1999CHAPTER 265
as well as MV anatomy that would predict a >95% of a successful
and durable repair in a low surgical risk patient. These aggressive
recommendations for surgery are predicated on the adverse longterm consequences of waiting for LV function to decline further as
well as the outstanding results achievable with mitral valve repair by
reference surgeons at high-volume centers. Indeed, repair of myxomatous MR (e.g., prolapse, flail) in patients <75 years with normal
LV systolic function and no coronary artery disease (CAD) can
now be performed by experienced surgeons with <1% perioperative
mortality risk. The risk of stroke, however, is also ~1%. Repair is feasible in up to 95% of patients with myxomatous disease operated on
by a high-volume surgeon in a referral center of excellence. Repair
techniques include chordal transfer, creation of neochords, limited
leaflet resection, and insertion of an annuloplasty band. Long-term
durability is excellent; the incidence of reoperative surgery for failed
primary repair is ~1% per year for the first 10 years after surgery.
For patients with AF, left or biatrial maze surgery, or radiofrequency
isolation of the pulmonary veins, along with left atrial appendage
amputation, is performed to reduce the risk of recurrent postoperative AF and associated thrombus formation.
The surgical management of patients with secondary MR is more
complicated. Surgery for patients with ischemic MR most often
involves simultaneous coronary artery revascularization. Current
surgical practice includes either annuloplasty repair with an undersized, rigid ring or chord-sparing valve replacement for patients
with moderate or greater degrees of MR. Valve repair for ischemic
MR is associated with lower perioperative mortality rates than
valve replacement but significantly higher rates of recurrent MR
over time. Thus, replacement may be preferred over repair in this
context. In patients with ischemic MR and significantly impaired LV
systolic function (EF <30%), the risk of surgery is higher, recovery
of LV performance is incomplete, and long-term survival is reduced.
Referral for surgery must be individualized and made only after
aggressive attempts to improve symptoms with GDMT and CRT,
when indicated. The routine performance of surgical valve repair in
patients with significant secondary MR due to a dilated cardiomyopathy has not been shown to improve long-term survival compared
with optimal GDMT. Patients with acute severe MR can often be
stabilized temporarily with appropriate medical therapy, but surgical correction will be necessary emergently in the case of papillary
muscle rupture and within days to weeks in most other settings.
When surgical treatment is contemplated, left and right heart
catheterization and left ventriculography may be helpful in confirming the presence of severe MR in patients in whom there is
a discrepancy between the clinical and TTE findings that cannot
be resolved with TEE or CMR. Coronary angiography identifies
patients who require concomitant coronary revascularization.
TRANSCATHETER MITRAL VALVE REPAIR AND
REPLACEMENT
A transcatheter approach to the treatment of either primary or secondary MR may be feasible in selected patients with appropriate
mitral valve anatomy. One approach involves the deployment of a
clip delivered via transseptal puncture that grasps the leading edges
of the mitral leaflets in their mid-portion (anterior scallop to posterior scallop or A2-P2; Fig. 264-3). The length and width of the gap
between these leading edges, as well as other considerations such as
leaflet thickening and calcification, dictate patient eligibility. The clip
device for transcatheter edge-to-edge repair (TEER) is commercially
available for treatment of both primary and secondary MR in appropriately selected patients (Figs. 264-1 and 264-2). The results of transthoracic and transesophageal echocardiographic imaging are critical
to patient selection, along with a detailed assessment of surgical risk,
comorbidities, and the adequacy of GDMT for heart failure. The use
of TEER with a clip device in addition to medical therapy was shown
to be superior to medical therapy alone in a trial involving symptomatic heart failure patients with reduced EF and at least moderately
severe secondary MR. Patients treated with the clip device had fewer
heart failure hospitalizations and longer survival than those treated
medically. This was the first trial to show such benefit in patients with
secondary MR and has impacted clinical practice. Other transcatheter
approaches to mitral valve repair include the deployment of a device
within the coronary sinus that can be adjusted to reduce mitral annular circumference and the effective orifice area of the valve much like
a surgically implanted ring. Variations in the anatomic relationship
of the coronary sinus to the mitral annulus and circumflex coronary
artery have limited the applicability of this technique. Attempts to
reduce the septal-lateral dimension of a dilated annulus using adjustable cords placed across the LV in a subvalvular location have also
been investigated. Construction of neochords to the mitral leaflets
under TEE guidance using a system delivered via the cardiac apex is
also under study. Investigational experience to date with transcatheter
mitral valve replacement systems is in early clinical stages, although
the field is evolving rapidly.
■ FURTHER READING
Bonow RO et al: 2020 focused update of the 2017 expert consensus
decision pathway on the management of mitral regurgitation. J Am
Coll Cardiol 75:2236, 2020.
El Sabbagh A et al: Mitral valve regurgitation in the contemporary
era: Insights into diagnosis, management and future directions. J Am
Coll Cardiol Imaging 11:628, 2018.
Nishimura RA et al: Mitral valve disease. Current management and
future challenges. Lancet 387:1324, 2016.
Otto CM et al: 2020 ACC/AHA guideline for the management
of patients with valvular heart disease: A report of the American
College of Cardiology/American Heart Association Joint Committee
on Clinical Practice Guidelines. Circulation 143:e72, 2021.
Rugueiro A et al: Transcatheter mitral valve replacement: Insights
from early clinical experience and future challenges. J Am Coll
Cardiol 69:2175, 2017.
Stone GW et al: Transcatheter mitral valve repair in patients with
heart failure. N Engl J Med 379:2307, 2018.
