Parameter-Efficient Adaptation of SAM 3 for Automated ITV Generation from 4DCT Images
Pith reviewed 2026-06-27 04:30 UTC · model grok-4.3
The pith
Adapting SAM 3 via LoRA plus temporal filtering automates ITV generation from 4DCT scans with seven annotated volumes.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
Parameter-efficient fine-tuning of SAM 3 with LoRA and hard negative mining aligns its text-prompted output to the medical domain; phase-wise predictions are then refined by temporal filtering that exploits the continuous periodic nature of respiration, so genuine anatomy remains contiguous across phases while transient artifacts are suppressed. The resulting contours achieve median Dice scores of 0.968 for pulmonary and 0.910 for cardiac structures with 95th-percentile Hausdorff distances of 0.998 mm and 2.931 mm, eliminate the severe false positives of zero-shot SAM 3, and retain over 95 percent of full-data accuracy when trained on only seven annotated volumes.
What carries the argument
LoRA-adapted SAM 3 segmentation followed by phase-coherent temporal filtering and spatial connectivity analysis.
Load-bearing premise
Genuine anatomy appears in contiguous blocks of phases while transient artifacts appear sporadically.
What would settle it
A 4DCT test set containing irregular or non-periodic motion patterns in which the temporal filtering step fails to raise Dice scores above those of the unadapted zero-shot model.
Figures
read the original abstract
Four-dimensional computed tomography (4DCT) captures the full respiratory cycle of thoracic anatomy, yet current Internal Target Volume contouring workflows process each phase in isolation, discarding temporal coherence and leaving contours vulnerable to phase-specific artifacts. We present a lightweight framework that applies parameter-efficient fine-tuning to the Segment Anything Model 3 (SAM 3) via low-rank adaptation (LoRA) to align its text-prompted segmentation with the medical domain using only seven annotated 3D CT volumes. Furthermore, the framework incorporates a hard negative mining strategy to improve boundary discrimination in low-contrast thoracic regions. At inference, phase-wise predictions are refined through phase-coherent temporal filtering and spatial connectivity analysis. Since respiratory motion is continuous and periodic, genuine anatomy appears in contiguous blocks of phases, whereas transient artifacts appear sporadically and are thus effectively suppressed. Experiments on pulmonary and cardiac structures yield median Dice scores of 0.968 and 0.910 with 95th-percentile Hausdorff distances of 0.998 mm and 2.931 mm, respectively. The proposed framework effectively eliminates the severe false-positive predictions inherent in the zero-shot inference of the unadapted SAM 3. With only seven annotated volumes, the framework retains over 95% of full-data accuracy, and the entire pipeline is trainable on a single consumer-grade GPU, demonstrating a scalable, data-efficient solution for adaptive radiotherapy.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The manuscript proposes a lightweight framework for automated Internal Target Volume (ITV) generation from 4DCT images by applying parameter-efficient fine-tuning (LoRA) to SAM 3 using only seven annotated 3D CT volumes, combined with hard negative mining during training. At inference, phase-wise predictions are refined via phase-coherent temporal filtering and spatial connectivity analysis, justified by the claim that genuine anatomy appears in contiguous phase blocks while transient artifacts are sporadic. Experiments on pulmonary and cardiac structures report median Dice scores of 0.968 and 0.910 with 95th-percentile Hausdorff distances of 0.998 mm and 2.931 mm, claiming elimination of zero-shot false positives and retention of over 95% of full-data accuracy on a single consumer GPU.
Significance. If validated, the work demonstrates a data-efficient adaptation of a foundation model for a clinically relevant radiotherapy task, highlighting the potential of LoRA for medical domain alignment with minimal annotations and low compute. The explicit use of 4D temporal coherence is a distinguishing element, though its contribution to the reported gains requires substantiation to confirm the framework's advantages over zero-shot or fully supervised baselines.
major comments (2)
- [Abstract] Abstract (inference stage): The headline performance metrics and the claim of eliminating severe false-positive predictions are achieved only after the phase-coherent temporal filtering plus spatial connectivity step. The justification rests solely on the untested assumption that 'genuine anatomy appears in contiguous blocks of phases, whereas transient artifacts appear sporadically,' with no quantitative verification on the evaluation data and no ablation isolating the filtering contribution. This makes it impossible to attribute the reported suppression of artifacts and retained accuracy (>95% of full-data) to the LoRA adaptation alone.
- [Abstract] Abstract: The reported numeric results lack accompanying information on total dataset size, cross-validation procedure, additional baselines beyond zero-shot SAM 3, or statistical testing. Without these, the strength of the claims (e.g., median Dice 0.968/0.910 and retention of 95% accuracy) cannot be assessed for robustness or generalizability.
