0000000000773047

AUTHOR

Giorgio De Santis

showing 4 related works from this author

Different Hydraulic Constructs to Optimize the Venous Drainage of DIEP Flaps in Breast Reconstruction: Decisional Algorithm and Review of the Literat…

2020

 Venous congestion is the most common perfusion-related complication of deep inferior epigastric artery perforator (DIEP) flap. Several hydraulic constructs can be created for venous superdrainage in case of flap venous engorgement or as a preventive measure. These can be classified based on the choice of the draining vein of the flap, either a second deep inferior epigastric vein (DIEV) or a superficial inferior epigastric vein (SIEV), and of the recipient vein, either a vein of the chest or the DIEV. Background Venous congestion is the most common perfusion-related complication of deep inferior epigastric artery perforator (DIEP) flap. Several hydraulic constructs can be created for venou…

MammaplastyreviewSettore MED/19 - Chirurgia PlasticaAnastomosissuperdrainageStandard anatomical positionDIEP flap superdrainage algorithm reviewDIEP flapDIEP flap; superdrainage; algorithm; reviewmedicineHumansVeinalgorithmbusiness.industryDeep Inferior Epigastric ArteryDIEP flapVenous drainageEpigastric ArteriesInferior epigastric veinmedicine.anatomical_structuremedicine.veincardiovascular systemDrainageSurgerybusinessBreast reconstructionPerforator FlapAlgorithmAlgorithms
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WSRM 2019 in Bologna: A Great Success beyond Expectations!

2021

MicrosurgeryMotivationMedical educationbusiness.industryMEDLINEHumansMedicineSurgeryPlastic Surgery ProceduresbusinessJournal of Reconstructive Microsurgery
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A sequence of flaps and dissection exercises in the living model to improve the learning curve for perforator flap surgery.

2020

Abstract Introduction The training to learn how to perform perforator flaps requires practice on a living model to optimize dissection and to evaluate outcome. The purpose of this study was to describe a training model that optimizes the use of animals in order to perform the maximum number of exercises per animal. Material and methods The sequence has been planned and practiced by the first and last author, recorded perfected and implemented in a two-day surgical course. The sequence was then evaluated by the trainers and the trainees by means of a questionnaire. Results All students were able to complete the sequence of exercises before the end of the second day except two (8/10) who coul…

medicine.medical_specialtyMicrosurgerySuperior epigastric arterymedicine.medical_treatmentMammaplastyeducationAnimal model; Flap teaching; Microsurgery; Perforator flaps03 medical and health sciences0302 clinical medicineAnimal modelmedicine.arteryMedicinePerforator flaps Animal model Flap teaching MicrosurgeryAnimalsHumansMedical physicsAnimal modelGeneral Environmental ScienceSequence (medicine)030222 orthopedicsbusiness.industryDissection030208 emergency & critical care medicineMicrosurgeryEpigastric ArteriesFlap teachingDissectionLearning curvePerforator flapsGeneral Earth and Planetary SciencesbusinessPerforator FlapPerforator flapsLearning Curve
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Porcine Model for Internal Mammary Vessels Harvesting

2018

Recipient vessels selection is crucial for successful microsurgical breast reconstruction. The internal mammary vessels (IMVs) have gained great popularity, and they are often selected as first choice recipient vessels. The IMVs can be exposed for microvascular anastomosis through a rib-removing (trans-costal) or a rib-sparing (intercostal) approach.1–3 Because the vessels are located between the rib cage and the parietal pleura, adequate training is needed to avoid and eventually manage bleedings and pleural perforation. This training is better performed in a nonhuman model. Our aim was to investigate the pig as a surgical model for IMVs harvesting to be used in training.

Settore MED/19 - Chirurgia PlasticaPorcine Model internal Mammary Vessels Harvesting surgical training microsurgerynon applicabile
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