Most of the genetic variants that are associated with disease lie within non-coding DNA and are thought to affect gene regulation. This has inspired efforts to identify variants that affect gene expression levels (eQTLs) in a wide range of adult tissues. However, most disease-associated SNPs – though they are located in putatively regulatory regions – have not been found to be eQTLs. One reason for this could be that despite large-scale efforts to map eQTLs in diverse sets of tissues (e.g, GTEx), we still have not yet examined gene regulation in the cell types or states most relevant for disease. Many human tissues and cell types, especially those that are present in early development, are inaccessible due to practical or ethical constraints. Thus, the pace of genetic discovery is fundamentally limited by access to relevant human tissues. The discovery that mature human cells can be transformed into stem cells was an important step toward solving this problem. Induced pluripotent stem cells (iPSCs) provide a renewable source of human tissue that can, in theory, develop into any cell type. In practice, however, it can take years to discover how to produce any single tissue from iPSCs using directed differentiation. At the nexus of stem cell biology and emerging single-cell technologies, there is an opportunity to generate and study many, or even most, human cell types simultaneously, all within a single dish. When grown in the proper conditions, stem cells form spontaneously differentiating organoids known as embryoid bodies (EBs). Cells within EBs differentiate asynchronously into cell types originating from all three germ layers, including pluripotent, intermediate, and mature cell types. By applying single-cell RNA-sequencing (scRNA-seq) to cells within EBs, we can jointly identify dynamic eQTLs across a multitude of cell types, all within a controlled genetic environment. The use of EBs also allows us to observe cellular transitions and regulatory events that are not evident in static cell culture.