# Synthesis with control of DNA nanoflowers towards biomedical applications

**Authors:** Nsolo M. Maarifa, Fahim El-Kassim M. Issimail, Jian He, Xingyi Ma

PMC · DOI: 10.1016/j.mtbio.2025.101886 · 2025-05-21

## TL;DR

DNA nanoflowers are being studied for biomedical uses due to their unique structure and properties, with a focus on how they can be controlled and applied in sensing, imaging, and drug delivery.

## Contribution

This review provides insights into the design, synthesis, and control of DNA nanoflowers for biomedical applications.

## Key findings

- DNFs offer high loading capacity due to their large surface area and roughness.
- DNFs can be used in biosensing, bioimaging, and drug delivery due to their programmability and biocompatibility.
- Challenges remain in controlling DNF structure and interactions with inorganic materials.

## Abstract

Along with the advancement of DNA nanotechnology, DNA nanomaterials have been extensively explored and applied in the biomedical field. DNA nanoflowers (DNFs), characterized as flower-shaped nanocrystals, have attracted notable interest in the biomedical field because of their large surface area relative to volume and significant surface roughness; enabling high loading capacity. Due to their unique sequence programmability, function designability, and biocompatibility, DNFs have increasingly been researched in biosensing, bioimaging and, drug delivery and therapy. Self-assembly of DNFs enables them to maintain DNA stability and provides additional functions of metal ions, which are difficult to obtain through conventional methods. However, some challenges must be addressed, such as the interaction between DNA and inorganic material and controlling the structural features like petals and DNA sequence. In this review, we discussed the designability of DNFs, we subsequently discuss the synthetic methods and controllable parameters. Then, we enumerate recent applications of DNFs in biosensing, bioimaging, drug delivery and therapy and, templating novel functional materials. Finally, we provide conclusion remarks and perspectives for future directions.

Image 1

•DNA nanoflowers are explored as an alternative totemplating functional materials.•Analysis of growth/morphology control strategies, including time, pH, metal ions, and enzyme activity.•Key applications of DNFs, including biosensing, bioimaging, drug delivery, therapeutics, and material templating.•Future perspectives and current challenges in the synthesis, control, and applications of DNFs.

DNA nanoflowers are explored as an alternative totemplating functional materials.

Analysis of growth/morphology control strategies, including time, pH, metal ions, and enzyme activity.

Key applications of DNFs, including biosensing, bioimaging, drug delivery, therapeutics, and material templating.

Future perspectives and current challenges in the synthesis, control, and applications of DNFs.

## Full-text entities

- **Chemicals:** metal (MESH:D008670)

## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12152897/full.md

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Source: https://tomesphere.com/paper/PMC12152897