In 2007, Segal et al. showed that careful characterization of the appearances of liver lesions in contrast-enhanced CT scans could be used to infer their molecular properties [11]. Similarly, in 2008, Brown et al. showed that quantitative analysis of gray-scale image texture on magnetic resonance (MR) scans of patients with oligodendroglioma could be used to predict their genetic signatures, specifically, co-deletion of chromosomes 1p and 19q [12]. These and other early examples showed that not only could appearances on non-invasive imaging be quantified, but that these data could illuminate fundamental molecular properties of cancers [13,14]. Early examples used “semantic features,” i.e., categorizations of human observations using a controlled vocabulary [15,16,17], and these have expanded to use “computational features” that are direct mathematical summarization of image regions. Together, semantic and computational feature classes are the basis of the new field of “radiomics” [18,19], defined as the “high-throughput extraction of quantitative features that result in the conversion of images into mineable data” [20,21] and feature prominently in what is today called “quantitative imaging” [22,23,24]. This chapter describes the radiomics workflow, including its strengths and its challenges, and highlights the integration of radiomics with clinical data and the molecular characterization of tissue, also known as “radiogenomics” [13,25,26,27,28,29,30,31], for the building of predictive models. It focuses on “conventional radiomics” (i.e., machine computation of human-engineered image features) [32]. The more recent developments in radiomics, including the use of artificial intelligence, or “deep learning,” to automatically learn informative image features for linking to clinical data (e.g., expression, outcomes) from a set of suitably labeled image and clinical data [33] will be discussed in detail in the final chapter of this book. Most examples in the literature focus on cancer, i.e., imaging and analysis of medical images of tumors. However, radiomics may be used to characterize any tissue, and so in the following we refer to the regions of imaging data to be analyzed as volumes of interest (VOIs).