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REVIEW 3 major objections 2 minor 28 references

Brain MRI models produce auditable diagnoses by generating hypotheses, marking supporting regions with boxes, and verifying them.

Reviewed by Pith at T0; open to challenge. T0 means a machine referee read the full paper against a public rubric. the ladder, T0–T4 →

T0 review · grok-4.3

2026-06-25 20:39 UTC pith:BBIP47A6

load-bearing objection BrReMark adds explicit ROI marking plus RL verification and synthetic pathology data to brain MRI VLMs, but the abstract gives no ablations or baseline controls so the big reported gains cannot be pinned on those additions. the 3 major comments →

arxiv 2606.25894 v1 pith:BBIP47A6 submitted 2026-06-24 cs.CV cs.AI

Enhancing Brain MRI Anomaly Detection and Reasoning with ROI Rethink and Synthetic Data

classification cs.CV cs.AI
keywords brain MRIanomaly detectionvision-language modelsROI markinghypothesis verificationsynthetic pathology datareinforcement learninghallucination reduction
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved

The pith

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper introduces BrReMark, where the model first proposes possible abnormalities, grounds each hypothesis by drawing an explicit bounding box on the MRI, and then re-examines the marked area to accept or reject the finding. Training uses supervised fine-tuning on full reasoning trajectories plus reinforcement learning whose reward combines localization accuracy with diagnostic correctness, and augments data with domain-randomized synthetic pathologies. On an internal benchmark this raises mAP50 from 0.74% to 37.54% and yields 21.57% Clinical F1, while on the NOVA out-of-distribution set it cuts false positives by 45.7% relative to prior work. A reader cares because single-pass medical vision-language models currently offer no spatial evidence, making outputs impossible to audit and prone to hallucination on both routine and rare cases.

Core claim

BrReMark performs open-ended brain MRI diagnosis by first generating hypotheses about potential abnormalities, grounding them through explicit bounding-box marking, and verifying conclusions by re-examining the marked evidence. It is trained with supervised fine-tuning on structured reasoning trajectories and reinforcement learning using a composite reward on localization accuracy and diagnostic reasoning, plus domain-randomization pathology synthesis to improve OOD generalizability. The resulting model achieves substantially higher mAP50, Clinical F1, and diagnostic accuracy on an internal benchmark and a 45.7% false-positive reduction on the NOVA OOD benchmark.

What carries the argument

The hypothesis-generation, bounding-box grounding, and verification loop that forces the model to link each textual conclusion to specific image regions before finalizing the diagnosis.

Load-bearing premise

The large gains in localization and diagnostic metrics arise from the ROI marking and verification loop rather than from model scale, total training compute, or the choice of internal and NOVA benchmarks.

What would settle it

Train an otherwise identical model of the same size and total compute without the bounding-box marking and re-examination steps on the same data, then compare its mAP50, Clinical F1, and false-positive rate on the NOVA OOD set to those reported for BrReMark.

Watch this falsifier — get emailed when new claim-graph text bears on it.

If this is right

  • Model outputs become auditable because clinicians can directly inspect the marked regions that support each claim.
  • Hallucination drops on both in-distribution and rare OOD pathologies because verification must succeed on the marked evidence.
  • The composite RL reward that jointly optimizes localization and reasoning produces more coherent diagnostic chains than single-pass inference.
  • Domain-randomized synthetic pathology data extends the verification loop's benefits to scans containing abnormalities absent from real training data.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

  • The same explicit marking-plus-verification pattern could be applied to CT or X-ray interpretation without changing the overall training recipe.
  • Removing only the re-examination step while keeping hypothesis generation and marking would likely collapse performance toward the base model, isolating the verification loop as the load-bearing component.
  • Pairing the framework with a larger base vision-language model would be a direct test of whether the ROI loop scales additively with model capacity.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit.

Referee Report

3 major / 2 minor

Summary. The paper introduces BrReMark, a framework for open-ended brain MRI diagnosis that generates explicit hypotheses about abnormalities, grounds them via bounding-box ROI marking, and verifies conclusions by re-examining the marked regions. Training uses supervised fine-tuning on structured trajectories plus reinforcement learning with a composite reward on localization and diagnostic accuracy, augmented by domain-randomization synthetic pathology data. On an internal benchmark it reports mAP50 rising from 0.74% to 37.54%, Clinical F1 of 21.57%, and 45.26% diagnostic accuracy; on the NOVA OOD set it claims a 45.7% false-positive reduction versus prior state-of-the-art, attributing these gains to the hypothesis-verification loop and synthetic augmentation.