Simulated Author's Rebuttal
We thank the referee for the thoughtful and constructive comments, which highlight important aspects of clarity and substantiation in our work. We address each major comment below and commit to revisions that strengthen the manuscript without misrepresenting our contributions.
read point-by-point responses
-
Referee: [Abstract] Abstract (inference stage): The headline performance metrics and the claim of eliminating severe false-positive predictions are achieved only after the phase-coherent temporal filtering plus spatial connectivity step. The justification rests solely on the untested assumption that 'genuine anatomy appears in contiguous blocks of phases, whereas transient artifacts appear sporadically,' with no quantitative verification on the evaluation data and no ablation isolating the filtering contribution. This makes it impossible to attribute the reported suppression of artifacts and retained accuracy (>95% of full-data) to the LoRA adaptation alone.
Authors: We agree that the reported metrics reflect the full pipeline, including phase-coherent filtering. The filtering is motivated by the established physical properties of periodic respiratory motion in 4DCT, where true anatomical structures exhibit temporal contiguity across phases while artifacts do not. However, to enable clearer attribution, we will add an ablation study that isolates the filtering step (reporting Dice and HD95 with and without it) and include quantitative verification by computing phase-contiguity metrics on both ground-truth annotations and zero-shot predictions within the evaluation set. This will be presented in a new results subsection. revision: yes
-
Referee: [Abstract] Abstract: The reported numeric results lack accompanying information on total dataset size, cross-validation procedure, additional baselines beyond zero-shot SAM 3, or statistical testing. Without these, the strength of the claims (e.g., median Dice 0.968/0.910 and retention of 95% accuracy) cannot be assessed for robustness or generalizability.
Authors: We will revise the abstract to explicitly state the total dataset size (number of 4DCT volumes), the cross-validation procedure (patient-wise), and include a brief note on statistical testing (e.g., reporting inter-quartile ranges or Wilcoxon tests for key comparisons). The full manuscript already details the seven annotated volumes used for adaptation and the full-data baseline for the 95% retention claim; we will ensure these elements are summarized concisely in the abstract and add any feasible additional baselines (such as a standard U-Net) if space permits, or reference them in the main text. revision: yes
Circularity Check
No circularity; empirical results independent of inputs
full rationale
The paper reports experimental Dice/Hausdorff metrics after LoRA fine-tuning on 7 volumes plus inference-time filtering. The filtering step invokes a domain assumption about phase-contiguous anatomy versus sporadic artifacts, but this is stated as prior knowledge rather than derived from any equation or fit within the paper. No equations, fitted parameters renamed as predictions, or self-citation chains appear in the provided text. Performance numbers are measured on held-out data and do not reduce to the method inputs by construction.
Axiom & Free-Parameter Ledger
axioms (1)
- domain assumption Respiratory motion is continuous and periodic so that genuine anatomy appears in contiguous phase blocks while artifacts are sporadic.
Reference graph
Works this paper leans on
-
[1]
In: Seminars in radiation oncology
Cardenas, C.E., Yang, J., Anderson, B.M., Court, L.E., Brock, K.B.: Advances in auto-segmentation. In: Seminars in radiation oncology. vol. 29, pp. 185–197. Elsevier (2019)
2019
-
[2]
Carion, N., Gustafson, L., Hu, Y.T., Debnath, S., Hu, R., Suris, D., Ryali, C., Al- wala, K.V., Khedr, H., Huang, A., Lei, J., Ma, T., Guo, B., Kalla, A., Marks, M., Greer, J., Wang, M., Sun, P., Rädle, R., Afouras, T., Mavroudi, E., Xu, K., Wu, T.H., Zhou, Y., Momeni, L., Hazra, R., Ding, S., Vaze, S., Porcher, F., Li, F., Li, S., Kamath, A., Cheng, H.K....
work page internal anchor Pith review Pith/arXiv arXiv 2025
-
[3]
Nature machine intelligence5(3), 220–235 (2023)
Ding, N., Qin, Y., Yang, G., Wei, F., Yang, Z., Su, Y., Hu, S., Chen, Y., Chan, C.M., Chen, W., et al.: Parameter-efficient fine-tuning of large-scale pre-trained language models. Nature machine intelligence5(3), 220–235 (2023)
2023
-
[4]
Dosovitskiy, A., Beyer, L., Kolesnikov, A., Weissenborn, D., Zhai, X., Unterthiner, T., Dehghani, M., Minderer, M., Heigold, G., Gelly, S., Uszkoreit, J., Houlsby, N.: An image is worth 16x16 words: Transformers for image recognition at scale (2021), https://arxiv.org/abs/2010.11929
