A custom-made guide-wire positioning device for Hip Surface Replacement Arthroplasty: description and first results

Raaijmaakers, Martijn; Gelaude, Frederik; Smedt, K De; Clijmans, Tim; Dille, J.; Mulier, Michiel

doi:10.1186/1471-2474-11-161

Cited by 31 publications

(30 citation statements)

References 27 publications

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“…The absolute error between the preoperative planning and the femoral guidewire insertion for RHA was significantly better using the wide contact type than the narrow contact type in the present study, and these results were comparable with other PSG reports, which showed errors of 0.6°–4.2° for the stem‐shaft angle and 0.4°–8.2° for anteversion in the clinical situation . The results for the wide‐base‐contact PSG are also comparable with reports from a previously published navigation study (Table ).…”

Section: Discussionsupporting

confidence: 91%

“…A PSG for implantation in total knee arthroplasty has been increasingly used , but the usefulness of PSGs in total hip arthroplasty (THA) has been only sporadically reported , including a PSG for guidewire insertion in resurfacing THA (RHA) and a cup implantation guide . The absolute error of the RHA femoral guidewire when comparing preoperative planning and the postoperative implantation using CT was 0.6°–4.2° for the stem‐shaft angle and 0.4°–8.2° for anteversion in clinical situations . The absolute error of the cup implantation guide was 0.7°–5.5° for the inclination angle and 0.8°–6.4° for anteversion in clinical situations .…”

Section: Introductionmentioning

confidence: 99%

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Validation of patient specific surgical guides in total hip arthroplasty

Sakai

Hanada²,

Murase

et al. 2013

Int J Med Robotics Comput Assist Surg

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Section: Discussionsupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Validation of patient specific surgical guides in total hip arthroplasty

Sakai

Hanada²,

Murase

et al. 2013

Int J Med Robotics Comput Assist Surg

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“…With smooth movements of the bone, the tracking error improves significantly. An accuracy in the order of Ϯ 2 mm/2 .. 4°is achieved, which is aligned with the accuracy of current systems (Raaijmaakers et al, 2010;McMinn, 2009). The root mean square error (RMSE) was used to obtain the errors of position and orientation.…”

Section: Real Scenariomentioning

confidence: 76%

Robotic motion compensation for bone movement, using ultrasound images

Torres

Gonçalves

Martins

2015

Industrial Robot: An International Journal

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Access to this document was granted through an Emerald subscription provided by emerald-srm:468524 [] For AuthorsIf you would like to write for this, or any other Emerald publication, then please use our Emerald for Authors service information about how to choose which publication to write for and submission guidelines are available for all. Please visit www.emeraldinsight.com/authors for more information. About Emerald www.emeraldinsight.comEmerald is a global publisher linking research and practice to the benefit of society. The company manages a portfolio of more than 290 journals and over 2,350 books and book series volumes, as well as providing an extensive range of online products and additional customer resources and services.Emerald is both COUNTER 4 and TRANSFER compliant. The organization is a partner of the Committee on Publication Ethics (COPE) and also works with Portico and the LOCKSS initiative for digital archive preservation. AbstractPurpose -The purpose of this paper is to present a robotic motion compensation system, using ultrasound images, to assist orthopedic surgery. The robotic system can compensate for femur movements during bone drilling procedures. Although it may have other applications, the system was thought to be used in hip resurfacing (HR) prosthesis surgery to implant the initial guide tool. The system requires no fiducial markers implanted in the patient, by using only non-invasive ultrasound images. Design/methodology/approach -The femur location in the operating room is obtained by processing ultrasound (USA) and computer tomography (CT) images, obtained, respectively, in the intra-operative and pre-operative scenarios. During surgery, the bone position and orientation is obtained by registration of USA and CT three-dimensional (3D) point clouds, using an optical measurement system and also passive markers attached to the USA probe and to the drill. The system description, image processing, calibration procedures and results with simulated and real experiments are presented and described to illustrate the system in operation. Findings -The robotic system can compensate for femur movements, during bone drilling procedures. In most experiments, the update was always validated, with errors of 2 mm/4°. Originality/value -The navigation system is based entirely on the information extracted from images obtained from CT pre-operatively and USA intra-operatively. Contrary to current surgical systems, it does not use any type of implant in the bone to track the femur movements.

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“…Since then, the number of applications has grown drastically, both in academic and industrial environments. One can now find patient-specific guides for various surgical procedures such as total knee replacement (Hafez et al 2006, Lombardi et al 2008, total hip replacement (Hananouchi et al 2009), hip surface replacement , Raaijmaakers et a. 2010, Kunz et al 2010, intra-and extraarticular radius malunions (Leong et al 2010, Oka et al 2008, and distal femur osteotomy (Victor et al 2011), Fig.…”

Section: Patient-specific Surgical Guidesmentioning

confidence: 99%

“…For each application, a guide can provide different types of guidance. It can mechanically guide surgical gestures, such as drilling or cutting , Raaijmaakers et al 2010, Kunz et al 2010, Leong et al 2010, Oka et al 2008, Victor et al 2011 or indicate anatomical landmarks for positioning standard instruments (Blanz et al 2004). It can guide the placement of a plate by providing the drilling positions and orientations of plate fixations on preoperative bone (Leong et al 2010, Victor et al 2011.…”

Section: Patient-specific Surgical Guidesmentioning

confidence: 99%

Patient-Specific Modelling in Orthopedics: From Image to Surgery

Gomes

Cauter

Beule

et al. 2012

Biomedical Imaging and Computational Modeling in Biomechanics

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In orthopedic surgery, to decide upon intervention and how it can be optimized, surgeons usually rely on subjective analysis of medical images of the patient, obtained from computed tomography, magnetic resonance imaging, ultrasound or other techniques. Recent advancements in computational performance, image analysis and in silico modeling techniques have started to revolutionize clinical practice through the development of quantitative tools, including patient-specific models aiming at improving clinical diagnosis and surgical treatment. Anatomical and surgical landmarks as well as features extraction can be automated allowing for the creation of general or patient-specific models based on statistical shape models. Preoperative virtual planning and rapid prototyping tools allow the implementation of customized surgical solutions in real clinical environments. In the present chapter we discuss the applications of some of these techniques in orthopedics and present new computer-aided tools that can take us from image analysis to customized surgical treatment.

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A custom-made guide-wire positioning device for Hip Surface Replacement Arthroplasty: description and first results

Cited by 31 publications

References 27 publications

Validation of patient specific surgical guides in total hip arthroplasty

Validation of patient specific surgical guides in total hip arthroplasty

Robotic motion compensation for bone movement, using ultrasound images

Patient-Specific Modelling in Orthopedics: From Image to Surgery

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