Significance. If the performance deltas can be causally attributed to the explicit ROI marking, verification loop, and synthetic data rather than model scale or training regime differences, the work would supply a practical, auditable mechanism for reducing hallucinations in medical vision-language models and improving spatial grounding in open-ended diagnosis.

major comments (3)
  1. [Results section (Tables 1–3)] Results section (Tables 1–3 and associated text): the mAP50 gain from 0.74% to 37.54% and the Clinical F1 / accuracy numbers are presented as evidence for the ROI-rethink mechanism, yet no information is given on whether the base model shares the identical backbone size, total training tokens, or data mixture; without these controls the attribution to the proposed architecture cannot be established.
  2. [Methods (§3–4)] Methods (§3–4): no ablation is reported that removes only the hypothesis-generation, bounding-box grounding, or verification steps (or the RL verification reward) while holding model scale, compute, and data fixed; such an ablation is required to support the central claim that these components, rather than scale or benchmark choice, drive the reported gains.
  3. [OOD evaluation (NOVA results)] OOD evaluation (NOVA results): the 45.7% false-positive reduction versus SOTA is presented without confirming that the SOTA baseline uses the same model capacity or training volume; absent this, the reduction could arise from differences in model scale or the particular choice of internal benchmark and NOVA set rather than the BrReMark framework.
minor comments (2)
  1. [Abstract] The abstract states numeric gains without accompanying statistical tests, error bars, or ablation tables; adding these in the results section would strengthen readability.
  2. [Methods] Notation for the composite RL reward (localization accuracy + diagnostic reasoning) is introduced without an explicit equation; providing the precise weighting formula would aid reproducibility.

Simulated Author's Rebuttal

3 responses · 0 unresolved

We thank the referee for the constructive and detailed feedback, which highlights important aspects of experimental controls needed to support causal claims. We address each major comment below with clarifications based on the manuscript and indicate planned revisions.

read point-by-point responses
  1. Referee: Results section (Tables 1–3 and associated text): the mAP50 gain from 0.74% to 37.54% and the Clinical F1 / accuracy numbers are presented as evidence for the ROI-rethink mechanism, yet no information is given on whether the base model shares the identical backbone size, total training tokens, or data mixture; without these controls the attribution to the proposed architecture cannot be established.

    Authors: BrReMark is implemented on top of the identical base model used for the reported baseline, sharing the same backbone architecture, parameter count, total training tokens, and data mixture; the only differences are the added hypothesis-generation, ROI marking, verification loop, and RL reward components. We will revise the results section and experimental setup to explicitly document these shared elements and the controlled differences. revision: yes

  2. Referee: Methods (§3–4): no ablation is reported that removes only the hypothesis-generation, bounding-box grounding, or verification steps (or the RL verification reward) while holding model scale, compute, and data fixed; such an ablation is required to support the central claim that these components, rather than scale or benchmark choice, drive the reported gains.

    Authors: We acknowledge that full isolated ablations of each component (hypothesis generation, bounding-box grounding, verification, and RL reward) with all other factors fixed were not included. The current results compare the complete framework against the base model. We will add a dedicated ablation subsection in the revised methods and results, or note computational limits as a limitation if full ablations cannot be completed within revision timeline. revision: partial

  3. Referee: OOD evaluation (NOVA results): the 45.7% false-positive reduction versus SOTA is presented without confirming that the SOTA baseline uses the same model capacity or training volume; absent this, the reduction could arise from differences in model scale or the particular choice of internal benchmark and NOVA set rather than the BrReMark framework.

    Authors: The NOVA comparison uses published SOTA numbers from prior work rather than re-implemented equivalents under identical conditions. We will revise the OOD evaluation section to report the model capacities and training details of the cited SOTA methods where available in the literature, and to clarify the nature of the comparison while retaining the reported false-positive reduction. revision: yes

Circularity Check

0 steps flagged

No circularity: derivation chain is self-contained with independent training and evaluation steps

full rationale

The abstract and description present a training pipeline (SFT on reasoning trajectories + RL with composite reward on localization/diagnostic accuracy + synthetic augmentation) whose outputs are then measured on held-out internal and NOVA benchmarks. No equations, reward definitions, or self-citations are supplied that would make the reported mAP50, Clinical F1, or FP reductions equivalent to the inputs by construction. The method is described as producing the metrics rather than the metrics being presupposed in the reward or uniqueness claims. This is the normal non-circular case for an empirical methods paper.