FIGURE 264-3 Clip used to grasp the free edges of the anterior and posterior
leaflets in their midsections during transcatheter repair of selected patients with
mitral regurgitation. (MitraClip is a trademark of Abbott or its related companies.
Reproduced with permission from Abbott © 2021. All rights reserved.)
The role of the physical examination in the evaluation of patients with
valvular heart disease is also considered in Chaps. 42 and 239; of electrocardiography (ECG) in Chap. 240; of echocardiography and other
noninvasive imaging techniques in Chap. 241; and of cardiac catheterization and angiography in Chap. 242.
265 Mitral Valve Prolapse
Patrick T. O’Gara, Joseph Loscalzo
2000 PART 6 Disorders of the Cardiovascular System
MITRAL VALVE PROLAPSE
Mitral valve prolapse (MVP), also variously termed the systolic clickmurmur syndrome, Barlow’s syndrome (Fig. 265-1), floppy-valve syndrome, and billowing mitral leaflet syndrome, is a relatively common
but highly variable clinical syndrome resulting from diverse pathologic mechanisms affecting the mitral valve apparatus. Among these
are excessive or redundant mitral leaflet tissue, which is commonly
associated with myxomatous degeneration and greatly increased
concentrations of certain glycosaminoglycans. MVP is the most common abnormality leading to primary mitral regurgitation (MR) (see
Chap. 264).
In most patients with MVP, the cause is unknown, but in some, it
appears to be genetically determined. A reduction in the production
of type III collagen has been implicated, and electron microscopy has
revealed fragmentation of collagen fibrils.
MVP is a frequent finding in patients with heritable disorders of
connective tissue, including Marfan syndrome (Chap. 413), osteogenesis imperfecta, and Ehlers-Danlos syndrome. MVP may be associated
with thoracic skeletal deformities similar to but not as severe as those
in Marfan syndrome, such as a high-arched palate and alterations
of the chest and thoracic spine, including the so-called straight back
syndrome. Other associated features can include a history of inguinal
hernias, joint dislocations, meniscal tears, and easy bruisability.
In most patients with MVP, myxomatous degeneration is confined
to the mitral valve, although the tricuspid and aortic valves may also
be affected. The posterior mitral leaflet is usually more affected than
the anterior, and the mitral valve annulus is often dilated. In many
patients, elongated, redundant, or ruptured chordae tendineae cause or
contribute to the regurgitation.
A B
C
FIGURE 265-1 Congenital or developmental mitral valve prolapse. Myxomatous
thickening and prolapse of the mitral valve can occur in isolation in 2–3% of the
general population or may be associated with heritable collagen-vascular disorders
and aortic root dilation, such as in Marfan syndrome. Myxomatous degeneration
of the valve predisposes to severe regurgitation and chordal rupture and is a
frequent indication for mitral valve repair or replacement. Prolapse can affect
one or both leaflets, to varying degrees. A. Three-dimensional transesophageal
echocardiogram showing a myxomatous mitral valve from the left atrial en face
aspect. There is billowing and prolapse of the entire middle scallop of the posterior
leaflet (asterisk). (Figure courtesy of Douglas C. Shook, MD, Department of
Anesthesiology, Perioperative and Pain Medicine, Brigham and Women’s Hospital.)
B. The posterior leaflet of the mitral valve demonstrates marked prolapse and
hooding in all segments and severe redundancy in this photograph taken from the
vantage point of the left atrium. C. Opening the left heart reveals prominent mitral
leaflet hooding (arrows). The chordae are focally thickened but are not fused as
would be the case in rheumatic valve disease. (Used with permission from JC Wu,
RF Padera: Clinicopathologic correlates, in Atlas of Echocardiography, 2nd ed, SD
Solomon [ed], E Braunwald [series ed]. Philadelphia, Current Medicine Group LLC,
2008. p 363.)
MVP also may occur rarely as a sequel to acute rheumatic fever, in
ischemic heart disease, and in various cardiomyopathies, as well as in
20% of patients with ostium secundum atrial septal defect.
MVP may lead to excessive stress on the papillary muscles, which,
in turn, leads to dysfunction and ischemia of the papillary muscles
and the subjacent ventricular myocardium. Rupture of chordae tendineae and progressive annular dilation and calcification contribute to
valvular regurgitation, which then places more stress on the diseased
mitral valve apparatus, thereby creating a vicious cycle. ECG changes
(see below) and ventricular arrhythmias described in some patients
with MVP appear to result from regional ventricular dysfunction and
fibrosis related to the increased stress placed on the papillary muscles.
■ CLINICAL FEATURES
MVP is more common in women than men and occurs most frequently
between the ages of 15 and 30 years; the clinical course is most often
benign. MVP may also be observed in older (>50 years) patients, often
men, in whom MR is often more severe because of chordal rupture and
requires surgical treatment. There is an increased familial incidence for
some patients, suggesting an autosomal dominant form of inheritance
with incomplete penetrance. MVP varies in its clinical expression, ranging from only a systolic click and murmur with mild prolapse of the
posterior leaflet to severe MR due to chordal rupture and leaflet flail.
The degree of myxomatous change of the leaflets can also vary widely.
In many patients, the condition progresses over years or decades; in
others, it worsens rapidly as a result of chordal rupture or endocarditis.
Most patients are asymptomatic and remain so for their entire lives.
