Saved in:
Bibliographic Details
Main Authors: Kumar, Ashwin, Holland, Robbie, Barrett, Corey, Kim, Jangwon, Varma, Maya, Chen, Zhihong, Gao, Yunhe, Zaharchuk, Greg, Taghavi, Tara, Kenthapadi, Krishnaram, Chaudhari, Akshay
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.22989
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866917434641874944
author Kumar, Ashwin
Holland, Robbie
Barrett, Corey
Kim, Jangwon
Varma, Maya
Chen, Zhihong
Gao, Yunhe
Zaharchuk, Greg
Taghavi, Tara
Kenthapadi, Krishnaram
Chaudhari, Akshay
author_facet Kumar, Ashwin
Holland, Robbie
Barrett, Corey
Kim, Jangwon
Varma, Maya
Chen, Zhihong
Gao, Yunhe
Zaharchuk, Greg
Taghavi, Tara
Kenthapadi, Krishnaram
Chaudhari, Akshay
contents Recent medical multimodal foundation models are built as multimodal LLMs (MLLMs) by connecting a CLIP-pretrained vision encoder to an LLM using LLaVA-style finetuning. This two-stage, decoupled approach introduces a projection layer that can distort visual features. This is especially concerning in medical imaging where subtle cues are essential for accurate diagnoses. In contrast, early-fusion generative approaches such as Chameleon eliminate the projection bottleneck by processing image and text tokens within a single unified sequence, enabling joint representation learning that leverages the inductive priors of language models. We present CheXmix, a unified early-fusion generative model trained on a large corpus of chest X-rays paired with radiology reports. We expand on Chameleon's autoregressive framework by introducing a two-stage multimodal generative pretraining strategy that combines the representational strengths of masked autoencoders with MLLMs. The resulting models are highly flexible, supporting both discriminative and generative tasks at both coarse and fine-grained scales. Our approach outperforms well-established generative models across all masking ratios by 6.0% and surpasses CheXagent by 8.6% on AUROC at high image masking ratios on the CheXpert classification task. We further inpaint images over 51.0% better than text-only generative models and outperform CheXagent by 45% on the GREEN metric for radiology report generation. These results demonstrate that CheXmix captures fine-grained information across a broad spectrum of chest X-ray tasks. Our code is at: https://github.com/StanfordMIMI/CheXmix.
format Preprint
id arxiv_https___arxiv_org_abs_2604_22989
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle CheXmix: Unified Generative Pretraining for Vision Language Models in Medical Imaging
Kumar, Ashwin
Holland, Robbie
Barrett, Corey
Kim, Jangwon
Varma, Maya
Chen, Zhihong
Gao, Yunhe
Zaharchuk, Greg
Taghavi, Tara
Kenthapadi, Krishnaram
Chaudhari, Akshay
Computer Vision and Pattern Recognition
Artificial Intelligence
Recent medical multimodal foundation models are built as multimodal LLMs (MLLMs) by connecting a CLIP-pretrained vision encoder to an LLM using LLaVA-style finetuning. This two-stage, decoupled approach introduces a projection layer that can distort visual features. This is especially concerning in medical imaging where subtle cues are essential for accurate diagnoses. In contrast, early-fusion generative approaches such as Chameleon eliminate the projection bottleneck by processing image and text tokens within a single unified sequence, enabling joint representation learning that leverages the inductive priors of language models. We present CheXmix, a unified early-fusion generative model trained on a large corpus of chest X-rays paired with radiology reports. We expand on Chameleon's autoregressive framework by introducing a two-stage multimodal generative pretraining strategy that combines the representational strengths of masked autoencoders with MLLMs. The resulting models are highly flexible, supporting both discriminative and generative tasks at both coarse and fine-grained scales. Our approach outperforms well-established generative models across all masking ratios by 6.0% and surpasses CheXagent by 8.6% on AUROC at high image masking ratios on the CheXpert classification task. We further inpaint images over 51.0% better than text-only generative models and outperform CheXagent by 45% on the GREEN metric for radiology report generation. These results demonstrate that CheXmix captures fine-grained information across a broad spectrum of chest X-ray tasks. Our code is at: https://github.com/StanfordMIMI/CheXmix.
title CheXmix: Unified Generative Pretraining for Vision Language Models in Medical Imaging
topic Computer Vision and Pattern Recognition
Artificial Intelligence
url https://arxiv.org/abs/2604.22989