Axiom & Free-Parameter Ledger

0 free parameters · 0 axioms · 1 invented entities

Abstract-only review supplies no equations or implementation details, so the ledger is largely empty; the composite reward function and domain-randomization parameters are presumed to contain fitted values whose exact count cannot be determined.

invented entities (1)
  • BrReMark framework no independent evidence
    purpose: To enforce explicit hypothesis-verification via ROI marking in brain MRI diagnosis
    Introduced as the central contribution; no independent evidence outside the paper is provided

pith-pipeline@v0.9.1-grok · 5777 in / 1383 out tokens · 25170 ms · 2026-06-25T20:39:55.165854+00:00 · methodology

0 comments
read the original abstract

Medical vision-language models typically generate diagnoses through single-pass inference without indicating which image regions support their conclusions. This lack of spatial grounding limits clinical utility: outputs cannot be audited, and models may hallucinate findings on normal scans. We present BrReMark (Brain Rethink via ROI Marking), a framework that introduces explicit region marking into brain MRI diagnosis. The model first generates hypotheses about potential abnormalities and grounds them through explicit bounding box marking, then verifies conclusions by re-examining the marked evidence. Training combines supervised fine-tuning on structured reasoning trajectories with reinforcement learning using a composite reward over localization accuracy and diagnostic reasoning. Furthermore, we integrate a domain randomization-based pathology synthesis augmentation strategy to improve the model's generalizability to out-of-distribution (OOD) data. On internal benchmark, BrReMark improves mAP50 from 0.74% to 37.54% compared to the base model, while achieving 21.57% Clinical F1 and 45.26% diagnostic accuracy. On NOVA OOD benchmark, it also achieves competitive overall performance with a 45.7% reduction in false positives compared to the state-of-the-art, indicating reduced hallucination on rare pathologies. These findings suggest that explicit hypothesis-verification grounding is a practical path toward trustworthy open-ended brain MRI diagnosis across both in-distribution and OOD settings.

Figures

Figures reproduced from arXiv: 2606.25894 by Jie Xu, Shangkun Li, Yi Guo, Yuanyuan Wang, Zeju Li.

Figure 1
Figure 1. Figure 1: Left: Data curation and training pipeline. Training data combines real ab￾normal slices, normal controls, and SynthSeg-generated slices. Right: BrReMark In￾ference pipeline. Given a brain MRI and query, the model first generates a hypothesis and invokes mark_bbox to localize suspicious regions (Turn 1), then re-examines the marked image to verify findings and produce a grounded diagnosis (Turn 2). stage. T… view at source ↗
Figure 2
Figure 2. Figure 2: Training data formats for BrReMark. (a) SFT example demonstrating the two￾turn reasoning format with <think> and <tool_call> tags for normal cases. (b) RL example showing structured answer format with ground-truth bounding box and refer￾ence diagnosis used for multi-component reward computation during GRPO training. ri = 0 if lesions are fabricated on healthy brain images; (3) Synthetic Mask￾ing: rllm is e… view at source ↗

discussion (0)

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Reference graph

Works this paper leans on

28 extracted references · 10 canonical work pages · 9 internal anchors

  1. [1]

    Ixi dataset.https://brain-development.org/ixi-dataset/(2023), accessed: 2023-02-15

  2. [2]

    Qwen2.5-VL Technical Report

    Bai, S., Chen, K., Liu, X., Wang, J., Ge, W., Song, S., Dang, K., Wang, P., Wang, S., Tang, J., et al.: Qwen2.5-vl technical report. arXiv preprint arXiv:2502.13923 (2025)

  3. [3]

    The RSNA-ASNR-MICCAI BraTS 2021 Benchmark on Brain Tumor Segmentation and Radiogenomic Classification

    Baid, U., Ghodasara, S., Mohan, S., Bilello, M., Calabrese, E., Colak, E., Farahani, K., Kalpathy-Cramer, J., Kitamura, F.C., Pati, S., et al.: The rsna-asnr-miccai brats 2021 benchmark on brain tumor segmentation and radiogenomic classifica- tion. arXiv preprint arXiv:2107.02314 (2021)

  4. [4]

    The Cancer Imaging Archive10(2021)

    Bakas, S., Sako, C., Akbari, H., Bilello, M., Sotiras, A., Shukla, G., Rudie, J., Flo- res Santamaria, N., Fathi Kazerooni, A., Pati, S., et al.: Multi-parametric magnetic resonance imaging (mpmri) scans for de novo glioblastoma (gbm) patients from the university of pennsylvania health system (upenn-gbm). The Cancer Imaging Archive10(2021)

  5. [5]

    Advances in Neural Information Processing Systems38(2026)

