Artificial intelligence and machine learning in spine research

Galbusera, Fabio; Casaroli, Gloria; Bassani, Tito

doi:10.1002/jsp2.1044

Cited by 190 publications

(163 citation statements)

References 139 publications

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“…The plans were generated by the proposed computer-assisted tool based on parametric modeling of the vertebral and pedicle shape, maximization of the screw fastening strength, and taking into account two important surgical considerations: (a) pedicle screw placement to simulate the straight-forward surgical insertion technique and (b) pedicle screw entry points to follow the spinal curvature. Although the emerging technologies based on state-of-the-art machine learning approaches [43][44][45][46] may represent an alternative for future modeling of the vertebral bodies, pedicles, and pedicle screw size and trajectories, our approach does not require any training but is based on parametric modeling augmented with morphological, structural, and procedural knowledge of vertebral structures and pedicle screw placement. The pedicle screw placement plans, obtained by different versions of the computer-assisted tool from preoperative CT images, were graded to assess their quality.…”

Section: Discussionmentioning

confidence: 99%

Computer‐assisted pedicle screw trajectory planning using CT‐inferred bone density: A demonstration against surgical outcomes

et al. 2019

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Purpose Image‐guided spine surgery and preoperative computer‐assisted planning provide spine surgeons with tools to improve the safety, accuracy, and reliability of pedicle screw placement. The purpose of this study is to demonstrate a computer‐assisted pedicle screw placement planning tool in comparison to screws as delivered by a spine surgeon. Methods We describe a novel computer‐assisted tool for preoperative pedicle screw placement planning in computed tomography (CT) images, designed with respect to the vertebral shape and structure, and augmented with respect to the considerations of surgical practice. The approach is based on three‐dimensional (3D) modeling of the vertebral body and pedicles, and planning of the pedicle screw size and insertion trajectory by maximizing the screw fastening strength, evaluated through CT‐inferred bone density maps. The approach is augmented by yielding screw plans consistent with the straight‐forward surgical technique of aligning screws parallel to vertebral endplates, and the screw entry points following the spinal curvature to facilitate rod attachment. For a cohort of 25 patients, placement plans were retrospectively obtained for 204 pedicle screws with the computer‐assisted tool from preoperative CT images, while reference trajectories of inserted pedicle screws were reconstructed in 3D from postoperative biplanar radiographs. Results The best performing version of the computer‐assisted tool achieved clinically acceptable preoperative pedicle screw placement plans in 96.6% of the cases, while the comparison to the postoperative reconstructions resulted in 3.4 ± 2.5 mm for the screw entry point location, 2.7 ± 1.6 mm for the screw crossing point location, and 7.4 ± 5.3∘ for the screw sagittal inclination (mean absolute difference ± standard deviation). Conclusion Quantitative comparison revealed that the preoperative placement plans are consistent with the postoperative results, and that the computer‐assisted tool integrating bone density and surgical constraints can successfully incorporate important aspects of pedicle screw placement. The results therefore confirm the accuracy of the tool prior to being integrated in an image‐guidance system.

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Section: Discussionmentioning

confidence: 99%

Computer‐assisted pedicle screw trajectory planning using CT‐inferred bone density: A demonstration against surgical outcomes

et al. 2019

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“…As CT and MRI scans became available in bulk, they became strong datasets for ML training, yielding stronger ML models. 26 With regards to spinal visualization and segmentation, many groups have applied sophisticated automated analysis of CT and MRI to both normal and pathological spines. One University of Cincinnati group used a "guess-and-revise" ML algorithm on sagittal MRI scans of whole spines.…”

Section: Automated Visualization and Segmentationmentioning

confidence: 99%

Applications of Machine Learning Using Electronic Medical Records in Spine Surgery

et al. 2019

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Developments in machine learning in recent years have precipitated a surge in research on the applications of artificial intelligence within medicine. Machine learning algorithms are beginning to impact medicine broadly, and the field of spine surgery is no exception. Electronic medical records are a key source of medical data that can be leveraged for the creation of clinically valuable machine learning algorithms. This review examines the current state of machine learning using electronic medical records as it applies to spine surgery. Studies across the electronic medical record data domains of imaging, text, and structured data are reviewed. Discussed applications include clinical prognostication, preoperative planning, diagnostics, and dynamic clinical assistance, among others. The limitations and future challenges for machine learning research using electronic medical records are also discussed.

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“…The paradigm shift in health care made possible by these technologies has been widely discussed (Galbusera, Casaroli, & Bassani, ). Because AI, machine learning, and big data can identify the occurrence of a disease at an early stage—sometimes even before any observable symptoms—they enable a shift from treatment to predictive health‐care models that reduce the chances of a patient developing chronic health problems, and allow timely clinical treatment to be offered.…”

Section: Apollo Hospitals: a Health‐care Pioneermentioning

confidence: 99%

“…When an AI system provided by an international vendor has been trained using data that is very different from a particular country's local conditions, this could produce false results and lead to unanticipated errors. For example, inappropriate training data may cause unforeseen biases when diagnosing illnesses, prescribing drugs, or suggesting treatment plans (Galbusera et al, ).…”

Section: Apollo Hospitals: a Health‐care Pioneermentioning

confidence: 99%

“…Even if everything is in place, the issue of accountability and responsibility for decisions remains (Galbusera et al, ). It is useful to think of the role of AI on a continuum, ranging from situations where humans and machines work together to perform tasks that humans already do—augmented intelligence—to situations where AI enables humans to do more than they can do currently—assisted intelligence—and to situations where AI performs tasks without human intervention—autonomous intelligence.…”

Section: Apollo Hospitals: a Health‐care Pioneermentioning

confidence: 99%

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