Practical Aspects in Optimisation of Radiological Protection in Digital Radiography, Fluoroscopy, and CT


Draft document: Practical Aspects in Optimisation of Radiological Protection in Digital Radiography, Fluoroscopy, and CT
Submitted by John Kotre, University of Cumbria
Commenting as an individual

The section on virtual grids (section 2.3.3, line 785 onward) reflects the commercial position on these software options, but may be unintentionally misleading. A physical grid prevents scattered photons from reaching the image receptor. A virtual grid removes the contrast-reducing low frequency effect of the scatter, but the scattered photons (which contain no imaging information) still reach the receptor carrying with them additional photon noise. Conventionally the noise variance is proportional to the number of photons per unit area recorded. The overall effect of the virtual grid could, then, be to increase the relative quantum noise in the image. Most manufacturer seem to dodge this by combining their virtual grid product with noise reduction i.e. pixel averaging in some form. This latter processing, if it is beneficial, could of course have been added to the conventional gridded image, so the two elements (virtual grid and noise averaging) are separate interventions. To then claim that dose reduction can be achieved from an intervention that is actually adding quantum noise starts to stretch things even further. Certainly the virtual grid can be beneficial in bedside radiography where conventional grids can cause problems, but I feel that the question of optimisation and signal to noise ratio has been sidestepped in manufacturer claims, and more independent research should be undertaken, or at least indpendent references sought.


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