Background: While large language models (LLMs) have demonstrated impressive capabilities in question-answering (QA) tasks, their utilization in analyzing ocular imaging data remains limited. We aim to develop an interactive system that harnesses LLMs for report generation and visual question answering in the context of fundus fluorescein angiography (FFA).Methods: Our system comprises two components: an image-text alignment module for report generation and a GPT-based module (Llama 2) for interactive QA. To comprehensively assess the system's performance, we conducted both automatic and manual evaluations. The automatic evaluation encompassed language-based metrics (BLEU, CIDEr, ROUGE, SPICE) and classification-based metrics (accuracy, sensitivity, specificity, precision, F1-score). Additionally, three ophthalmologists participated in a manual assessment, evaluating the completeness and correctness of generated reports, as well as accuracy, completeness, and potential harm of generated answers.Results: Model development leveraged a dataset of 654,343 FFA images from 9,392 participants. In the automatic evaluation of generated reports, our system demonstrated satisfactory performance, yielding scores of BLEU1 = 0.48, BLEU2 = 0.42, BLEU3 = 0.38, BLEU4 = 0.34, CIDEr = 0.33, ROUGE = 0.36, and SPICE = 0.18. Notably, the top five conditions exhibited strong specificity (≥ 0.94) and accuracy (ranging from 0.88 to 0.91), with F1-scores spanning from 0.66 to 0.82. The manual assessment revealed that the generated reports were on par with the ground truth reports, with 68.3% achieving high accuracy and 62.3% achieving high completeness. In the manual QA evaluation, the consensus among the three ophthalmologists was that the majority of answers were characterized by high accuracy, completeness, and safety (70.7% as error-free, 84.0% as complete, and 93.7% as harmless). Notably, substantial agreement was observed among the ophthalmologists both in the evaluation of generated reports and answers, as reflected by kappa values ranging from 0.739 to 0.834.Conclusions: This study introduces an innovative framework that merges multi-modal transformers and LLMs, yielding enhancements in ophthalmic image interpretation. Moreover, the system facilitates dynamic communication between ophthalmologists and patients through interactive capabilities, heralding a new era of collaborative diagnostic processes.