However, in North America, MVP is now the most common cause
of isolated severe MR requiring surgical treatment. Arrhythmias,
most commonly ventricular premature contractions and paroxysmal
supraventricular and ventricular tachycardia, as well as atrial fibrillation (AF), have been reported and may cause palpitations, lightheadedness, and syncope. Sudden death is a very rare complication
and occurs most often in patients with severe MR and depressed left
ventricle (LV) systolic function, although it can occur in individuals
with normal LV size and function. A small subset of MVP patients
with high-grade ventricular ectopy has been identified with phenotypic features including electrocardiographic inferior-apical T-wave
abnormalities, high-density premature ventricular complexes at rest,
mitral annular disjunction (defined as abnormal atrial displacement of
the mitral valve leaflet hinge point), and papillary muscle fibrosis on
cardiac magnetic resonance imaging with late gadolinium enhancement. In addition, there may be an excess risk of sudden death among
patients with a flail leaflet. Many patients have chest pain that is difficult to evaluate; it is often substernal, prolonged, and not related to
exertion, but may rarely resemble angina pectoris. Transient cerebral
ischemic attacks secondary to emboli from the mitral valve due to
endothelial disruption have been reported. Infective endocarditis may
occur in patients with MR and/or leaflet thickening.
Auscultation A frequent finding is the mid- or late (nonejection)
systolic click, which occurs 0.14 s or more after S1
and is thought to
be generated by the sudden tensing of slack, elongated chordae tendineae or by the prolapsing mitral leaflet when it reaches its maximal
excursion. Systolic clicks may be multiple and may be followed by
a high-pitched, mid-late systolic crescendo–decrescendo murmur,
which occasionally is “whooping” or “honking” and is heard best at
the apex. Radiation of the murmur will depend on the involved leaflet.
With posterior leaflet prolapse, the jet of MR is directed anteriorly and
the murmur will radiate to the base of the heart. With anterior leaflet
involvement, the jet of MR is directed posteriorly and the murmur will
radiate to the axilla and back. The click and murmur occur earlier with
standing, during the strain phase of the Valsalva maneuver and with
any intervention that decreases LV volume (preload), exaggerating
the propensity of the leaflet to prolapse. Conversely, squatting and
isometric exercises, which increase LV volume, diminish MVP; the
click-murmur complex is delayed, moves away from S1
, and may even
disappear. Some patients have a mid-systolic click without a murmur;
others have a murmur without a click. Still others have both sounds at
different times.
Tricuspid Valve Disease
2001CHAPTER 266
FIGURE 265-2. Barlow’s valve with classic mitral valve prolapse, as seen on
transthoracic echocardiogram in parasternal long-axis windows. Left: parasternal
long-axis window, showing both myxomatous leaflets billowing into the left atrium
in late systole. Right: same window with color Doppler showing significant mitral
regurgitation (arrow) in systole. (Courtesy of Justina Wu, MD, PhD.)
LABORATORY EXAMINATION
The ECG most commonly is normal but may show biphasic or inverted
T waves in leads II, III, and aVF and, occasionally, supraventricular or
ventricular premature beats. Transthoracic echocardiography (TTE) is
particularly effective in identifying the abnormal position and prolapse
of the mitral valve leaflets. A useful echocardiographic definition of
MVP is systolic displacement (in the parasternal long axis view) of the
belly of the mitral valve leaflets by at least 2 mm into the left atrium
(LA) superior to the plane of the mitral annulus. There can be prolapse
of one or both leaflets (Fig. 265-2). Color flow and continuous wave
Doppler imaging is helpful to evaluate the associated MR and provide
estimates of severity. The jet lesion of MR due to MVP is most often
eccentric, and assessment of the effective regurgitant orifice area and
regurgitant volume can be difficult with standard techniques. Both
three-dimensional echocardiography and cardiac magnetic resonance
imaging can provide more precise determinations of LV volumes.
Transesophageal echocardiography (TEE) is indicated when more
accurate anatomic information is required and is performed routinely
for intraoperative guidance during valve repair. Exercise testing can be
performed when there is uncertainty regarding functional capacity. It
is often combined with rest and immediate poststress TTE to assess LV
and right ventricular (RV) function and the dynamic nature of MR and
pulmonary artery pressures. Left ventriculography done at the time of
right and left heart catheterization is rarely necessary but can also show
prolapse of the posterior and sometimes of both mitral valve leaflets.
TREATMENT
Mitral Valve Prolapse
Infective endocarditis prophylaxis is indicated for patients with a
prior history of endocarditis. Beta blockers sometimes relieve chest
pain and control palpitations. Decisions regarding anticoagulation
for stroke prevention in AF should be based on the CHA2DS2-
VASc score and an assessment of bleeding risk. If the patient is
symptomatic from severe MR, mitral valve repair is indicated (see
Fig. 264-1). Other indications for surgery for MVP with severe primary MR include findings of established or progressive LV systolic
dysfunction. Surgery can also be considered for low-risk asymptomatic patients in whom a successful and durable repair can be
achieved with at least 95% likelihood by an expert surgeon. Mitral
valve repair is preferred over replacement in patients with MVP or
flail mitral leaflet (see Table 264-2); technical success is dependent
not only on the anatomic findings but also on the skill and experience of the surgeon. Repair of isolated posterior leaflet prolapse
is usually straightforward, but increasingly more complex pathologies (e.g., anterior leaflet prolapse, bileaflet prolapse, Barlow’s
deformity) require advanced skills. Careful pre- and intraoperative
TEE imaging is an important component of patient evaluation and
surgical planning. Transcatheter edge-to-edge repair (TEER) using
a clip to grasp the anterior and posterior leaflets together can be
considered for treatment of symptomatic patients at prohibitive
or high surgical risk with severe primary MR due to MVP (see
Fig. 264-3). Most often, the MR will be reduced in severity but not
eliminated. Nevertheless, symptom status and indices of LV size and
function can be improved with this approach, which is now offered
at >475 specialized sites in the United States. Reported hospital
mortality rates following the procedure are ~2%. Other transcatheter repair and replacement devices are not yet approved for clinical
use in the United States (see Chap. 264).