work page internal anchor Pith review Pith/arXiv arXiv 2021
-
[5]
Eslick, E.M., Kipritidis, J., Gradinscak, D., Stevens, M.J., Bai- ley, D.L., Harris, B., Booth, J.T., Keall, P.J.: Ct ventilation as a functional imaging modality for lung cancer radiotherapy (ct-vs- pet-ventilation-imaging) (2022). https://doi.org/10.7937/3PPX-7S22, https://www.cancerimagingarchive.net/collection/ct-vs-pet-ventilation-imaging/
- [6]
-
[7]
Hu, E.J., Shen, Y., Wallis, P., Allen-Zhu, Z., Li, Y., Wang, S., Wang, L., Chen, W.: Lora: Low-rank adaptation of large language models (2021), https://arxiv.org/abs/2106.09685
work page internal anchor Pith review Pith/arXiv arXiv 2021
-
[8]
International Commission on Radiation Units and Measure- ments (1999)
International Commission on Radiation Units and Measurements: ICRU Report 62: Prescribing, Recording and Reporting Photon Beam Therapy (Supplement to ICRU Report 50). International Commission on Radiation Units and Measure- ments (1999)
1999
-
[9]
Nature methods18(2), 203–211 (2021)
Isensee, F., Jaeger, P.F., Kohl, S.A., Petersen, J., Maier-Hein, K.H.: nnu-net: a self-configuring method for deep learning-based biomedical image segmentation. Nature methods18(2), 203–211 (2021)
2021
-
[10]
Medical physics33(10), 3874–3900 (2006)
Keall, P.J., Mageras, G.S., Balter, J.M., Emery, R.S., Forster, K.M., Jiang, S.B., Kapatoes, J.M., Low, D.A., Murphy, M.J., Murray, B.R., et al.: The management of respiratory motion in radiation oncology report of aapm task group 76 a. Medical physics33(10), 3874–3900 (2006)
2006
-
[11]
In: Proceedings of the IEEE/CVF international conference on computer vision
Kirillov, A., Mintun, E., Ravi, N., Mao, H., Rolland, C., Gustafson, L., Xiao, T., Whitehead, S., Berg, A.C., Lo, W.Y., et al.: Segment anything. In: Proceedings of the IEEE/CVF international conference on computer vision. pp. 4015–4026 (2023)
2023
-
[12]
Lin, T.Y., Goyal, P., Girshick, R., He, K., Dollár, P.: Focal loss for dense object detection.In:ProceedingsoftheIEEEinternationalconferenceoncomputervision. pp. 2980–2988 (2017)
2017
-
[13]
Loshchilov, I., Hutter, F.: Decoupled weight decay regularization (2019), https://arxiv.org/abs/1711.05101 10 C. Song
work page internal anchor Pith review Pith/arXiv arXiv 2019
-
[14]
Nature communications15(1), 654 (2024)
Ma, J., He, Y., Li, F., Han, L., You, C., Wang, B.: Segment anything in medical images. Nature communications15(1), 654 (2024)
2024
-
[15]
Milletari, F., Navab, N., Ahmadi, S.A.: V-net: Fully convolutional neural networks for volumetric medical image segmentation (2016), https://arxiv.org/abs/1606.04797
work page internal anchor Pith review Pith/arXiv arXiv 2016
-
[16]
SAM 2: Segment Anything in Images and Videos
Ravi, N., Gabeur, V., Hu, Y.T., Hu, R., Ryali, C., Ma, T., Khedr, H., Rädle, R., Rolland, C., Gustafson, L., et al.: Sam 2: Segment anything in images and videos. arXiv preprint arXiv:2408.00714 (2024)
work page internal anchor Pith review Pith/arXiv arXiv 2024
- [17]
-
[18]
In: International Conference on Medical image computing and computer-assisted intervention
Ronneberger, O., Fischer, P., Brox, T.: U-net: Convolutional networks for biomedi- cal image segmentation. In: International Conference on Medical image computing and computer-assisted intervention. pp. 234–241. Springer (2015)
2015
-
[19]
International Journal of Radiation Oncology* Biology* Physics 63(1), 253–260 (2005)
Underberg, R.W., Lagerwaard, F.J., Slotman, B.J., Cuijpers, J.P., Senan, S.: Use of maximum intensity projections (mip) for target volume generation in 4dct scans for lung cancer. International Journal of Radiation Oncology* Biology* Physics 63(1), 253–260 (2005)
2005
-
[20]
Physics in Medicine & Biology48(1), 45–62 (2003)
Vedam, S., Keall, P., Kini, V., Mostafavi, H., Shukla, H., Mohan, R.: Acquiring a four-dimensional computed tomography dataset using an external respiratory signal. Physics in Medicine & Biology48(1), 45–62 (2003)
2003
-
[21]
Radiology: Artificial Intelligence 5(5), e230024 (2023)
Wasserthal, J., Breit, H.C., Meyer, M.T., Pradella, M., Hinck, D., Sauter, A.W., Heye, T., Boll, D.T., Cyriac, J., Yang, S., et al.: Totalsegmentator: robust segmen- tation of 104 anatomic structures in ct images. Radiology: Artificial Intelligence 5(5), e230024 (2023)
2023
- [22]
-
[23]
International Journal of Radiation Oncology* Biology* Physics38(1), 197–206 (1997)
Yan, D., Wong, J., Vicini, F., Michalski, J., Pan, C., Frazier, A., Horwitz, E., Mar- tinez, A.: Adaptive modification of treatment planning to minimize the deleterious effects of treatment setup errors. International Journal of Radiation Oncology* Biology* Physics38(1), 197–206 (1997)
1997
- [24]
- [25]
discussion (0)
Sign in with ORCID, Apple, or X to comment. Anyone can read and Pith papers without signing in.