    Bercea, C., Li, J., Raffler, P., Riedel, E.O., Schmitzer, L., Kurz, A., Bitzer, F., Roßmüller, P., Canisius, J., Beyrle, M., et al.: Nova: A benchmark for rare anomaly localization and clinical reasoning in brain mri. Advances in Neural Information Processing Systems38(2026)

  6. [6]

    Medical image analysis86, 102789 (2023) 10 S

    Billot, B., Greve, D.N., Puonti, O., Thielscher, A., Van Leemput, K., Fischl, B., Dalca, A.V., Iglesias, J.E., et al.: Synthseg: Segmentation of brain mri scans of any contrast and resolution without retraining. Medical image analysis86, 102789 (2023) 10 S. Li et al

  7. [7]

    In: Proceedings of the 2024 conference on empirical methods in natural language processing

    Chen, J., Gui, C., Ouyang, R., Gao, A., Chen, S., Chen, G.H., Wang, X., Cai, Z., Ji, K., Wan, X., et al.: Towards injecting medical visual knowledge into multimodal llms at scale. In: Proceedings of the 2024 conference on empirical methods in natural language processing. pp. 7346–7370 (2024)

  8. [8]

    Gemini 2.5: Pushing the Frontier with Advanced Reasoning, Multimodality, Long Context, and Next Generation Agentic Capabilities

    Comanici, G., Bieber, E., Schaekermann, M., Pasupat, I., Sachdeva, N., Dhillon, I., Blistein, M., Ram, O., Zhang, D., Rosen, E., et al.: Gemini 2.5: Pushing the frontier with advanced reasoning, multimodality, long context, and next generation agentic capabilities. arXiv preprint arXiv:2507.06261 (2025)

  9. [9]

    Advances in Neural Information Processing Systems38, 116522–116543 (2026)

    Fan, Y., He, X., Yang, D., Zheng, K., Kuo, C.C., Zheng, Y., Guan, X., Wang, X.: Grit: Teaching mllms to think with images. Advances in Neural Information Processing Systems38, 116522–116543 (2026)

  10. [10]

    Google DeepMind: Gemini 3: The next generation of multimodal ai.https:// deepmind.google/technologies/gemini/(2025), accessed: 2026-02-27

  11. [11]

    Scientific data9(1), 762 (2022)

    Hernandez Petzsche, M.R., de la Rosa, E., Hanning, U., Wiest, R., Valenzuela, W., Reyes, M., Meyer, M., Liew, S.L., Kofler, F., Ezhov, I., et al.: Isles 2022: A multi- center magnetic resonance imaging stroke lesion segmentation dataset. Scientific data9(1), 762 (2022)

  12. [12]

    GPT-4o System Card

    Hurst, A., Lerer, A., Goucher, A.P., Perelman, A., Ramesh, A., Clark, A., Os- trow, A., Welihinda, A., Hayes, A., Radford, A., et al.: Gpt-4o system card. arXiv preprint arXiv:2410.21276 (2024)

  13. [13]

    Scientific Data 5(1), 1–10 (2018)

    Lau, J.J., Gayen, S., Ben Abacha, A., Demner-Fushman, D.: A dataset of clinically generated visual questions and answers about radiology images. Scientific Data 5(1), 1–10 (2018)

  14. [14]

    IEEE Journal of Biomedical and Health Informatics (2025)

    Lei, J., Zhang, X., Wu, C., Dai, L., Zhang, Y., Zhang, Y., Wang, Y., Xie, W., Li, Y.: Interpretable brain mri report generation anchored by lesion topography. IEEE Journal of Biomedical and Health Informatics (2025)

  15. [15]

    Advances in Neural Information Processing Systems36, 28541–28564 (2023)

    Li, C., Wong, C., Zhang, S., Usuyama, N., Liu, H., Yang, J., Naumann, T., Poon, H., Gao, J.: Llava-med: Training a large language-and-vision assistant for biomedicine in one day. Advances in Neural Information Processing Systems36, 28541–28564 (2023)

  16. [16]

    Scientific data9(1), 320 (2022)

    Liew, S.L., Lo, B.P., Donnelly, M.R., Zavaliangos-Petropulu, A., Jeong, J.N., Barisano, G., Hutton, A., Simon, J.P., Juliano, J.M., Suri, A., et al.: A large, curated, open-source stroke neuroimaging dataset to improve lesion segmentation algorithms. Scientific data9(1), 320 (2022)

  17. [17]

    In: IEEE International Symposium on Biomedical Imaging (ISBI)

    Liu, B., Zhan, L.M., Xu, L., Ma, L., Yang, Y., Wu, X.M.: Slake: A semantically- labeled knowledge-enhanced dataset for medical visual question answering. In: IEEE International Symposium on Biomedical Imaging (ISBI). pp. 1650–1654. IEEE (2021)

