Statistically Adaptive Filtering for Low Signal Correction in X-ray Computed Tomography

TL;DR

This paper introduces a statistically adaptive filtering method for low signal correction in low-dose X-ray CT imaging, reducing artifacts while preserving anatomical details by using local statistics for adaptive filtering.

Contribution

The paper presents a novel adaptive filtering technique that combines local statistical analysis with bilateral filtering to improve low signal correction in CT images.

Findings

Reduced low frequency bias and streak artifacts.

Improved modulation transfer function and noise power spectrum.

Enhanced detail preservation in low signal regions.

Abstract

Low x-ray dose is desirable in x-ray computed tomographic (CT) imaging due to health concerns. But low dose comes with a cost of low signal artifacts such as streaks and low frequency bias in the reconstruction. As a result, low signal correction is needed to help reduce artifacts while retaining relevant anatomical structures. Low signal can be encountered in cases where sufficient number of photons do not reach the detector to have confidence in the recorded data. % NOTE: SNR is ratio of powers, not std. dev. X-ray photons, assumed to have Poisson distribution, have signal to noise ratio proportional to the dose, with poorer SNR in low signal areas. Electronic noise added by the data acquisition system further reduces the signal quality. In this paper we will demonstrate a technique to combat low signal artifacts through adaptive filtration. It entails statistics-based filtering on the uncorrected data, correcting the lower signal areas more aggressively than the high signal ones. We look at local averages to decide how aggressive the filtering should be, and local standard deviation to decide how much detail preservation to apply. Implementation consists of a pre-correction step i.e. local linear minimum mean-squared error correction, followed by a variance stabilizing transform, and finally adaptive bilateral filtering. The coefficients of the bilateral filter are computed using local statistics. Results show that improvements were made in terms of low frequency bias, streaks, local average and standard deviation, modulation transfer function and noise power spectrum.