Right-to-left shunt

A right-to-left shunt is a cardiac shunt which allows blood to flow from the right heart to the left heart.^[1] This terminology is used both for the abnormal state in humans and for normal physiological shunts in reptiles.

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Clinical Significance

A right-to-left shunt occurs when:

there is an opening or passage between the atria, ventricles, and/or great vessels; and,
right heart pressure is higher than left heart pressure and/or the shunt has a one-way valvular opening.

Small physiological, or "normal", shunts are seen due to the return of bronchial artery blood and coronary blood through the Thebesian veins, which are deoxygenated, to the left side of the heart.

Causes

Congenital defects can lead to right-to-left shunting immediately after birth:^[2]

Persistent truncus arteriosus (minimal cyanosis)
Transposition of great vessels
Tricuspid atresia
Tetralogy of Fallot
Total anomalous pulmonary venous return

A mnemonic to remember the conditions associated with right-to-left shunting involves the numbers 1-5, as follows:

1 Combination Vessel: Persistent truncus arteriosus (minimal cyanosis)
2 Vessels involved: Transposition of great vessels
3 Leaflets: Tricuspid atresia
4 Tetra- prefix: Tetralogy of Fallot
5 Words: Total anomalous pulmonary venous return

A mainstem intubation with an endotracheal tube can lead to right-to-left shunting.^{[citation needed]} This occurs when the tip of the endotracheal tube is placed beyond the carina. In this way only one lung is oxygenated and oxygen-poor blood from the non-ventilated lung dilutes the oxygen level of blood returning from the lungs in the left ventricle.

Eisenmenger syndrome

An uncorrected left-to-right shunt can progress to a right-to-left shunt; this process is termed Eisenmenger syndrome.^[3] This is seen in Ventricular septal defect, Atrial septal defect, and patent ductus arteriosus, and can manifest as late as adult life. This switch in blood flow direction is precipitated by pulmonary hypertension due to increased pulmonary blood flow in a left-to-right shunt. The right ventricle hypertrophies to compensate for this pulmonary hypertension, so the right ventricular pressure becomes higher than the pressure in the left ventricle. Because of this switch in the pressure gradient, blood starts flowing right to left, forming a right-to-left shunt. As with any right-to-left shunt, there is decreased blood flow to the lungs, resulting in decreased oxygenation of blood and cyanosis.

Tetralogy of Fallot

The most common cause of right-to-left shunt is the Tetralogy of Fallot, a congenital cardiac anomaly characterized by four co-existing heart defects.

Pulmonary stenosis (narrowing of the pulmonary valve and outflow tract, obstructing blood flow from the right ventricle to the pulmonary artery)
Overriding aorta (aortic valve is enlarged and appears to arise from both the left and right ventricles instead of the left ventricle, as occurs in normal hearts)
Right ventricular hypertrophy (thickening of the muscular walls of the right ventricle, this is a result of the increased amount of work the heart has to do)
Ventricular septal defect (a hole exists in the septum that divides the left and right ventricles)

Outside of heart-related conditions, right-to-left shunts of the heart can be seen with Pulmonary Arteriovenous Malformations (PAVMs).

Symptoms

Early cyanosis is a symptom of a right-to-left shunt.^[2] A right-to-left shunt results in decreased blood flow through the pulmonary system, leading to decreased blood oxygen levels (hypoxemia). Hypoxemia manifests as cyanosis, causing "blue babies."

Diagnosis

Differentiation between a right-to-left shunt and pulmonary disease is often aided clinically by the results of a hyperoxia test.^{[citation needed]} Using high levels of inspired oxygen should have little effect on the dissolved O2 in the blood because highly oxygenated blood is diluted by shunted (low oxygenation) blood.

Shunt equation

$Q_{p}/Q_{s}=(CcO_{2}-CaO_{2})/(CcO_{2}-CvO_{2})$

Qp/Qs is the shunt fraction
CcO2 is the end-capillary oxygen content
CaO2 is the arterial oxygen content
CvO2 is the mixed venous oxygen content.

Reptiles

Because most reptiles have a single ventricle and all reptiles have both a right aortic arch and a left aortic arch, all reptiles have the capacity for right-to-left shunt. ^{[citation needed]}

References

^ "right-to-left shunt" at Dorland's Medical Dictionary
^ ^a ^b Rao, PS (Aug 2013). "Consensus on timing of intervention for common congenital heart diseases: part II - cyanotic heart defects". Indian Journal of Pediatrics. 80 (8): 663–74. doi:10.1007/s12098-013-1039-2. PMID 23640699. S2CID 39106680.
^ Krishnan, U; Rosenzweig, EB (Dec 2013). "Pulmonary arterial hypertension associated with congenital heart disease". Clinics in Chest Medicine. 34 (4): 707–17. doi:10.1016/j.ccm.2013.08.011. PMID 24267300.

Congenital heart defects

Heart septal defect

Aortopulmonary septal defect	Double outlet right ventricle Taussig–Bing syndrome Transposition of the great vessels dextro levo Persistent truncus arteriosus Aortopulmonary window
Atrial septal defect	Sinus venosus atrial septal defect Lutembacher's syndrome
Ventricular septal defect	Tetralogy of Fallot
Atrioventricular septal defect	Ostium primum
Consequences	Cardiac shunt Cyanotic heart disease Eisenmenger syndrome

Valvular heart disease

Right	pulmonary valves stenosis insufficiency absence tricuspid valves atresia regurgitation stenosis Ebstein's anomaly
Left	aortic valves stenosis insufficiency bicuspid mitral valves stenosis regurgitation

Other

Underdeveloped heart chambers
- right
- left
- Uhl anomaly
Dextrocardia
Levocardia
Cor triatriatum
Crisscross heart
Brugada syndrome
Coronary artery anomaly
Anomalous aortic origin of a coronary artery
Ventricular inversion

This page was last edited on 23 May 2024, at 05:56

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