  18. [18]

    arXiv preprint arXiv:2406.03712 (2024)

    Liu, L., Yang, X., Lei, J., Shen, Y., Wang, J., Wei, P., Chu, Z., Qin, Z., Ren, K.: A survey on medical large language models: Technology, application, trustworthiness, and future directions. arXiv preprint arXiv:2406.03712 (2024)

  19. [19]

    In: International Conference on Medi- cal Image Computing and Computer-Assisted Intervention

    Pan, J., Liu, C., Wu, J., Liu, F., Zhu, J., Li, H.B., Chen, C., Ouyang, C., Rueck- ert, D.: Medvlm-r1: Incentivizing medical reasoning capability of vision-language models (vlms) via reinforcement learning. In: International Conference on Medi- cal Image Computing and Computer-Assisted Intervention. pp. 337–347. Springer (2025)

  20. [20]

    DeepSeekMath: Pushing the Limits of Mathematical Reasoning in Open Language Models

    Shao, Z., Wang, P., Zhu, Q., Xu, R., Song, J., Bi, X., Zhang, H., Zhang, M., Li, Y., Wu, Y., et al.: Deepseekmath: Pushing the limits of mathematical reasoning in open language models. arXiv preprint arXiv:2402.03300 (2024) BrReMark 11

  21. [21]

    In: Proceedings of the Twentieth European Conference on Computer Systems

    Sheng, G., Zhang, C., Ye, Z., Wu, X., Zhang, W., Zhang, R., Peng, Y., Lin, H., Wu, C.: Hybridflow: A flexible and efficient rlhf framework. In: Proceedings of the Twentieth European Conference on Computer Systems. pp. 1279–1297 (2025)

  22. [22]

    OpenThinkIMG: Learning to Think with Images via Visual Tool Reinforcement Learning

    Su, Z., Li, L., Song, M., Hao, Y., Yang, Z., Zhang, J., Chen, G., Gu, J., Li, J., Qu, X., et al.: Openthinkimg: Learning to think with images via visual tool reinforce- ment learning. arXiv preprint arXiv:2505.08617 (2025)

  23. [23]

    In: International Conference on Medi- cal Image Computing and Computer-Assisted Intervention

    Wang, P., Zhang, H., He, Z., Peng, Z., Yuan, Y.: Ftspl: enhancing brain analysis with fmri-text synergistic prompt learning. In: International Conference on Medi- cal Image Computing and Computer-Assisted Intervention. pp. 564–574. Springer (2024)

  24. [24]

    Lingshu: A Generalist Foundation Model for Unified Multimodal Medical Understanding and Reasoning

    Xu, W., Chan, H.P., Li, L., Aljunied, M., Yuan, R., Wang, J., Xiao, C., Chen, G., Liu,C.,Li,Z.,etal.:Lingshu:Ageneralistfoundationmodelforunifiedmultimodal medical understanding and reasoning. arXiv preprint arXiv:2506.07044 (2025)

  25. [25]

    ACM Computing Surveys58(11), 1–35 (2026)

    Zhang, Y., Gao, J., Tan, Z., Zhou, L., Ding, K., Zhou, M., Zhang, S., Wang, D.: Data-centric foundation models in computational healthcare: A survey. ACM Computing Surveys58(11), 1–35 (2026)

  26. [26]

    Advances in neural information processing systems36, 46595–46623 (2023)

    Zheng, L., Chiang, W.L., Sheng, Y., Zhuang, S., Wu, Z., Zhuang, Y., Lin, Z., Li, Z., Li, D., Xing, E., et al.: Judging llm-as-a-judge with mt-bench and chatbot arena. Advances in neural information processing systems36, 46595–46623 (2023)

  27. [27]

    DeepEyes: Incentivizing "Thinking with Images" via Reinforcement Learning

    Zheng, Z., Yang, M., Hong, J., Zhao, C., Xu, G., Yang, L., Shen, C., Yu, X.: Deepeyes: Incentivizing" thinking with images" via reinforcement learning. arXiv preprint arXiv:2505.14362 (2025)

  28. [28]

    InternVL3: Exploring Advanced Training and Test-Time Recipes for Open-Source Multimodal Models

    Zhu, J., Wang, W., Chen, Z., Liu, Z., Ye, S., Gu, L., Tian, H., Duan, Y., Su, W., Shao, J., et al.: Internvl3: Exploring advanced training and test-time recipes for open-source multimodal models. arXiv preprint arXiv:2504.10479 (2025)