In Situ Single-Cell Surgery and Intracellular Organelle Manipulation Via Thermoplasmonics Combined Optical Trapping.
Xiaoting ZhaoYang ShiTing PanDengyun LuJianyun XiongBaojun LiHongbao XinPublished in: Nano letters (2021)
Microsurgery and biopsies on individual cells in a cellular microenvironment are of great importance to better understand the fundamental cellular processes at subcellular and even single-molecular levels. However, it is still a big challenge for in situ surgery without interfering with neighboring living cells. Here, we report a thermoplasmonics combined optical trapping (TOT) technique for in situ single-cell surgery and intracellular organelle manipulation, without interfering with neighboring cells. A selective single-cell perforation was demonstrated via a localized thermoplasmonic effect, which facilitated further targeted gene delivery. Such a perforation was reversible, and the damaged membrane was capable of being repaired. Remarkably, a targeted extraction and precise manipulation of intracellular organelles were realized via the optical trapping. This TOT technique represents a new way for single-cell microsurgery, gene delivery, and intracellular organelle manipulation, and it provides a new insight for a deeper understanding of cellular processes as well as to reveal underlying causes of diseases associated with organelle malfunctions at a subcellular level.
Keyphrases
- single cell
- rna seq
- minimally invasive
- coronary artery bypass
- induced apoptosis
- living cells
- high throughput
- reactive oxygen species
- cell cycle arrest
- high resolution
- high speed
- surgical site infection
- fluorescent probe
- single molecule
- oxidative stress
- cell death
- gene expression
- coronary artery disease
- dna methylation
- percutaneous coronary intervention
- pi k akt