DNA nanostructures have shown excellent prospects in biomedical applications owing to their unique sequence programmability, function designability, and biocompatibility. As a type of unique DNA-inorganic hybrid nanostructures, DNA nanoflowers (DNFs) have attracted considerable attention in the past few years. Precise design of the DNA sequence enables the functions of DNFs to be customized. Specifically, DNFs exhibit high physiological stability and more diverse properties by virtue of the incorporation of inorganic materials, which in turn have been applied in an assortment of biomedical fields. In this review, the design, synthesis, and biomedical applications of programmable DNFs are discussed. First, the background of DNA-based materials and the fundamentals of DNFs are briefly introduced. In the second part, two synthetic methods of DNFs are categorized as the rolling circle amplification and salt aging method, focusing on the formation mechanism of DNFs and differences between the synthetic methods. In the third part, the biomedical applications of DNFs functional materials are summarized, including biosensing, bioimaging, and therapeutics. Finally, the challenges and future opportunities of DNFs are discussed toward more widespread applications.