■ FURTHER READING
Dejgaard LA et al: The mitral annulus disjunction arrhythmic
syndrome. J Am Coll Card 72:1600, 2018.
Nishimura RA et al: Mitral valve disease. Current management and
future challenges. Lancet 387:1324, 2016.
O’Gara PT et al: 2017 ACC expert consensus decision pathway on
the management of mitral regurgitation. J Am Coll Cardiol 70:2421,
2017.
Otto CM et al: 2020 ACC/AHA guideline for the management of
patients with valvular heart disease: A report of the American College of Cardiology/American Heart Association Joint Committee on
Clinical Practice Guidelines. Circulation 143:e72, 2021.
TRICUSPID STENOSIS
Tricuspid stenosis (TS), which is much less prevalent than mitral stenosis (MS) in North America and Western Europe, is generally rheumatic
in origin and is more common in women than men (Table 266-1). It
does not occur as an isolated lesion and is usually associated with MS.
Hemodynamically significant TS occurs in 5–10% of patients with
severe MS; rheumatic TS is commonly associated with some degree
of tricuspid regurgitation (TR). Nonrheumatic causes of TS are rare.
■ PATHOPHYSIOLOGY
A diastolic pressure gradient between the right atrium (RA) and right
ventricle (RV) defines TS. It is augmented when the transvalvular
blood flow increases during inspiration and declines during expiration.
A mean diastolic pressure gradient of 4 mmHg is usually sufficient to
elevate the mean RA pressure to levels that result in systemic venous
congestion. Unless sodium intake has been restricted and diuretics
administered, this venous congestion is associated with hepatomegaly,
ascites, and edema, sometimes severe. In patients with sinus rhythm,
the RA a wave may be extremely tall and may even approach the level
of the RV systolic pressure. The y descent is prolonged. The cardiac
output (CO) at rest is usually depressed, and it fails to rise during
exercise. The low CO is responsible for the normal or only slightly elevated left atrial (LA), pulmonary artery (PA), and RV systolic pressures
despite the presence of MS. Thus, the presence of TS can mask the
hemodynamic and clinical features of any associated MS.
■ SYMPTOMS
Because the development of MS generally precedes that of TS, many
patients initially have symptoms of pulmonary congestion and fatigue.
Characteristically, patients with severe TS complain of relatively little
dyspnea for the degree of hepatomegaly, ascites, and edema that they
have. However, fatigue secondary to a low CO and discomfort due to
refractory edema, ascites, and marked hepatomegaly are common in
patients with advanced TS and/or TR. In some patients, TS may be suspected for the first time when symptoms of right-sided failure persist
after an adequate mitral commissurotomy.
266 Tricuspid Valve Disease
Patrick T. O’Gara, Joseph Loscalzo
2002 PART 6 Disorders of the Cardiovascular System
■ PHYSICAL FINDINGS
Because TS usually occurs in the presence of other obvious valvular
disease, the diagnosis may be missed unless it is considered. Severe
TS is associated with marked hepatic congestion, often resulting in
cirrhosis, jaundice, serious malnutrition, anasarca, and ascites. Congestive hepatomegaly and, in cases of severe tricuspid valve disease,
splenomegaly are present. The jugular veins are distended, and in
patients with sinus rhythm, there may be giant a waves. The v waves
are less conspicuous, and because tricuspid obstruction impedes RA
emptying during diastole, there is a slow y descent. In patients with
sinus rhythm, there may be prominent presystolic pulsations of the
enlarged liver as well.
On auscultation, an opening snap (OS) of the tricuspid valve may
rarely be heard ~0.06 s after pulmonic valve closure. The diastolic
murmur of TS has many of the qualities of the diastolic murmur of
MS, and because TS almost always occurs in the presence of MS, it
may be missed. However, the tricuspid murmur is generally heard best
along the left lower sternal border and over the xiphoid process and is
most prominent during presystole in patients with sinus rhythm. The
murmur of TS is augmented during inspiration, and it is reduced during expiration and particularly during the strain phase of the Valsalva
maneuver, when tricuspid transvalvular flow is reduced.
■ LABORATORY EXAMINATION
The electrocardiogram (ECG) features of RA enlargement (see
Fig. 240-8) include tall, peaked P waves in lead II, as well as prominent,
upright P waves in lead V1
. The absence of ECG evidence of RV hypertrophy (RVH) in a patient with right-sided heart failure who is believed
to have MS should suggest associated tricuspid valve disease. The chest
x-ray in patients with combined TS and MS shows particular prominence of the RA and superior vena cava without much enlargement of
the PA and with less evidence of pulmonary vascular congestion than
occurs in patients with isolated MS; engorgement of the azygos vein
can often be appreciated. On transthoracic echocardiographic (TTE)
examination, the tricuspid valve is usually thickened and domes in
diastole; the transvalvular gradient can be estimated by continuous
wave Doppler echocardiography. Severe TS is characterized by a valve
area ≤1 cm2
or pressure half-time of ≥190 ms. The RA and inferior vena
cava (IVC) are enlarged. TTE provides additional information regarding the severity of any associated TR, mitral valve structure and function, left ventricular (LV) and RV size and function, and PA pressure.
Cardiac catheterization is not routinely necessary for assessment of TS.
