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03.08.2016 | Original Article

Image quality and dose differences caused by vendor-specific image processing of neonatal radiographs

verfasst von: William F. Sensakovic, M. Cody O’Dell, Haley Letter, Nathan Kohler, Baiywo Rop, Jane Cook, Gregory Logsdon, Laura Varich

Erschienen in: Pediatric Radiology | Ausgabe 11/2016

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Abstract

Background

Image processing plays an important role in optimizing image quality and radiation dose in projection radiography. Unfortunately commercial algorithms are black boxes that are often left at or near vendor default settings rather than being optimized.

Objective

We hypothesize that different commercial image-processing systems, when left at or near default settings, create significant differences in image quality. We further hypothesize that image-quality differences can be exploited to produce images of equivalent quality but lower radiation dose.

Materials and methods

We used a portable radiography system to acquire images on a neonatal chest phantom and recorded the entrance surface air kerma (ESAK). We applied two image-processing systems (Optima XR220amx, by GE Healthcare, Waukesha, WI; and MUSICA² by Agfa HealthCare, Mortsel, Belgium) to the images. Seven observers (attending pediatric radiologists and radiology residents) independently assessed image quality using two methods: rating and matching. Image-quality ratings were independently assessed by each observer on a 10-point scale. Matching consisted of each observer matching GE-processed images and Agfa-processed images with equivalent image quality. A total of 210 rating tasks and 42 matching tasks were performed and effective dose was estimated.

Results

Median Agfa-processed image-quality ratings were higher than GE-processed ratings. Non-diagnostic ratings were seen over a wider range of doses for GE-processed images than for Agfa-processed images. During matching tasks, observers matched image quality between GE-processed images and Agfa-processed images acquired at a lower effective dose (11 ± 9 μSv; P < 0.0001).

Conclusion

Image-processing methods significantly impact perceived image quality. These image-quality differences can be exploited to alter protocols and produce images of equivalent image quality but lower doses. Those purchasing projection radiography systems or third-party image-processing software should be aware that image processing can significantly impact image quality when settings are left near default values.

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Schauer DA, Linton OW (2009) NCRP Report No. 160, Ionizing radiation exposure of the population of the United States, medical exposure – are we doing less with more, and is there a role for health physicists? Health Phys 97:1–5CrossRefPubMed

Dorfman AL, Fazel R, Einstein AJ et al (2011) Use of medical imaging procedures with ionizing radiation in children: a population-based study. Arch Pediatr Adolesc Med 165:458–464CrossRefPubMedPubMedCentral

Donadieu J, Zeghnoun A, Roudier C et al (2006) Cumulative effective doses delivered by radiographs to preterm infants in a neonatal intensive care unit. Pediatrics 117:882–888CrossRefPubMed

Don S, Macdougall R, Strauss K et al (2013) Image Gently campaign back to basics initiative: ten steps to help manage radiation dose in pediatric digital radiography. AJR Am J Roentgenol 200:W431–436CrossRefPubMed

Willis CE, Slovis TL (2005) The ALARA concept in pediatric CR and DR: dose reduction in pediatric radiographic exams--a white paper conference. AJR Am J Roentgenol 184:373–374CrossRefPubMed

GE Healthcare (2010) Optima XR220amx X-ray system operator manual

Schaetzing R (2007) Agfa’s MUSICA² Taking image processing to the next level. http://www.agfahealthcare.com/usa/en/main/products_services/product-info/white_papers/musica2.jsp. Accessed 20 May 2016

Gwet KL (2008) Variance estimation of nominal-scale inter-rater reliability with random selection of raters. Psychometrika 73:407–430CrossRef

Kramer R, Cavalcanti A, Cassola V et al (2012) CALDose_X online: real time Monte Carlo calculations for patient dosimetry in X-ray diagnosis. 13^th International Congress of the International Radiation Protection Association (IRPA), Glasgow

10.

Box GEP, Hunter JS, Hunter WG (2005) Statistics for experimenters: design, innovation, and discovery. Wiley-Interscience, Hoboken

11.

Cohen J, Cohen J (2003) Applied multiple regression/correlation analysis for the behavioral sciences. L. Erlbaum Associates, Mahwah

12.

IBM (2013) IBM SPSS statistics for windows. IBM Corp, Armonk

13.

Lowry R VassarStats: Website for statistical computation. Vassar College Website. http://vassarstats.net/. Accessed 9 May 2016

14.

Busch HP, Lehmann KJ, Georgi M (1993) New analog and digital imaging techniques for chest diagnosis–principles–clinical value–economics. Aktuelle Radiol 3:6–13PubMed

15.

van Heesewijk HP, van der Graaf Y, de Valois JC et al (1996) Effects of dose reduction on digital chest imaging using a selenium detector: a study of detecting simulated diffuse interstitial pulmonary disease. AJR Am J Roentgenol 167:403–408CrossRefPubMed

16.

Schaefer CM, Greene RE, Oestmann JW et al (1989) Improved control of image optical density with low-dose digital and conventional radiography in bedside imaging. Radiology 173:713–716CrossRefPubMed

17.

Don S, Whiting BR, Ellinwood JS et al (2007) Neonatal chest computed radiography: image processing and optimal image display. AJR Am J Roentgenol 188:1138–1144

18.

Uffmann M, Schaefer-Prokop C, Neitzel U et al (2004) Skeletal applications for flat-panel versus storage-phospor radiography: effect of exposure on detection of low-contrast details. Radiology 231:506–514

19.

Kroft LJ, Veldkamp WJ, Mertens BJ et al (2005) Comparison of eight different digital chest radiography systems: variation in detection of simulated chest disease. AJR Am J Roentgenol 185:339–346

20.

Armpilia CI, Fife IA, Croasdale PL (2002) Radiation dose quantities and risk in neonates in a special care baby unit. Br J Radiol 75:590–595CrossRefPubMed

21.

Brindhaban A, Eze CU (2006) Estimation of radiation dose during diagnostic X-ray examinations of newborn babies and 1-year-old infants. Med Princ Pract 15:260–265CrossRefPubMed

22.

Lowe A, Finch A, Boniface D et al (1999) Diagnostic image quality of mobile neonatal chest X-rays and the radiation exposure incurred. Br J Radiol 72:55–61CrossRefPubMed

23.

Ma H, Elbakri IA, Reed M (2013) Estimation of organ and effective doses from newborn radiography of the chest and abdomen. Radiat Prot Dosim 156:160–167CrossRef

24.

Singh S, Kalra MK, Hsieh J et al (2010) Abdominal CT: comparison of adaptive statistical iterative and filtered back projection reconstruction techniques. Radiology 257:373–383CrossRefPubMed

Titel: Image quality and dose differences caused by vendor-specific image processing of neonatal radiographs
verfasst von: William F. Sensakovic
M. Cody O’Dell
Haley Letter
Nathan Kohler
Baiywo Rop
Jane Cook
Gregory Logsdon
Laura Varich
Publikationsdatum: 03.08.2016
Verlag: Springer Berlin Heidelberg
Erschienen in: Pediatric Radiology / Ausgabe 11/2016
Print ISSN: 0301-0449
Elektronische ISSN: 1432-1998
DOI: https://doi.org/10.1007/s00247-016-3663-2

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Image quality and dose differences caused by vendor-specific image processing of neonatal radiographs