
20%
28. Pulsus suppression
RV or LV are markedly noncompliant= severe
left ventricular (LV) failure, right ventricular
hypertrophy, left ventricular hypertrophy, acute
myocardial infarction,severe aortic
insufficiency (elevated left ventricular end
diastolicpressure and damping of respiratory
variation), or in uremia, atrial septal defect (as
venous return is offset by right to left
shunting), and pericardial adhesions
29. QRS alternans
QRS alternans is present in 20% and total
alternans (of P, QRS, and T waves) in 8% of
patients.
Low voltage complex
32. Inflow and out flow doppler
Mitral 35% and aortic 25% variation
and TV=80%
33. Pe ricardialCo nstrictio n
≥ 5mm echo and ≥4mm CT(N=1-2mm,<4mm)
CP Physiology with non thickened 20%
Kussmaul’s sign(JVP distension in inspiration)
pericardial knock≥frequency than S3
Friedrich’s sign=Rapid Y descent of early
diastolic suction
“square-root”=sign of no further filling occurs
after early diastole
Equalized diastolic in all 4 chambers
36. CT Scan
CT is the best imaging
≥4 mm diagnostic
sigmoid-shaped ventricular septum
Persistent concordance of tagged signals
between the pericardium and the myocardium
during both systolic and the diastolic phases
is a sign of pericardial adhesions and is a
reliable sign of pericardial constriction.
37. CMRI+ CE T1 We ig hte d
More soft tissue clarification at more cost