TABLE 266-1 Causes of Tricuspid Valve Diseases
VALVE LESION ETIOLOGIES
Tricuspid stenosis Rheumatic
Congenital
Tricuspid regurgitation Primary (organic)
Rheumatic
Endocarditis
Myxomatous (TVP)
Carcinoid
Radiation
Congenital (Ebstein’s)
Trauma (including that due to intracardiac leads
and RV endomyocardial biopsy)
Papillary muscle injury (post-MI)
Secondary (functional)
RV and tricuspid annular dilation due to multiple
causes (e.g., long-standing pulmonary HTN,
remodeling post-RV MI, left-sided heart disease,
cardiomyopathy, AF (atrial functional tricuspid
regurgitation), chronic RV apical pacing
(dyssynchrony)
Abbreviations: AF, atrial fibrillation; HTN, hypertension; MI, myocardial infarction;
RV, right ventricular; TVP, tricuspid valve prolapse.
TREATMENT
Tricuspid Stenosis
Patients with TS generally exhibit marked systemic venous congestion; salt restriction, bed rest, and diuretic therapy are required during the preoperative period. Such a preparatory period may diminish
hepatic congestion and thereby improve hepatic function sufficiently
so that the risks of operation, particularly bleeding, are diminished.
Surgical relief of the TS should be carried out, preferably at the time
of surgical mitral commissurotomy or mitral valve replacement
(MVR) for mitral valve disease, in patients with moderate or severe
TS who have mean diastolic pressure gradients exceeding ~4 mmHg
and tricuspid orifice areas <1.5–2 cm2
. TS is almost always accompanied by significant TR. Operative repair may permit substantial
improvement of tricuspid valve function. If repair cannot be accomplished, the tricuspid valve may have to be replaced. Meta-analysis
has shown no difference in overall survival between mechanical and
tissue valve replacement. Mechanical valves in the tricuspid position
are more prone to thromboembolic complications than in other
positions. Percutaneous tricuspid balloon commissurotomy for isolated severe TS without significant TR is very rarely performed.
TRICUSPID REGURGITATION
More than 85% of TR cases encountered in clinical practice are secondary (functional) in nature and related to tricuspid annular dilation
and leaflet tethering in the setting of RV remodeling caused by pressure
or volume overload (or both), myocardial infarction (MI), or trauma
(Table 266-1). Secondary TR is commonly seen in the late stages of
heart failure due to rheumatic or congenital heart disease with severe
PA hypertension (PA systolic pressure >55 mmHg), as well as in other
types of left-sided valvular (e.g., mitral regurgitation) or myocardial
diseases (e.g., ischemic and idiopathic dilated cardiomyopathies).
Secondary TR can also develop from chronic RV apical pacing and
dyssynchronous contraction; in some patients, the RV leads may also
perforate or entrap the TV leaflets. TR can often emerge in the setting
of new-onset atrial fibrillation (AF), particularly in older patients
(atrial functional TR). Rheumatic fever may produce primary TR,
often associated with TS. Tricuspid valve prolapse, carcinoid heart
disease, endomyocardial fibrosis, radiation, infective endocarditis, and
leaflet trauma can also produce primary TR. Less commonly, primary
TR results from congenitally deformed tricuspid valves and can occur
with defects of the atrioventricular canal, as well as with Ebstein’s malformation of the tricuspid valve (Chap. 269).
■ PATHOPHYSIOLOGY
The incompetent tricuspid valve allows blood to flow backward from the
RV into the RA, the volume of which is dependent on the driving pressure
(i.e., RV systolic pressure) and the size of the regurgitant orifice. The severity
and physical signs of TR can vary as a function of PA systolic pressure (in
the absence of RV outflow tract stenosis), the dimension of the tricuspid
valve annulus, the respiratory cycle-dependent changes in RV preload, and
RA compliance. RV filling is increased during inspiration. Forward CO is
reduced and does not augment with exercise. Significant degrees of TR will
lead to RA enlargement and elevation of the RA and jugular venous pressures with prominent c-v waves in the pulse tracings. Progressively severe
TR can lead to “ventricularization” of the RA wave form (see Fig. 239-1B).
Severe TR is also characterized by RV dilation (RV volume overload) and
eventual systolic dysfunction, the progression of which can be accelerated
by a concomitant pressure load from PA hypertension or by myocardial
fibrosis from previous injury.
■ SYMPTOMS
Mild or moderate degrees of TR are usually well tolerated in the absence
of other hemodynamic disturbances. Because TR most often coexists
with left-sided valve lesions, LV dysfunction, and/or PA hypertension,
symptoms related to these lesions may dominate the clinical picture.
Fatigue and exertional dyspnea owing to reduced forward CO are early
symptoms of isolated, severe TR. As the disease progresses and RV
Tricuspid Valve Disease
2003CHAPTER 266
function declines, patients may report cervical pulsations, abdominal
fullness/bloating, diminished appetite, and muscle wasting, although
with progressive weight gain and painful swelling of the lower extremities.
■ PHYSICAL FINDINGS
The neck veins in patients with severe TR are distended with prominent
c-v waves and rapid y descents (in the absence of TS). TR is more often
diagnosed by examination of the neck veins than by auscultation of the
heart sounds. Other findings may include marked hepatomegaly with
systolic pulsations, ascites, pleural effusions, edema, and a positive hepatojugular reflux sign. A prominent RV pulsation in the left parasternal
region and a blowing holosystolic murmur along the lower left sternal
margin, which may be intensified during inspiration (Carvallo’s sign) and
reduced during expiration or the strain phase of the Valsalva maneuver,
are characteristic findings. The murmur of TR may sometimes be confused with that of mitral regurgitation (MR) unless attention is paid to its
variation during the respiratory cycle and the extent of RV enlargement
is appreciated. AF is usually present in the chronic phase of the disease.
