Oral lesions are highly prevalent globally, and oral cancer ranks among the most common malignancies, underscoring the need for AI-driven tools to support early detection and triage, especially in resource-scarce settings. This work investigates the capabilities of multimodal large language models (MLLMs) for automated detection of oral lesions in smartphone-acquired buccal mucosa images. Unlike convolutional neural networks (CNNs), which require large annotated datasets and significant computational resources, MLLMs need no task-specific training and can adapt quickly through intelligent prompting architectures. We propose a novel expert-informed mixture-of-experts paradigm that mimics the idealistic collaborative medical decision-making approach of clinicians, where each expert module independently retrieves contextually relevant images and the corresponding expert-generated descriptions from the existing data corpus, guided by different similarity metrics. These enriched examples help the expert to form an independent, informed diagnosis. A specialist MLLM then reviews all expert opinions and the image and synthesises a final decision, effectively emulating a consensus diagnosis process. Experimental results on a dataset of buccal mucosa images show that the proposed method attains a sensitivity of 89.81%, making it comparable with existing CNN-based approaches. Additionally, we provide explainability through a detailed interpretation of experimental results and failure case analysis, supported by insights from medical experts. The proposed framework represents a human–AI collaborative model, where we do not leave diagnostic outcomes entirely to the model’s internal representations. Rather, it actively shapes the model’s reasoning through curated, expert-informed descriptions provided as few-shot examples. Overall, it facilitates reliable decision-making while reducing dependence on large, annotated datasets and extensive computational resources. By enabling accurate and interpretable lesion detection from smartphone images, the proposed approach has strong potential to support early triage in low-resource and remote health care environments, contributing to improved oral cancer prevention and patient outcomes.
Nayak et al. (Thu,) studied this question.