Introduction. In this prospective multicenter analysis, we aimed to investigate the predictive role of neutrophil/lymphocyte ratio (NLR) in permanent pacemaker implantation (PPI) in patients undergoing transcatheter aortic valve replacement (TAVR). Material and methods. 179 consecutive patients without previous PPI underwent TAVR from February 2017 to September 2021. Patients were further divided based on presence (n=48) and absence of conduction abnormalities (CAs) at hospital admission (n=131). Results . In patients with previous CAs, NLR values did not differ significantly between patients requiring PPI (n=16, 33%) and those not requiring it. In contrast, in patients with no CAs at hospital admission, NLR values measured at admission and on TAVR day were significantly higher in patients requiring PPI (n=17, 13%) (4.07±3.22 vs 3.01±1.47, p=0.025, and 10.81±7.81 vs 5.84±3.78, p=0.000, respectively). Multivariable analysis showed that NLR at TAVR day was an independent predictor of PPI in patients without CAs (OR 1.294; 95% CI 1.028-1.630; p=0.028), but not in those with previous CAs. ROC curve analysis showed that the cut point was a NLR value of >7.25. Time to PPI was delayed till 21 days in patients without CAs. Conclusions. In this prospective study, higher NLR values on the day of TAVR day were associated with an increased PPI rate in patients undergoing TAVR with no previous CAs. It is advisable, being inflammation part of the process, to prolong the time of observation for all patients without CAs till at least 21 days not to miss any new CA necessitating PPI.

ARTIFICIAL CHORDAE FOR ANTERIOR LEAFLET PROLAPSE: ARE ALL THE ROADS LEADING TO ROME?Antonio Maria Calafiore (a), MD, Antonio Totaro (a), MD, Sotirios Prapas (b), MD, Diego Magnano, MD (a), Stefano Guarracini (c), PhD, Massimo Di Marco (d), MD, Michele Di Mauro (c,e), PhDDepartment of Cardiovascular Diseases, Gemelli Molise, Campobasso, ItalyDivision of Cardiac Surgery A, Henry Dunant Hospital, Athens, GreeceDepartment of Cardiology, “Pierangeli” Hospital, Pescara, ItalyDepartment of Cardiology, “S Spirito” Hospital, Pescara, ItalyCardio‐Thoracic Surgery Department, Cardiovascular Research Institute Maastricht (CARIM), Maastricht University Medical Centre (MUMC), Maastricht, The Netherlands

Despite advances in technologies and clinical experience, conduction disorders, after TAVR or SAVR, represent the weak point of these procedures, requiring permanent pacemaker implantation (PPI) till 37.7% of patients in TAVR recipients. The role of PPI in TAVR and SAVR remains controversial in mid- and long-term outcomes. Indeed, many studies have been published with contradictory results, leaving doubts rather than certainties.

Based on Carpentier’s classification and principles, the techniques for mitral valve repair continue to evolve. We herein report our experience with the morpho-functional echocardiographic analysis of single mitral leaflets, as different anatomic features, even if conflicting, may coexist not only in the two leaflets, but in the same leaflet as well. A classification is proposed, based on the length (normal, short, or long) and mobility (normal, restricted, or excessive) of mitral leaflets. The surgical techniques adopted for mitral valve repair are the direct consequence of this analysis.

The chordae tendinae connect the papillary muscles to the mitral valve. While the first-order chordae serve to secure the leaflets to maintain valve closure and prevent mitral valve prolapse, the second-order chordae are believed that they play a role in maintaining normal LV size and geometry. The papillary muscles, from where the chordae tendinae originate, function as shock absorbers that compensate for the geometric changes of the left ventricular wall. The second-order chordae connect the PMs to both trigons under tension. The tension distributed towards the second-order chordae has been demonstrate to be more than three-fold that in the first-order counterpart. Cutting the second-order chordae puts all the tension on the first-order chordae, that can go closer to their rupture point. However, it has been experimentally demonstrated that the tension where the first-order chordae break is 6.8 N, by far higher than the maximal tension reached, that is 0.4 N. Even if the clinical reports have been favorable, the importance of cutting the second-order chordae to recover curvature of the anterior leaflet and increasing the coaptation length between the mitral leaflet has been slowly absorbed by the surgical world. Nevertheless, there are progressive demonstrations that chordal tethering affects the anterior leaflet not only in secondary, but also in primary mitral regurgitation, having a not negligeable role in the long-term outcome of mitral repair.