■ LABORATORY EXAMINATION
The ECG may show changes characteristic of the lesion responsible for
the TR, e.g., an inferior Q-wave MI suggestive of a prior RV MI, RVH,
or a bizarre right bundle branch block–type pattern with preexcitation in
patients with Ebstein’s anomaly. ECG signs of RA enlargement may be
present in patients with sinus rhythm; AF is frequently noted. The chest
x-ray may show RA and RV enlargement, depending on the chronicity
and severity of TR. TTE is usually definitive with demonstration of RA
dilation and RV volume overload and prolapsing, flail, scarred, or displaced/tethered tricuspid leaflets with annular dilatation; the diagnosis
and assessment of TR can be made by color flow Doppler imaging (see
Fig. 241-8). Severe TR is accompanied by hepatic vein systolic flow
reversal. Continuous wave Doppler of the TR velocity profile is useful in
estimating PA systolic pressure, except when the TR is very severe and
the jet velocity is blunted by rapidly increasing RA pressure. Accurate
assessment of TR severity, PA pressures, and RV size and systolic function
with TTE can be quite challenging in many patients. Real-time three-dimensional echocardiography and cardiac magnetic resonance (CMR)
imaging provide alternative imaging modalities, although they are not
widely available. In patients with severe TR, the CO is usually markedly
reduced, and the RA pressure pulse may not exhibit an x descent during early systole but rather show a prominent c-v wave with a rapid y
descent. The mean RA and RV end-diastolic pressures are often elevated.
Exercise testing can be used to assess functional capacity in patients with
asymptomatic severe TR. The prognostic significance of exercise-induced
changes in TR severity and RV function has not been well studied.
TREATMENT
Tricuspid Regurgitation (Fig. 266-1)
Diuretics can be useful for patients with severe TR and signs of
right heart failure. An aldosterone antagonist may be particularly
Tricuspid regurgitation
Severe TR
(Stages C and D)
At time of leftsided valve surgery
At time of leftsided valve surgery
Asymptomatic
Stage C
Annular dilation
>4.0 cm
or
prior right HF
Primary TR with
progressive RV
dilation or systolic
dysfunction
Right heart failure
Stage D
Prior left-sided
valve surgery
Secondary
TR
Poorly
responsive
to GDMT
Annular
dilation without
↑PAP or leftsided disease
Absences of
severe PH or
RV systolic
dysfunction
Primary
TR
TV surgery
(2b)
TV surgery
(2b)
TV surgery
(2a)
TV surgery
(2a)
TV surgery
(2a)
TV surgery
(1)
Progressive TR
(Stage B)
FIGURE 266-1 Management of tricuspid regurgitation. See legend for Fig. 261-4 for explanation of treatment recommendations (Class I, IIa, IIb) and disease stages (B, C,
D). Preoperative coronary angiography should be performed routinely as determined by age, symptoms, and coronary risk factors. Cardiac catheterization and angiography
may also be helpful when there is a discrepancy between clinical and noninvasive findings. GDMT, guideline-directed management and therapy; HF, heart failure; PAP,
pulmonary artery pressure; PH, pulmonary hypertension; RV, right ventricular; TR, tricuspid regurgitation; TV, tricuspid valve. Annular dilation is defined by >40 mm on
transthoracic echocardiography (>21 mm/m2
) or >70 mm on direct intraoperative measurement. (Reproduced with permission from CM Otto et al: 2020 AHA/ACC Guideline
for management of patients with valvular heart disease: A report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines.
Circulation 143:e72, 2021.)
2004 PART 6 Disorders of the Cardiovascular System
PULMONIC STENOSIS
Pulmonic valve stenosis (PS) is essentially a congenital disorder
(Table 267-1). With isolated PS, the valve is typically domed. Dysplastic pulmonic valves are seen as part of the Noonan syndrome
(Chap. 281), which maps to chromosome 12. Mutations in the PTPN1
gene are associated with about half of all cases of Noonan syndrome.
Much less common etiologies include carcinoid and obstructing
tumors or bulky vegetations. The pulmonic valve is only very rarely
affected by the rheumatic process.
■ PATHOPHYSIOLOGY
PS is defined hemodynamically by a systolic pressure gradient between
the right ventricle (RV) and the main pulmonary artery (PA). RV hypertrophy (RVH) develops as a consequence of sustained obstruction to RV
outflow, and systolic ejection is prolonged. Compared with the ability of
the LV to compensate for the pressure overload imposed by aortic stenosis (AS), RV dysfunction from afterload mismatch occurs earlier in the
course of PS and at lower peak systolic pressures, because the RV adapts
267 Pulmonic Valve Disease
Patrick T. O’Gara, Joseph Loscalzo
TABLE 267-1 Causes of Pulmonic Valve Disease
VALVE LESION ETIOLOGIES
Pulmonic stenosis Congenital
Carcinoid
Tumor
Endocarditis
Pulmonic regurgitation Primary valve disease
Congenital
Post-valvotomy
Endocarditis
Carcinoid
Annular enlargement
Pulmonary hypertension
Idiopathic dilation
Marfan syndrome
helpful because many patients have secondary hyperaldosteronism
from marked hepatic congestion. Therapies to reduce elevated PA
pressures and/or pulmonary vascular resistance, including those targeted at left-sided heart disease, can also be considered for patients
with PA hypertension and severe secondary TR. Tricuspid valve
surgery is recommended for patients with severe TR who are undergoing left-sided valve surgery and is also undertaken frequently for
treatment of even moderate TR in patients undergoing left-sided
valve surgery who have tricuspid annular dilation (>40 mm), a
history of right heart failure, or PA hypertension. Operation most
often comprises repair rather than replacement in these settings
and has become routine in most major surgical centers. Surgery
may also infrequently be required for treatment of severe, primary
TR with right heart failure not responsive to standard medical
therapy or because of progressively declining RV systolic function.
