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Techniques in Type IIIa: Diastolic Restricted Leaflet Motion
The great majority of valvular diseases with diastolic-restricted leaflet motion have a rheumatic origin. The limitation of the motion of the leaflets is due to commissural fusion, leaflet thickening, chordae fibrosis, and occasionally calcifications. These lesions produce either pure mitral valve stenosis or mitral regurgitation or combined valve stenosis and regurgitation.
VALVE STENOSIS
Mitral valve stenosis was the first mitral valve dysfunction to be treated surgically by closed commissurotomy. Open commissurotomy was implemented when extracorporeal circulation became available. Today, most patients with mitral valve stenosis are treated by percutaneous balloon dilatation or a transcutaneous mechanical dilator. Surgeons, however, may have to treat this condition if the valve stenosis is not amenable to balloon dilatation, if there is a combined stenosis and regurgitation, or if a previous valve dilatation has failed.
In valve stenosis, the fibrotic lesions are predominant at the commissures and in the zone of leaflet coaptation. The fused commissures are categorized according to three grades of increasing severity ( Fig. 13-1 ). Grade I is a partial fusion of the commissures with preservation of commissural chordae. Grade II is a complete fusion of the commissures with a visible delineation between the anterior and the posterior leaflets. Grade III is a complete fusion of one or two commissures with no visible delineation between the anterior and posterior leaflets. The fusion of the commissures generates turbulence, the main cause of platelet-fibrin deposits and ultimately calcification. The underlying subvalvular apparatus is fibrotic and sometimes retracted to the point that the head of the corresponding papillary muscle is adherent to the commissure. The annulus fibrosus usually has a normal kidney shape during systole with the anteroposterior diameter smaller than the transverse diameter ( Fig. 13-2, a ). In this case, a commissurotomy does not produce a regurgitation (b) . Occasionally the annulus is dilated, with the anteroposterior diameter equal to or greater than the transverse diameter (c) . In this case, a commissurotomy may lead to further annular dilatation by releasing the opposing resistance caused by the centrifugal forces of the stenotic valvular orifice (d) .
Two types of mitral valve stenosis can be observed:
- 1.
Those with a normal systolic kidney-shaped annulus
- 2.
Those with a dilated and circular annulus
Commissural Fusion: Commissurotomy
Commissural fusion is treated by commissurotomy ( Fig. 13-3 ). To avoid commissural leakage, the technique should preserve a 5 mm long segment of valvular tissue near the annulus equivalent to the commissural leaflet. The main difficulty in performing a commissurotomy is the identification of a commissural line—the delineation between the anterior and the posterior leaflets. This is relatively easy in grade I and grade II commissural fusion but more difficult whenever the line of commissurotomy is not apparent, as in grade III fusion. In this case, traction on the main chordae of the anterior leaflet opposite to the commissure creates a furrow, which delineates the limit between the anterior and the posterior leaflets (a) . Using a knife with a sharp triangular blade, the incision begins 5 mm from the annulus and proceeds towards the mitral valve orifice (b) . At 5 mm from the orifice, the incision is interrupted. The commissural chordae are then identified and exposed with a nerve hook or a right angle clamp passed around the corresponding papillary muscle (c) . The incision is then completed, leaving at least one chordae on each margin of the commissural opening ( d ). The corresponding papillary muscle is split, leaving a little more thickness on the anterior leaflet side than on the posterior leaflet side. The splitting of the papillary muscle is extended downward until a subcommissural orifice is created. This orifice should be large enough to admit the extremity of a cardiotomy sucker (e) . Whenever possible, the splitting of chordae or papillary muscle is completed by a “fenestration,” *
* See Glossary .
that is, removal of a triangular piece of tissue to avoid early refusion (f, g) . Once completed, the commissurotomy provides enhanced access to the subvalvular apparatus.
Subvalvular Lesions: Chordae Resection and Fenestration
Leaflet mobilization is completed by resecting thickened secondary chordae and by splitting or “fenestrating” fused marginal chordae ( Fig. 13-4, a ). The secondary chordae to be resected are identified with a nerve hook (b) . Their attachment to the papillary muscle is cut first. The attachment to the leaflet is then exposed by gentle traction and also cut (inset) . During this maneuver, care should be taken to avoid cutting an adjacent marginal chordae inadvertently and to avoid excess traction, which may lead to leaflet perforation. If a defect is made in the leaflet tissue, it is closed by direct suture or occasionally a small piece of autologous pericardium. All thickened chordae can be resected without hesitation provided that at least one marginal chordae is preserved every 4 mm along the leaflet free edge. Whenever the distance between two marginal chordae is greater than 4 mm, a secondary chordae of appropriate length should be transposed to secure the free edge of the leaflet. Fused marginal chordae participating in the subvalvular obstruction are not cut, but “fenestrated” by removing a triangular piece of fibrous tissue and splitting the corresponding papillary muscle.
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