# Development and clinical application of a high‐performance medical static computed tomography system

**Authors:** Haining Ding, Yunxiang Li, Zhili Cui, Hongchun Xu

PMC · DOI: 10.1002/acm2.70456 · Journal of Applied Clinical Medical Physics · 2026-01-15

## TL;DR

This paper introduces a new static CT system that improves imaging resolution and eliminates mechanical rotation, offering better diagnostic accuracy for medical scans.

## Contribution

A novel multi-source static CT system with a compressed-sensing reconstruction algorithm and scatter correction for ultra-high-resolution imaging.

## Key findings

- The system achieved a spatial resolution of up to 25 LP/cm@MTF = 10%, the highest in ultra-high-resolution CT imaging.
- Clinical scans showed sharper images of bones, joints, and organs compared to conventional helical CT.
- The system supports precise diagnosis of hip fractures and detailed trabecular bone assessment.

## Abstract

Conventional helical computed tomography (CT) is limited by constraints related to centripetal acceleration, with current rotation speeds nearing the boundaries of engineering feasibility. This study addresses these challenges by proposing a novel CT system design

This study introduces an innovative multi‐source static CT architecture that employs an array‐based, fully integrated x‐ray source paired with a photon stream detector. This system utilizes a complete circular configuration and implements a sequential exposure strategy for each source, thereby eliminating the need for mechanical rotation typical of traditional helical CT. Leveraging the compact integration of the x‐ray source and the fine pixel structure of the detector, we developed a compressed‐sensing iterative reconstruction algorithm based on the bilateral extended Feldkamp‐Davis‐Kress (bixFDK), referred to as “iVision” reconstruction. In addition, a software‐based scatter correction algorithm was implemented. These enhancements collectively improve system performance by significantly boosting spatial resolution.

The multi‐source static CT system met all key regulatory standards for performance indicators, including image noise, uniformity, measurement accuracy, spatial resolution, and density resolution. Notably, the system achieved a spatial resolution of up to 25 LP/cm@MTF = 10%, positioning it at the forefront of ultra‐high‐resolution CT imaging. In volunteer clinical scans, the system consistently delivered sharper images of anatomical regions such as the head, chest, abdomen, and musculoskeletal structures, outperforming conventional helical CT, particularly in detailed visualization of bones and joints, pulmonary tissues, and internal organs.

Based on the above results and analyses, this multi‐source static CT system achieves diagnostic‐quality imaging, aligning with clinical practice standards. It excels in capturing fine anatomical detail and detecting critical pathological features. Its high‐resolution capability also supports precise diagnoses of hip fractures and facilitates detailed trabecular bone assessment, thus improving overall diagnostic accuracy.

## Full-text entities

- **Diseases:** hip fractures (MESH:D006620)

## Full text

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## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12807589/full.md

## References

40 references — full list in the complete paper: https://tomesphere.com/paper/PMC12807589/full.md

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Source: https://tomesphere.com/paper/PMC12807589