New cross sonic piezosonic cutting blade geometry design: pilot study

New cross sonic piezosonic cutting blade geometry design: pilot study

Abstract The principle of piezosurgery is “pressure electrification”. When electrical voltage is applied to certain materials such as quartz and Rochelle salts, it causes the materials to expand and contract, producing ultrasonic vibrations. This device uses ultrasonic vibration at 60–210 μm/s at 24...

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Main Authors: Bianca Pulino, Marcelo Pigatto D’Amado, Guilherme Louzada, Gustavo Câmara, Geraldo Prestes de Camargo Filho, Raphael Capelli Guerra
Format: Article
Language:English
Published: Springer 2025-06-01
Series:Discover Applied Sciences
Subjects:
Piezosurgery
Ultrasonic device
Osteotomy
Online Access:https://doi.org/10.1007/s42452-025-07203-x
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author Bianca Pulino
Marcelo Pigatto D’Amado
Guilherme Louzada
Gustavo Câmara
Geraldo Prestes de Camargo Filho
Raphael Capelli Guerra
author_facet Bianca Pulino
Marcelo Pigatto D’Amado
Guilherme Louzada
Gustavo Câmara
Geraldo Prestes de Camargo Filho
Raphael Capelli Guerra
author_sort Bianca Pulino
collection DOAJ
description Abstract The principle of piezosurgery is “pressure electrification”. When electrical voltage is applied to certain materials such as quartz and Rochelle salts, it causes the materials to expand and contract, producing ultrasonic vibrations. This device uses ultrasonic vibration at 60–210 μm/s at 24–36 kHz to selectively remove bone with minimal damage to soft tissues such as blood vessels and nerves. In addition, it provides excellent visibility due to its cavitation effect. Piezoelectric surgery uses low-frequency ultrasonic vibration for osteotomy, which minimizes the risk of damage to soft tissue (nerves, vessels and mucosa). Micrometric vibration ensures precise cutting action and allows operative control, with consequent increased safety, in anatomical areas that are difficult to access. The aim of this study is to provide a device capable of providing a smaller contact area, less effort, lower temperature generation, faster cutting, shorter surgery time, shorter post-operative time and maxillofacial, orthopedic, neurosurgical and otorhinolaryngological procedures.
format Article
id doaj-art-2210e8aa7cb6455a86d21d14676bd2ac
institution Kabale University
issn 3004-9261
language English
publishDate 2025-06-01
publisher Springer
record_format Article
series Discover Applied Sciences
spelling doaj-art-2210e8aa7cb6455a86d21d14676bd2ac2025-08-20T03:47:16ZengSpringerDiscover Applied Sciences3004-92612025-06-017711010.1007/s42452-025-07203-xNew cross sonic piezosonic cutting blade geometry design: pilot studyBianca Pulino0Marcelo Pigatto D’Amado1Guilherme Louzada2Gustavo Câmara3Geraldo Prestes de Camargo Filho4Raphael Capelli Guerra5Instituto de Ensino e Pesquisa, Hospital Sírio-LibanêsInstituto de Ensino e Pesquisa, Hospital Sírio-LibanêsInstituto de Ensino e Pesquisa, Hospital Sírio-LibanêsInstituto de Ensino e Pesquisa, Hospital Sírio-LibanêsCollege of Dental Medicine, Clearwater Campus, Nova Southeastern University-NSU FlóridaInstituto de Ensino e Pesquisa, Hospital Sírio-LibanêsAbstract The principle of piezosurgery is “pressure electrification”. When electrical voltage is applied to certain materials such as quartz and Rochelle salts, it causes the materials to expand and contract, producing ultrasonic vibrations. This device uses ultrasonic vibration at 60–210 μm/s at 24–36 kHz to selectively remove bone with minimal damage to soft tissues such as blood vessels and nerves. In addition, it provides excellent visibility due to its cavitation effect. Piezoelectric surgery uses low-frequency ultrasonic vibration for osteotomy, which minimizes the risk of damage to soft tissue (nerves, vessels and mucosa). Micrometric vibration ensures precise cutting action and allows operative control, with consequent increased safety, in anatomical areas that are difficult to access. The aim of this study is to provide a device capable of providing a smaller contact area, less effort, lower temperature generation, faster cutting, shorter surgery time, shorter post-operative time and maxillofacial, orthopedic, neurosurgical and otorhinolaryngological procedures.https://doi.org/10.1007/s42452-025-07203-xPiezosurgeryUltrasonic deviceOsteotomy
spellingShingle Bianca Pulino
Marcelo Pigatto D’Amado
Guilherme Louzada
Gustavo Câmara
Geraldo Prestes de Camargo Filho
Raphael Capelli Guerra
New cross sonic piezosonic cutting blade geometry design: pilot study
Discover Applied Sciences
Piezosurgery
Ultrasonic device
Osteotomy
title New cross sonic piezosonic cutting blade geometry design: pilot study
title_full New cross sonic piezosonic cutting blade geometry design: pilot study
title_fullStr New cross sonic piezosonic cutting blade geometry design: pilot study
title_full_unstemmed New cross sonic piezosonic cutting blade geometry design: pilot study
title_short New cross sonic piezosonic cutting blade geometry design: pilot study
title_sort new cross sonic piezosonic cutting blade geometry design pilot study
topic Piezosurgery
Ultrasonic device
Osteotomy
url https://doi.org/10.1007/s42452-025-07203-x
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AT marcelopigattodamado newcrosssonicpiezosoniccuttingbladegeometrydesignpilotstudy
AT guilhermelouzada newcrosssonicpiezosoniccuttingbladegeometrydesignpilotstudy
AT gustavocamara newcrosssonicpiezosoniccuttingbladegeometrydesignpilotstudy
AT geraldoprestesdecamargofilho newcrosssonicpiezosoniccuttingbladegeometrydesignpilotstudy
AT raphaelcapelliguerra newcrosssonicpiezosoniccuttingbladegeometrydesignpilotstudy

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