Novel multi-scan-body cone-beam CT: comparison with photon-counting and energy-integrating CT in an anthropomorphic hand phantom

Abstract

Background

Cone-beam computed tomography (CBCT) can offer advantages over multidetector CT in dose efficiency and economic costs, but musculoskeletal applications were limited in gantry-free systems.

Purpose

To assess the utility of novel multi-scan-body CBCT for osseous imaging, compared to clinically implemented photon-counting-detector (PCCT) and energy-integrating-detector (EICT) CT.

Material and Methods

An anthropomorphic hand wrist phantom underwent gantry-based CBCT (low-dose, regular, enhanced, and best settings), PCCT, and EICT. Quantitative metrics included dose values, noise, and noise power spectrum (NPS). Three radiologists with varying experience levels (10, 6, and 1 years) assessed depiction of cortical and trabecular bone, articular surfaces, intraosseous ganglion cyst, and overall image quality using 5-point Likert scales.

Results

Low-dose and regular CBCT (0.37 and 0.67 mGy) showed the lowest dose values (CTDI_vol), followed by EICT, enhanced and best CBCT, and then PCCT (0.76, 1.08, and 1.61, and 3.56 mGy, respectively). Absolute noise was lowest for PCCT (15.1), followed by best (23.2), regular (25.1), and enhanced (27.4) CBCT. Highest noise was measured for low-dose CBCT (35.1) and EICT (30.1). CBCT showed overall irregular and relatively high NPS, compared to regular and high NPS of EID, whereas PCCT showed a cleaner texture with the lowest NPS. Qualitatively, CBCT (enhanced, best) generally achieved the best scores, while the other scans scored equally well. Average interreader agreement ranged from moderate to near-perfect (k = 0.53–0.87).

Conclusion

Novel multi-scan-body CBCT with variable image quality settings can provide detailed depiction of fine osseous structures, demonstrating comparable or lower doses compared to clinically implemented PCCT and EICT.

Keywords

Cone-beam computed tomography computed tomography diagnostic imaging skeleton hand bones

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References

Posadzy

Desimpel

Vanhoenacker

. Cone beam CT of the musculoskeletal system: clinical applications. Insights Imaging 2018;9:35–45.

Carrino

Ibad

Lin

, et al.

CT In musculoskeletal imaging: still helpful and for what?

Skeletal Radiol 2024;53:1711–1725.

Cetinic

Ullman

Hellman

, et al. Cone-beam CT volumetry: a new method for evaluating osteotomy healing–a clinical evaluation and MDCT comparison. Acta Radiol 2024;65:1375–1381.

Kettunen

Partio

Salo

, et al. Cone-beam computed tomography imaging and three-dimensional analysis of midfoot joints during non-weightbearing and weightbearing in 11 healthy feet. Acta Radiol 2024;65:959–966.

Neubauer

Gerstmair

, et al. Comparison of the radiation dose from cone beam computed tomography and multidetector computed tomography in examinations of the hand. RoFo 2016;188:488–493.

Grunz

J-P

Weng

Gietzen

, et al. Evaluation of ultra-high-resolution cone-beam CT prototype of twin robotic radiography system for cadaveric wrist imaging. Acad Radiol 2021;28:e314–e322.

De Cock

Zanca

Canning

, et al. A comparative study for image quality and radiation dose of a cone beam computed tomography scanner and a multislice computed tomography scanner for paranasal sinus imaging. Eur Radiol 2015;25:1891–1900.

Mason

Iball

Hinchcliffe

, et al. A systematic review comparing the effective radiation dose of musculoskeletal cone beam computed tomography to other diagnostic imaging modalities. Eur J Radiol 2024;177:111558.

Tschauner

Marterer

Nagy

, et al. Experiences with image quality and radiation dose of cone beam computed tomography (CBCT) and multidetector computed tomography (MDCT) in pediatric extremity trauma. Skeletal Radiol 2020;49:1939–1949.

10.

Ibad

de Cesar Netto

Shakoor

, et al. Computed tomography: state-of-the-art advancements in musculoskeletal imaging. Invest Radiol 2023;58:99–110.

11.

De Smet

De Praeter

Verstraete

, et al. Direct comparison of conventional radiography and cone-beam CT in small bone and joint trauma. Skeletal Radiol 2015;44:1111–1117.

12.

Edlund

Skorpil

Lapidus

, et al. Cone-beam CT in diagnosis of scaphoid fractures. Skeletal Radiol 2016;45:197–204.

13.

Klintström

Spångeus

, et al. Trabecular bone microstructure analysis on data from a novel twin robotic X-ray device. Acta Radiol 2023;64:1566–1572.

14.

Kaatsch

Fulisch

Dillinger

, et al. Ultra-low-dose photon-counting CT of paranasal sinus: an in vivo comparison of radiation dose and image quality to cone-beam CT. Dentomaxillofac Radiol 2024;53:103–108.

15.

Grunz

J-P

Huflage

Heidenreich

, et al. Image quality assessment for clinical cadmium telluride-based photon-counting computed tomography detector in cadaveric wrist imaging. Invest Radiol 2021;56:785–790.

16.

Grunz

J-P

Huflage

Photon-counting computed tomography: experience in musculoskeletal imaging. Korean J Radiol 2024;25:662.

17.

Faccioli

Santi

Foti

, et al. Cost-effectiveness of introducing cone-beam computed tomography (CBCT) in the management of complex phalangeal fractures: economic simulation. Musculoskelet Surg 2022; 106: 169–177.

18.

Huang

Chang

Thomas

, et al. Using cone-beam CT as a low-dose 3D imaging technique for the extremities: initial experience in 50 subjects. Skeletal Radiol 2015;44:797–809.

19.

Grunz

J-P

Jordan

Schmitt

, et al. Gantry-free high-resolution cone-beam CT: efficacy for distal radius and scaphoid fracture detection and characterization. Acad Radiol 2023;30:1358–1366.

20.

Jaroma

Suomalainen

J-S

Niemitukia

, et al. Imaging of symptomatic total knee arthroplasty with cone beam computed tomography. Acta Radiol 2018;59:1500–1507.

21.

Wellenberg

Dobbe

Erkkilä

, et al. Marker-less assessment of the geometric error of fused cone-beam computed tomography images of the foot constructed using stitching software. Acta Radiol 2021;62:1341–1348.

22.

Yang

T-W

Lin

Y-Y

Hsu

S-C

, et al. Diagnostic performance of cone-beam computed tomography for scaphoid fractures: a systematic review and diagnostic meta-analysis. Sci Rep 2021;11:2587.

23.

Jacques

Morel

Dartus

, et al. Impact of introducing extremity cone-beam CT in an emergency radiology department: a population-based study. Orthop Traumatol Surg Res 2021;107:102834.

24.

Farracho

Moutinot

Neroladaki

, et al. Determining diagnosis of scaphoid healing: comparison of cone beam CT and X-ray after six weeks of immobilization. Eur J Radiol Open 2020;7:100251.

25.

Virtanen

Gommers

Oliphant

, et al. Scipy 1.0: fundamental algorithms for scientific computing in Python. Nat Methods 2020;17:261–272.

26.

Landis

The measurement of observer agreement for categorical data. Biometrics 1977;33:159.