Reported perioperative mortality rates for isolated tricuspid valve
surgery (repair and replacement) are high (~8–9%) and likely are
influenced by the hazards encountered during reoperation on
patients who have undergone previous left-sided valve surgery and
have reduced RV function. Indwelling pacemaker or defibrillator
leads can also pose technical challenges. Investigation of transcatheter tricuspid valve repair and replacement systems is ongoing.
■ FURTHER READING
Dreyfus GD et al: Functional tricuspid regurgitation. J Am Coll Cardiol 65:2331, 2015.
Hahn RT et al: Early feasibility study of transcatheter tricuspid valve
annuloplasty. J Am Coll Cardiol 69:1795, 2017.
Kadri AN et al: Outcomes of patients with severe tricuspid regurgitation and congestive heart failure. Heart 105:1813, 2019.
Otto CM et al: 2020 ACC/AHA guideline for the management
of patients with valvular heart disease: A report of the American
College of Cardiology/American Heart Association Joint Committee
on Clinical Practice Guidelines. Circulation 143:e72, 2021.
Rodés-Cabau J et al: Diagnosis and treatment of tricuspid valve disease: Current and future perspectives. Lancet 388:2431, 2016.
Rodés-Cabau J et al: Transcatheter therapies for treating tricuspid
regurgitation. J Am Coll Cardiol 67:1829, 2016.
less well to this type of hemodynamic burden. With normal systolic
function and cardiac output (CO), severe PS is defined by a peak systolic gradient across the pulmonic valve of >64 mmHg (mean gradient
>35 mm Hg, Doppler jet velocity >4 m/s); moderate PS correlates with
a peak gradient of 36–64 mmHg (Doppler jet velocity 3-4 m/s). Mild PS
is characterized by a jet velocity <3 m/s (peak gradient <36 mmHg). PS
rarely progresses in patients with mild PS mmHg but may worsen in
those with moderate disease due to valve thickening and calcification
with age. The right atrial (RA) a wave elevates in relation to the higher
pressures needed to fill a noncompliant, hypertrophied RV. A prominent RA v wave signifies functional tricuspid regurgitation (TR) from
RV and annular dilation. The CO is maintained until late in the course
of the disease.
■ SYMPTOMS
Patients with mild or even moderate PS are usually asymptomatic and
first come to medical attention because of a heart murmur (or early
systolic click) that leads to echocardiography. With severe PS, patients
may report exertional dyspnea or early-onset fatigue. Anginal chest
pain from RV oxygen supply-demand mismatch and syncope may
occur with very severe forms of obstruction, particularly in the presence of a destabilizing trigger such as atrial fibrillation, fever, infection,
anemia, or pregnancy.
■ PHYSICAL FINDINGS
The murmur of mild or moderate PS is mid-systolic in timing,
crescendo–decrescendo in configuration, heard best in the left second
interspace, and usually introduced by an ejection sound (click) in
younger adults whose valves are still pliable. The ejection sound is the
only right-sided acoustic event that decreases in intensity with inspiration. This phenomenon reflects premature opening of the pulmonic
valve by the elevated RV end-diastolic (post-atrial a wave) pressure.
The systolic murmur increases in intensity during inspiration. With
progressively severe PS, the ejection sound moves closer to the first
heart sound and eventually becomes inaudible. A right-sided fourth
heart sound may emerge. The systolic murmur peaks later and may
persist through the aortic component of the second heart sound (A2
).
Pulmonic valve closure is delayed, and the pulmonic component of
the second heart sound (P2
) is reduced or absent. A prominent a wave,
indicative of the higher atrial pressure necessary to fill the noncompliant RV, may be seen in the jugular venous pulse. A parasternal or RV
lift can be felt with significant pressure overload. Signs of right heart
failure, such as hepatomegaly, ascites, and edema, are uncommon but
may appear very late in the disease.
■ LABORATORY EXAMINATION
The electrocardiogram (ECG) will show right axis deviation, RVH, and
RA enlargement in adult patients with severe PS. Chest x-ray findings
include poststenotic dilation of the main PA in the frontal plane projection and filling of the retrosternal airspace due to RV enlargement on
Multiple and Mixed Valvular Heart Disease
2005CHAPTER 268
not contain a valve. PA pressures in these individuals are not elevated,
and the diastolic murmur can be misleadingly low pitched and of short
duration despite significant degrees of PR and RV volume overload.
■ LABORATORY EXAMINATION
Depending on both the etiology and severity of PR, the ECG may show
findings of RVH and RA enlargement. On chest x-ray, the RV and RA
may be enlarged. Pulmonic valve morphology and function can be
assessed with transthoracic Doppler echocardiography. RV systolic
pressure can be estimated from the tricuspid valve systolic jet velocity. Cardiac magnetic resonance (CMR) imaging can provide greater
anatomic detail, particularly in patients with repaired congenital heart
disease, and more precise assessment of RV volumes and function. Cardiac catheterization is not routinely necessary but would be performed
as part of a planned transcatheter PV procedure.
