Beam hardening artefacts occur in dental implant scans with the NewTom^®cone beam CT but not with the dental 4-row multidetector CT

Abstract: Visual spatial resolution of the NewTom 9000 CBCT was less accurate than the Philips MX 8000 MDCT in the imaging of metallic dental implants.

“…Gutta-percha was heated and glued to mark 13 points on a dry human skull in order to measure the following specific mandibular, maxillary, and skull-base distances: (1) distance between left and right foramen mentales, (2) distance between left and right distal tubercules of mandibular second molars, (3) distance between left and right angulus mandibulae, (4) distance between left and right coronoid process, (5) distance between left and right incisura mandibulae, (6) distance between left and right fovea pterygoidea, (7) distance between spina nasalis anterior and spina nasalis posterior, (8) distance between left and right foramen infraorbitalis, (9) distance between left and right infraorbital suture, (10) distance between left and right foramen palatinum majus, (11) distance between left and right foramen ovale, (12) distance between left and right canalis caroticus, and (13) distance between left and right occipital condyle. Figures 1 and 2 show schematic drawing of mandible and human skull along with specific distances measured, respectively.…”

“…In comparison to traditional medical computed tomography (CT) systems, dental CBCT units offer reduced effective radiation doses, shorter acquisition scan times, easier imaging, and lower costs [8][9][10]. Disadvantages associated with dental CBCT include scatter radiation, a limited dynamic range, minimal soft tissue detail, and beam hardening artifacts caused by dental care material and implants [11][12][13][14]. CBCT image quality is influenced by detector quality, imaging setting, voxel size, and hardware/ software characteristics [15].…”

Accuracy of CBCT Measurements of a Human Skull

“…Gutta-percha was heated and glued to mark 13 points on a dry human skull in order to measure the following specific mandibular, maxillary, and skull-base distances: (1) distance between left and right foramen mentales, (2) distance between left and right distal tubercules of mandibular second molars, (3) distance between left and right angulus mandibulae, (4) distance between left and right coronoid process, (5) distance between left and right incisura mandibulae, (6) distance between left and right fovea pterygoidea, (7) distance between spina nasalis anterior and spina nasalis posterior, (8) distance between left and right foramen infraorbitalis, (9) distance between left and right infraorbital suture, (10) distance between left and right foramen palatinum majus, (11) distance between left and right foramen ovale, (12) distance between left and right canalis caroticus, and (13) distance between left and right occipital condyle. Figures 1 and 2 show schematic drawing of mandible and human skull along with specific distances measured, respectively.…”

“…In comparison to traditional medical computed tomography (CT) systems, dental CBCT units offer reduced effective radiation doses, shorter acquisition scan times, easier imaging, and lower costs [8][9][10]. Disadvantages associated with dental CBCT include scatter radiation, a limited dynamic range, minimal soft tissue detail, and beam hardening artifacts caused by dental care material and implants [11][12][13][14]. CBCT image quality is influenced by detector quality, imaging setting, voxel size, and hardware/ software characteristics [15].…”

Accuracy of CBCT Measurements of a Human Skull

“…Örneğin; endodontik kanal dolum materyalinin etrafındaki siyah koyu bölgeler boşlukları ve dental implantların etrafındaki lineer dü-şük dansiteli alanlar da osteointegrasyon kaybını taklit edebilir. 20 Kanal tedavili dişlerde çizgisel artefaktları azaltmak ve kanal tedavili dişlerin kök kırığı değerlen-dirmesinde tanısal doğruluğu artırmak amacıyla küçük boyutlu voksel kullanılması tercih edilmektedir. 21 Benic ve arkadaşları 22 , dental implantların KIBT görüntülerinde neden olduğu artefaktların yoğun-luğunu ve geometrik şeklini belirlemek amacıyla yaptıkları in vitro çalışmada; implant pozisyonu ne olursa olsun, titanyum implantın bitişiğinde her zaman artefakt görüldüğünü bildirmişlerdir.…”

Konik Işinli Bilgisayarli Tomografide Artefakt Çeşitleri Ve Nedenleri

“…A TCFC é uma técnica de TC que, apesar de apresentar uma menor resolução da imagem em relação à TCMS (Cavalcanti 2008;Draenert et al, 2007;Katsumata et al, 2006;, também promove mensurações precisas e com alta acurácia. Quando comparada à TCMS, a TCFC tem menor custo e produz menor quantidade de radiação, o que levou à sua adoção no planejamento na colocação de implantes dentários (Baba et al, 2004;Cavalcanti 2008;Ganz 2005;Kobayashi 2004, Palomo et al, 2008.…”

“…Embora exista evidência de que ambas as técnicas sejam precisas e tenham acurácia, a presença de artefatos metálicos dentários ainda parece interferir com a análise das imagens (Draenert et al, 2007;Katsumata et al, 2006;Holberg et al, 2005;Perrella et al, 2010 (Fiala et al, 1993;Fiala et al, 1994;Glover et al, 1981). Na reconstrução das imagens, os artefatos metálicos dentários podem ser observados como áreas hipodensas (beam hardening), circunscritas por áreas hiperdensas (estrias) com mais de 1000 Unidades Hounsfield (UH) (escala de densidade cinza da TC), que podem ser observadas próximo de qualquer tipo de metal, incluindo implantes de titânio e restaurações metálicas (Draenert et al, 2007;Perrella et al, 2010). A presença dos artefatos metálicos dentários pode interferir na identificação de estruturas anatômicas importantes, como o forame mentual (Sanders et al, 2007).…”

Avaliação das medidas lineares do rebordo alveolar previamente à colocação de implantes, na presença de artefatos metálicos dentários, usando a tomografia computadorizada de feixe cônico ou tomografia computadorizada multislice