Minimal Access Aortic Valve Surgery
Abstract
:1. Introduction
2. Minimal Access Options
2.1. Approach
2.1.1. Hemi-Sternotomy
2.1.2. Right Anterior Mini-Thoracotomy
2.1.3. Hybrid Approach (Sternotomy + Transcatheter Aortic Valve Implantation)
2.2. Cannulation and Cardiopulmonary Bypass
2.2.1. Central
2.2.2. Peripheral
2.2.3. Hypothermia and Systemic Hyperkalaemia
2.2.4. Venting (and Imaging)
- The right superior pulmonary vein;
- The pulmonary artery;
- Trans-aortically.
2.3. Adjuncts
2.3.1. Rapid Deployment Valves
2.3.2. Automatic Suture/Knotting Devices
2.3.3. Transvenous Pacing, Cannulation, and Venting
- Transvenous pacing can be floated using an inflatable balloon tip into the right ventricle for endocardial pacing if the anterior right ventricle is not accessible;
- Coronary sinus cannulation via the right internal jugular was previously possible using the Proplege device (Edwards LifeSciences, Irvin, CA, USA). but as the strategies for anterograde cardioplegia alone showed good efficacy, it is no longer available;
- Pulmonary artery venting through a percutaneously floated catheter has again lost favour, as trans-aortic and direct pulmonary artery or pulmonary vein venting have been shown to be efficacious and safe.
2.3.4. Thoracoscopes
2.3.5. Robot Assistance
2.4. Special Circumstances
2.4.1. Concomitant Procedures
2.4.2. Re-Do Procedures
3. Minimal Access Pre-Operative Planning/Setup
- A CT scan pre-operatively can allow for assessment of the position of the aorta relative to the incision planned. If peripheral cannulation is intended, CT can also determine whether the femoral vessels are of an adequate calibre and the descending aorta is free of mobile atheroma that may preclude retrograde perfusion.
- Short-acting anaesthetic drugs should be considered to facilitate early extubation and enhanced recovery.
- A sheath in the right internal jugular vein can be introduced at the time of induction of anaesthesia if the usual access limits epicardial pacing wires.
- A bag of saline behind the shoulder blades can elevate and expand the chest, providing an improved approach to the mediastinum.
- External defibrillator pads are required to cardiovert ventricular fibrillation, as internal paddles cannot be applied to the heart.
- Trans-oesophageal echocardiography is mandated for minimally invasive aortic valve surgery, as the direct visualization of the right and left ventricular function is impaired.
- A double lumen tube or bronchial blocker for selective ventilation of the right lung can facilitate the early learning curve [65].
- Carbon dioxide field flooding can aid in de-airing at the end of the case, when cardiac massage is not possible and venting is limited. Passive and limited active de-airing can therefore be supplemented with displacement of air in the cardiac chambers with highly soluble CO2.
4. Outcomes
4.1. Pain
4.2. Respiratory Mechanics
4.3. Quality of Life
4.4. Complications
5. Discussion
6. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Full Sternotomy | Hemi-Sternotomy | Right Anterior Minithoracotomy | |
---|---|---|---|
Access | Unfettered view of whole mediastinum and whole heart | Good access to aortic root, limited to whole heart | Most challenging view |
Sternal disruption | Whole sternum | To 2nd–4th intercostal spaces unilaterally or bilaterally | None, although costal cartilages are sometimes divided (may include right mammary artery ligation) |
Cannulation | Full central | Variable—from full central to aortic arterial only | Typically requires peripheral cannulation |
Instruments | Standard cardiac | Variable—can be standard or long-handled | Typically requires long-handled |
Technical difficulty | Baseline | Learning curve easily traversed, including for trainee surgeons | Accepted to be technically challenging |
Adjuncts Required | None | Variable—possible with standard equipment. Facilitated by rapid deployment valves, suture placement devices, and knot-tying devices | Facilitated by rapid deployment valves, suture placement devices, and knot-tying devices; Light source advantageous; Single lung ventilation. |
Benefits (from most recent meta-analyses) * | Reduced intensive care and hospital length of stay; Reduced ventilation time | Reduced hospital length of stay; Reduced ventilation time; Lower stroke rate; Lower pacemaker rate | |
Risks * | Increased operative time; Increased costs | Increased operative time; Increased costs (including vs. ministernotomy); Lung herniation |
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Kirmani, B.H.; Akowuah, E. Minimal Access Aortic Valve Surgery. J. Cardiovasc. Dev. Dis. 2023, 10, 281. https://doi.org/10.3390/jcdd10070281
Kirmani BH, Akowuah E. Minimal Access Aortic Valve Surgery. Journal of Cardiovascular Development and Disease. 2023; 10(7):281. https://doi.org/10.3390/jcdd10070281
Chicago/Turabian StyleKirmani, Bilal H., and Enoch Akowuah. 2023. "Minimal Access Aortic Valve Surgery" Journal of Cardiovascular Development and Disease 10, no. 7: 281. https://doi.org/10.3390/jcdd10070281
APA StyleKirmani, B. H., & Akowuah, E. (2023). Minimal Access Aortic Valve Surgery. Journal of Cardiovascular Development and Disease, 10(7), 281. https://doi.org/10.3390/jcdd10070281