TREATMENT
Pulmonic Regurgitation
In patients with functional PR due to PA hypertension and annular dilation, efforts to reduce PA vascular resistance and pressure should be pursued. Such efforts may include pharmacologic/
vasodilator and/or surgical/interventional strategies, depending on
the cause of the PA hypertension (e.g., idiopathic PA hypertension,
left-sided heart valve disease). Diuretics can be used to treat the
manifestations of right heart failure. Surgical valve replacement
for primary, severe, pulmonic valve disease, such as carcinoid or
endocarditis, is rarely undertaken. Transcatheter pulmonic valve
replacement has been successfully performed in many patients with
severe PR after childhood repair of tetralogy of Fallot or pulmonic
valve stenosis or atresia. This procedure was introduced clinically
prior to transcatheter aortic valve replacement.
■ FURTHER READING
Ansari MM et al: Percutaneous pulmonary valve implantation. J Am
Coll Cardiol 66:2246, 2015.
Otto CM et al: 2020 AHA/ACC guideline for the management of
patients with valvular heart disease. A report of the American College
of Cardiology/American Heart Association Joint Committee on
Clinical Practice Guidelines. Circulation 143:e72, 2021.
Stout KK et al: 2018 ACC/AHA guidelines for the management of
adults with congenital heart disease. J Am Coll Cardiol 73:e81, 2019.
the lateral film. In some patients with RVH, the cardiac apex appears
to be lifted off the left hemidiaphragm. The RA may also be enlarged.
Transthoracic echocardiography (TTE) allows definitive diagnosis and
characterization in most cases, with depiction of the valve and assessment of the jet velocity, gradient, RV function, PA pressures (which
should be low), and any associated cardiac lesions. Transesophageal
echocardiography (TEE) may be useful in some patients for improved
delineation of the RV outflow tract (RVOT) and assessment of infundibular hypertrophy. Cardiac catheterization is not usually necessary
for diagnostic purposes, but if performed, pressures should be obtained
from just below and above the pulmonic valve with attention to the
possibility that a dynamic component to the gradient may exist. The
correlation between Doppler assessment of peak instantaneous gradient and catheterization-measured peak-to-peak gradient is weak. The
latter may correlate better with the Doppler mean gradient.
TREATMENT
Pulmonic Stenosis
Diuretics can be used to treat symptoms and signs of right heart
failure. Provided there is less than moderate pulmonic regurgitation (PR), percutaneous pulmonic balloon valvuloplasty is recommended for symptomatic patients with moderate or severe PS
and for asymptomatic patients with a peak gradient >64 mmHg
(or mean gradient >35 mmHg). Surgery may be required when the
valve is dysplastic (as seen in patients with Noonan’s syndrome and
other disorders). A multidisciplinary heart team is best positioned
to make treatment decisions of this nature.
PULMONIC REGURGITATION
PR may develop as a consequence of primary valve pathology, annular
enlargement, or their combination; after surgical treatment of RVOT
obstruction in children with such disorders as tetralogy of Fallot; or
after percutaneous pulmonic balloon valvotomy (Table 267-1). Carcinoid usually causes mixed pulmonic valve disease with PR and PS.
Long-standing severe PA hypertension from any cause can result in
dilation of the pulmonic valve ring and PR.
■ PATHOPHYSIOLOGY
Severe PR results in RV chamber enlargement and eccentric hypertrophy. As is the case for aortic regurgitation (AR), PR is a state of
increased preload and afterload. The reverse pressure gradient from the
PA to the RV, which drives the PR, progressively decreases throughout
diastole and accounts for the decrescendo nature of the diastolic murmur. As RV diastolic pressure increases, the murmur becomes shorter
in duration. The forward CO is preserved during the early stages of the
disease but may not increase normally with exercise and declines over
time. A reduction in RV ejection fraction may be an early indicator
of hemodynamic compromise. In advanced stages, there is significant
enlargement of the RV and RA with marked elevation of the jugular
venous pressure.
■ SYMPTOMS
Mild or moderate degrees of PR do not, by themselves, result in symptoms. Other issues, such as PA hypertension, may dominant the clinical
picture. With progressively severe PR and RV dysfunction, fatigue,
exertional dyspnea, abdominal fullness/bloating, and lower extremity
swelling may be reported.
■ PHYSICAL FINDINGS
The physical examination hallmark of PR is a high-pitched, decrescendo diastolic murmur (Graham Steell murmur) heard along the
left sternal border that can be difficult to distinguish from the more
frequently appreciated murmur of AR. The Graham Steell murmur
may become louder with inspiration and is usually associated with a
loud and sometimes palpable P2
and an RV lift, as would be expected
in patients with significant PA hypertension of any cause. Survivors
of childhood surgery for tetralogy of Fallot or PS/pulmonary atresia
may have an RV-PA conduit that is freely regurgitant because it does
Many acquired and congenital cardiac lesions may result in stenosis
and/or regurgitation of one or more heart valves. For example, rheumatic heart disease can involve the mitral (mitral stenosis [MS], mitral
regurgitation [MR], or MS and MR), aortic (aortic stenosis [AS], aortic
regurgitation [AR], or AS and AR), and tricuspid (tricuspid stenosis
[TS], tricuspid regurgitation [TR], or TS and TR) valve, alone or in
combination. The common association of functional TR with significant mitral valve disease is discussed in Chap. 266. Severe mitral
annular calcification can result in regurgitation (due to decreased
annular shortening during systole) and mild or moderate stenosis
(caused by extension of the calcification onto the leaflets resulting in
restricted valve opening). Patients with severe AS and LV remodeling
may develop functional MR that may not improve after isolated aortic
268 Multiple and Mixed
Valvular Heart Disease
Patrick T. O’Gara, Joseph Loscalzo
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