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Evaluating the Zero-shot Performance of Segment Anything Model 2 in 3D Segmentation of Abdominal Organs in CT Scans


Основні поняття
Segment Anything Model 2 (SAM 2) demonstrated promising zero-shot performance in segmenting certain abdominal organs in CT scans, particularly larger organs with clear boundaries, but struggled with smaller and less defined structures.
Анотація

This study evaluated the zero-shot performance of Segment Anything Model 2 (SAM 2) in 3D segmentation of eight major abdominal organs in CT scans. The researchers used a subset of the TotalSegmentator CT dataset from eight institutions to assess SAM 2's ability to segment the organs.

Key findings:

  • Larger organs with clear boundaries, such as the liver, kidneys, and spleen, demonstrated high segmentation performance, with mean Dice similarity coefficients (DSCs) ranging from 0.821 to 0.891.
  • Smaller organs, such as the gallbladder, pancreas, and adrenal glands, showed lower performance, with mean DSCs ranging from 0.203 to 0.531.
  • The initial slice selected for segmentation and the use of negative prompts significantly influenced the results. Removing negative prompts from the input led to a significant decrease in DSCs for six organs.
  • A moderate positive correlation was observed between organ volume and DSCs, suggesting that volume size is one of several key factors influencing segmentation accuracy.

The study highlights the potential of SAM 2 in medical image segmentation, particularly for larger organs, while also underscoring the importance of optimizing input prompts to enhance the accuracy of the model for smaller and less distinct structures.

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Статистика
The dataset included 123 patients with a mean age of 60.7 ± 15.5 years, consisting of 63 men and 60 women. The final dataset contained 891 organ segmentations after excluding masks with volumes less than 100 voxels. The liver had the largest mean volume of 465,008.6 ± 156,091.0 voxels, while the adrenal glands had the smallest mean volumes of 1,101.86 ± 465.47 voxels (right) and 1,259.03 ± 522.81 voxels (left).
Цитати
"SAM 2 demonstrated promising zero-shot performance in segmenting certain abdominal organs in CT scans, particularly larger organs with clear boundaries." "Performance was significantly influenced by input negative prompts and initial slice selection, highlighting the importance of optimizing these factors."

Ключові висновки, отримані з

by Yosuke Yamag... о arxiv.org 09-25-2024

https://arxiv.org/pdf/2408.06170.pdf
Zero-shot 3D Segmentation of Abdominal Organs in CT Scans Using Segment Anything Model 2

Глибші Запити

How can the performance of SAM 2 be further improved for smaller and less distinct abdominal organs in CT scans?

To enhance the performance of SAM 2 for smaller and less distinct abdominal organs in CT scans, several strategies can be implemented: Fine-tuning with Domain-Specific Data: Although SAM 2 operates effectively in a zero-shot capacity, fine-tuning the model on a curated dataset specifically containing smaller organs can significantly improve segmentation accuracy. This would involve training the model with annotated images of these organs to help it learn their unique characteristics and boundaries. Enhanced Prompt Engineering: The study highlighted the importance of prompt settings in segmentation performance. For smaller organs, utilizing more precise and strategically placed positive prompts can help the model focus on the target area more effectively. Additionally, refining negative prompts to exclude more irrelevant regions could reduce confusion during segmentation. Multi-Scale Analysis: Implementing a multi-scale approach where the model analyzes images at different resolutions could help capture the finer details of smaller organs. This technique allows the model to adapt its focus based on the size and distinctiveness of the organ being segmented. Incorporating Contextual Information: Utilizing contextual information from surrounding structures can aid in distinguishing smaller organs. By integrating additional features or metadata about the anatomical context, SAM 2 could improve its understanding of where smaller organs are located relative to larger, more defined structures. Post-Processing Techniques: Applying advanced post-processing techniques, such as morphological operations or conditional random fields, can refine the segmentation masks generated by SAM 2. These techniques can help smooth out the boundaries and fill in gaps, particularly for smaller organs that may have been poorly segmented. User Feedback Loop: Establishing a feedback mechanism where radiologists can provide input on segmentation results can help iteratively improve the model. This could involve a semi-supervised learning approach where user corrections are used to retrain the model, enhancing its performance over time.

What other medical imaging modalities and anatomical structures could benefit from the zero-shot segmentation capabilities of SAM 2?

The zero-shot segmentation capabilities of SAM 2 can be extended to various medical imaging modalities and anatomical structures beyond abdominal CT scans: MRI Scans: SAM 2 can be applied to MRI imaging, particularly for segmenting brain structures, spinal cord, and soft tissues. The model's ability to generalize can help in identifying complex anatomical features without extensive training on specific MRI datasets. Ultrasound Imaging: In ultrasound, where images can vary significantly due to operator technique and patient anatomy, SAM 2 could assist in segmenting organs such as the heart, liver, and kidneys, providing real-time assistance during examinations. PET Scans: The integration of SAM 2 in PET imaging could facilitate the segmentation of tumors and other metabolic abnormalities, enhancing the accuracy of oncological assessments. Chest X-rays: SAM 2 could be utilized for segmenting lung structures, nodules, and other thoracic abnormalities in chest X-rays, aiding in the diagnosis of conditions like pneumonia, tuberculosis, and lung cancer. Vascular Imaging: In angiography, SAM 2 could help segment blood vessels and assess vascular diseases, improving the evaluation of conditions such as atherosclerosis or aneurysms. Anatomical Structures: Beyond organs, SAM 2 can be beneficial for segmenting anatomical structures such as bones, ligaments, and cartilage in musculoskeletal imaging, which is crucial for diagnosing injuries and degenerative diseases.

What are the potential clinical applications and implications of using a general-purpose segmentation model like SAM 2 in radiological practice, and how can it be integrated with existing workflows?

The integration of a general-purpose segmentation model like SAM 2 into radiological practice presents numerous clinical applications and implications: Efficiency in Workflow: SAM 2 can significantly reduce the time radiologists spend on manual segmentation, allowing them to focus on interpretation and diagnosis. By automating the segmentation process, the model can streamline workflows, leading to faster report generation and improved patient care. Enhanced Diagnostic Accuracy: With its zero-shot capabilities, SAM 2 can assist in identifying and delineating structures that may be challenging to segment manually, thereby enhancing diagnostic accuracy. This is particularly beneficial in complex cases where anatomical variations exist. Training and Education: SAM 2 can serve as a valuable educational tool for radiology trainees. By providing automated segmentations, it can help trainees learn to identify anatomical structures and understand their relationships, fostering a deeper understanding of imaging. Integration with PACS Systems: To effectively incorporate SAM 2 into existing workflows, it can be integrated with Picture Archiving and Communication Systems (PACS). This integration would allow radiologists to access segmentation results directly within their imaging software, facilitating seamless use during image interpretation. Decision Support Systems: SAM 2 can be part of a broader decision support system, providing radiologists with automated insights and recommendations based on segmented images. This could enhance clinical decision-making, particularly in complex cases requiring multidisciplinary input. Research and Development: The use of SAM 2 can accelerate research in medical imaging by providing a robust tool for segmenting large datasets. This can facilitate studies on disease progression, treatment response, and the development of new imaging biomarkers. Patient-Centric Care: By improving the speed and accuracy of imaging analysis, SAM 2 can contribute to more timely diagnoses and treatment plans, ultimately enhancing patient outcomes and satisfaction. In conclusion, the integration of SAM 2 into radiological practice holds the potential to transform workflows, improve diagnostic accuracy, and enhance educational opportunities, making it a valuable asset in modern medical imaging.
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