Banana100: Breaking NR-IQA Metrics by 100 Iterative Image Replications with Nano Banana Pro

The multi-step, iterative image editing capabilities of multi-modal agentic systems have transformed digital content creation. Although latest image editing models faithfully follow instructions and generate high-quality images in single-turn edits, we identify a critical weakness in multi-turn editing, which is the iterative degradation of image quality. As images are repeatedly edited, minor artifacts accumulate, rapidly leading to a severe accumulation of visible noise and a failure to follow simple editing instructions. To systematically study these failures, we introduce Banana100, a comprehensive dataset of 28,000 degraded images generated through 100 iterative editing steps, including diverse textures and image content. Alarmingly, image quality evaluators fail to detect the degradation. Among 21 popular no-reference image quality assessment (NR-IQA) metrics, none of them consistently assign lower scores to heavily degraded images than to clean ones. The dual failures of generators and evaluators may threaten the stability of future model training and the safety of deployed agentic systems, if the low-quality synthetic data generated by multi-turn edits escape quality filters. We release the full code and data to facilitate the development of more robust models, helping to mitigate the fragility of multi-modal agentic systems.

MRAnnotator: A Multi-Anatomy Deep Learning Model for MRI Segmentation

Purpose To develop a deep learning model for multi-anatomy and many-class segmentation of diverse anatomic structures on MRI imaging. Materials and Methods In this retrospective study, two datasets were curated and annotated for model development and evaluation. An internal dataset of 1022 MRI sequences from various clinical sites within a health system and an external dataset of 264 MRI sequences from an independent imaging center were collected. In both datasets, 49 anatomic structures were annotated as the ground truth. The internal dataset was divided into training, validation, and test sets and used to train and evaluate an nnU-Net model. The external dataset was used to evaluate nnU-Net model generalizability and performance in all classes on independent imaging data. Dice scores were calculated to evaluate model segmentation performance. Results The model achieved an average Dice score of 0.801 on the internal test set, and an average score of 0.814 on the complete external dataset across 49 classes. Conclusion The developed model achieves robust and generalizable segmentation of 49 anatomic structures on MRI imaging. A future direction is focused on the incorporation of additional anatomic regions and structures into the datasets and model.