Resection or exclusion of scars following a myocardial infarction on the LAD territory started even before the beginning of the modern era of cardiac surgery. Many techniques were developed, but there is still confusion on who did what. The original techniques underwent modifications that brought to a variety of apparently new procedures that, however, were only a “revisitation” of what described before. In some case old techniques were reproposed and renamed, without giving credit to the surgeon that was the original designer. Herein we try to describe which are the seminal procedures and some of the most important modifications, respecting however the merit of who first communicated the procedure to the scientific world.

Mitral valve (MV) repair for mitral regurgitation (MR) due to posterior leaflet (PL) prolapse is achieved nowadays with a great success rate and a good survival, similar, in certain subgroups. In this paper, Sakaguchi et al describe their results in two groups of patients with PL prolapse. Some patients underwent resection (resection group) and others chordal replacement with/out limited resection (respect group). Results were similar in terms of survival and MR recurrence. Our goal is to eliminate, as much as possible, MR when a patient with degenerative MR is operated on. Reduction of the mitral orifice and consequently an increase of the transmitral gradient is the rule. MV repair for degenerative MR provides great results, but there is not a single surgical technique. A close evaluation of the anatomical findings will allow us to choose the best strategy for the individual patient. An open mind is the most important characteristic that a surgeon should have to repair a prolapsing PL without residual regurgitation and dangerous gradients.

Large studies demonstrated that moderate or severe patient-prosthesis mismatch (PPM) occurs in 44.2% to 65% of patients undergoing aortic valve replacement. If there is general agreement that patients with PPM have worse outcome than patients without, it is difficult to understand how to prevent this dangerous complication. The formula used to calculate the effective orifice area (EOA) of an implanted aortic prosthesis has many weak points that produce inconsistent results using the same prosthetic valve (type and size). The observed EOA (3 to 6 months postoperatively) of a #23 biological prosthesis can range from 0.9 to 3.5 cm², making PPM prevention impossible using projected EOA, where only the mean value is reported (1.83 cm² for the same #23 biological prosthesis). An EACTS-STS-AATS Valve Labelling Task Force has been established to suggest the manufacturers to present essential information on valvular prosthesis characteristics in standardized Valve Charts. For valves used in the aortic position, Valve Charts should include a standardized PPM chart to assess the probability of PPM after implantation. This will not solve completely the conundrum of prevention, but most likely it will be a step ahead.

In secondary mitral regurgitation, the concept that the mitral valve (MV) is an innocent bystander, has been challenged by many studies in the last decades. The MV is a living structure with an intrinsic plasticity that reacts to changes in stretch or in mechanical stress activating bio-humoral mechanisms that have, as purpose, the adaptation of the valve to the new environment. If the adaptation is balanced, the leaflets increase both surface and length and the chordae tendinae lengthen: the result is a valve with different characteristics, but able to avoid or to limit the regurgitation. However, if the adaptation is unbalanced, the leaflets and the chords do not change their size, but become stiffer and rigid, with moderate or severe regurgitation. These changes are mediated mainly by a cytokine, the transforming growth factor β (TGF-β), which is able to promote the changes that the MV needs to adapt to a new hemodynamic environment. In general, mild TGF-β activation facilitates leaflet growth, excessive TGF-β activation, as after a myocardial infarction, results in profibrotic changes in the leaflets, with increased thickness and stiffness. The MV is then a plastic organism, that reacts to the external stimuli, trying to maintain its physiologic integrity. This review has the goal to unveil the secret life of the MV, to understand which stimuli can trigger its plasticity and to explain why the equation “large heart=moderate/severe mitral regurgitation” and “small heart=no/mild mitral regurgitation” does not work into the clinical practice.