posted on 2022-07-13, 12:07authored byXiaoshuai Liu, Qing Gao, Shuai Wu, Haifeng Qin, Tiange Zhang, Xianchuang Zheng, Baojun Li
As the first line
of host defense against invading pathogens, neutrophils
have an inherent phagocytosis capability for the elimination of foreign
agents and target loading upon activation, as well as the ability
to transmigrate across blood vessels to the infected tissue, making
them natural candidates to execute various medical tasks in
vivo. However, most of the existing neutrophil-based strategies
rely on their spontaneous chemotactic motion, lacking in effective
activation, rapid migration, and high navigation precision. Here,
we report an optically manipulated neutrophil microcraft in
vivo through the organic integration of endogenous neutrophils
and scanning optical tweezers, functioning as a native biological
material and wireless remote controller, respectively. The neutrophil
microcrafts can be remotely activated by light and then navigated
to the target position along a designated route, followed by the fulfillment
of its task in vivo, such as active intercellular
connection, targeted delivery of nanomedicine, and precise elimination
of cell debris, free from the extra construction or modification of
the native neutrophils. On the basis of the innate immunologic function
of neutrophils and intelligent optical manipulation, the proposed
neutrophil microcraft might provide new insight for the construction
of native medical microdevices for drug delivery and precise treatment
of inflammatory diseases.