A preclinical Talbot-Lau prototype for x-ray dark-field imaging of human-sized objects

C Hauke; P Bartl; M Leghissa; L Ritschl; S M Sutter; T Weber; J Zeidler; J Freudenberger; T Mertelmeier; M Radicke; T Michel; G Anton; F G Meinel; A Baehr; S Auweter; D Bondesson; T Gaass; J Dinkel; M Reiser; K Hellbach

doi:10.1002/mp.12889

A preclinical Talbot-Lau prototype for x-ray dark-field imaging of human-sized objects

Med Phys. 2018 Jun;45(6):2565-2571. doi: 10.1002/mp.12889. Epub 2018 Apr 27.

Authors

C Hauke^{1

2}, P Bartl¹, M Leghissa¹, L Ritschl¹, S M Sutter¹, T Weber¹, J Zeidler¹, J Freudenberger¹, T Mertelmeier¹, M Radicke¹, T Michel², G Anton², F G Meinel³, A Baehr⁴, S Auweter⁵, D Bondesson⁵, T Gaass⁵, J Dinkel⁵, M Reiser⁵, K Hellbach⁵

Affiliations

¹ Siemens Healthcare GmbH, 91301, Forchheim, Germany.
² Erlangen Centre for Astroparticle Physics, FAU Erlangen-Nuremberg, 91058, Erlangen, Germany.
³ Department of Diagnostic and Interventional Radiology, University of Rostock Medical Center, 18057, Rostock, Germany.
⁴ Department of Veterinary Science, LMU Munich, 85764, Oberschleissheim, Germany.
⁵ Department of Radiology, University Hospital, LMU Munich, 80336, Munich, Germany.

PMID: 29582440
DOI: 10.1002/mp.12889

Abstract

Purpose: Talbot-Lau x-ray interferometry provides information about the scattering and refractive properties of an object - in addition to the object's attenuation features. Until recently, this method was ineligible for imaging human-sized objects as it is challenging to adapt Talbot-Lau interferometers (TLIs) to the relevant x-ray energy ranges. In this work, we present a preclinical Talbot-Lau prototype capable of imaging human-sized objects with proper image quality at clinically acceptable dose levels.

Methods: The TLI is designed to match a setup of clinical relevance as closely as possible. The system provides a scan range of 120 × 30 cm² by using a scanning beam geometry. Its ultimate load is 100 kg. High aspect ratios and fine grid periods of the gratings ensure a reasonable setup length and clinically relevant image quality. The system is installed in a university hospital and is, therefore, exposed to the external influences of a clinical environment. To demonstrate the system's capabilities, a full-body scan of a euthanized pig was performed. In addition, freshly excised porcine lungs with an extrinsically provoked pneumothorax were mounted into a human thorax phantom and examined with the prototype.

Results: Both examination sequences resulted in clinically relevant image quality - even in the case of a skin entrance air kerma of only 0.3 mGy which is in the range of human thoracic imaging. The presented case of a pneumothorax and a reader study showed that the prototype's dark-field images provide added value for pulmonary diagnosis.

Conclusion: We demonstrated that a dedicated design of a Talbot-Lau interferometer can be applied to medical imaging by constructing a preclinical Talbot-Lau prototype. We experienced that the system is feasible for imaging human-sized objects and the phase-stepping approach is suitable for clinical practice. Hence, we conclude that Talbot-Lau x-ray imaging has potential for clinical use and enhances the diagnostic power of medical x-ray imaging.

Keywords: Talbot-Lau interferometer; radiography; x-ray dark-field imaging; x-ray interferometry.

Publication types

Validation Study

MeSH terms

Animals
Equipment Design
Humans
Interferometry / instrumentation
Interferometry / methods*
Lung / diagnostic imaging
Models, Anatomic
Phantoms, Imaging
Pneumothorax / diagnostic imaging
Radiation Dosage
Radiography / instrumentation
Radiography / methods*
Skin / diagnostic imaging
Swine
Thorax / diagnostic imaging
Whole Body Imaging / instrumentation
Whole Body Imaging / methods*
X-Rays*