AI-Based Radiographic Detection of Periodontal Defects

University of Cagliari

Status

Completed

Conditions

Periodontitis

Study type

Observational

Funder types

Other

Identifiers

NCT07086625

PerioDefects-AI

Details and patient eligibility

About

The primary objective of the study is to develop and validate a machine learning model for the automatic identification of periodontal vertical bone defects, improving diagnostic accuracy and efficiency.

The study comprises three phases:

Public dataset annotation: Approximately 7,000 intraoral radiographs will be manually annotated by experts to classify periodontal bone defects (1-wall, 2+ walls, craters, furcation involvement).
Model training: A deep learning algorithm will be trained on the annotated images to learn automatic recognition of the defects.
Clinical validation: The model will be tested on a dataset of 150 anonymized radiographs from 20-30 patients treated at AOU (Azienda Ospedaliero Universitaria) Cagliari, comparing its performance to expert dental evaluations.

Full description

To address the challenge of detecting periodontal osseous defects, the study will employ the YOLOv8 (You Only Look Once versione 8) framework, a state-of-the-art deep learning model optimized for object detection tasks. This architecture is known for its balance between accuracy and inference speed, making it suitable for clinical applications that require efficient processing.

The YOLOv8l (large) variant will be selected to maximize detection accuracy, given the complexity of the task. The architecture will include:

Backbone: a convolutional neural network (CNN) for multi-scale feature extraction;
Neck: a feature pyramid network (FPN) to integrate spatial and semantic information across layers;
Head: a detection module responsible for class probabilities and bounding box predictions.

Model Training

The training will be performed on a dataset consisting of approximately 406 images for training, 58 for validation, and 117 for testing. Annotations will include bounding boxes for four types of defects: 1-wall, 2+ walls, craters, and furcation involvement. The dataset will be formatted according to YOLO standards.

Key training parameters will include:

Input resolution: 640 × 640 pixels
Batch size: 16
Optimizer: AdamW with a learning rate of 0.0014
Epochs: 100
Loss function: a combination of box, class, and distribution focal loss (DFL)
Hardware: NVIDIA GeForce RTX 4090 with mixed precision training

Inference and Evaluation

Inference will be conducted on the test set, and model performance will be evaluated using standard object detection metrics. These will include:

Intersection over Union (IoU) to measure the overlap between predicted and ground truth bounding boxes
Precision and recall, computed based on true positives, false positives, and false negatives
Confidence threshold (initially set at 0.25) to filter out low-confidence predictions
Precision-recall curves, to visualize the trade-off between precision and recall at varying thresholds

Performance will be summarized using mean Average Precision (mAP):

mAP@0.5: mean average precision at a fixed IoU threshold of 0.5
mAP@0.5:0.95: mean average precision averaged across multiple IoU thresholds (from 0.5 to 0.95 in 0.05 increments)

The model's detection capabilities will be assessed across all four classes of periodontal bone defects, providing a comprehensive evaluation of its diagnostic potential.

Enrollment

500 patients

Sex

All

Volunteers

No Healthy Volunteers

Inclusion criteria