Macrophages (Mφs) are characterized by remarkable plasticity, an essential component of chronic inflammation. Thus, an appropriate and timely transition from proinflammatory (M1) to anti‐inflammatory (M2) Mφs during wound healing is vital to promoting resolution of acute inflammation and enhancing tissue repair. Herein, exosomes derived from M2‐Mφs (M2‐Exos), which contain putative key regulators driving Mφ polarization, are used as local microenvironmental cues to induce reprogramming of M1‐Mφs toward M2‐Mφs for effective wound management. As an injectable controlled release depot for exosomes, hydrolytically degradable poly(ethylene glycol) (PEG) hydrogels (Exogels) are designed and employed for encapsulating M2‐Exos to maximize their therapeutic effects in cutaneous wound healing. The degradation time of the hydrogels is adjustable from 6 days or up to 27 days by controlling the crosslinking density and tightness. The localization of M2‐Exos leads to a successful local transition from M1‐Mφs to M2‐Mφs within the lesion for more than 6 days, followed by enhanced therapeutic effects including rapid wound closure and increased healing quality in an animal model for cutaneous wound healing. Collectively, the hydrolytically degradable PEG hydrogel‐based exosome delivery system may serve as a potential tool in regulating local polarization state of Mφs, which is crucial for tissue homeostasis and wound repair.
Noninvasive and precise stem cell tracking after transplantation in living subject is very important to monitor both stem cell destinations and their in vivo fate, which is closely related to their therapeutic efficacy. Herein, we developed bicyclo[6.1.0]nonyne (BCN)-conjugated glycol chitosan nanoparticles (BCN-NPs) as a delivery system of dual-modal stem cell imaging probes. Near-infrared fluorescent (NIRF) dye Cy5.5 was chemically conjugated to the BCN-NPs, and then oleic acid-coated superparamagnetic iron oxide nanoparticles (OA-Fe3O4 NPs) were encapsulated into BCN-NPs, resulting in Cy5.5-labeled and OA-Fe3O4 NP-encapsulated BCN-NPs (BCN-dual-NPs). For bioorthogonal labeling of human adipose-derived mesenchymal stem cells (hMSCs), first, hMSCs were treated with tetra-acetylated N-azidoacetyl-d-mannosamine (Ac4ManNAz) for generating azide (−N3) groups onto their surface via metabolic glycoengineering. Second, azide groups on the cell surface were successfully chemically labeled with BCN-dual-NPs via bioorthogonal click chemistry in vitro. This bioorthogonal labeling of hMSCs could greatly increase the cell labeling efficiency, safety, and imaging sensitivity, compared to only nanoparticle-derived labeling technology. The dual-modal imaging-guided precise tracking of bioorthogonally labeled hMSCs was tested in the photothrombotic stroke mouse model via intraparenchymal injection. Finally, BCN-dual-NPs-labeled hMSCs could be effectively tracked by their migration from the implanted site to the brain stroke lesion using NIRF/T 2-weighted magnetic resonance (MR) dual-modal imaging for 14 days. Our observation would provide a potential application of bioorthogonally labeled stem cell imaging in regenerative medicine by providing safety and high labeling efficiency in vitro and in vivo.
Exosomes are cellular components with promising uses in cancer diagnostics and therapeutics, and their imaging and tracking are essential to study their biological properties. Herein, we report on an in situ one-step fluorescence labeling strategy for exosomes via bioorthogonal click chemistry. First, exosome donor cancer cells were treated with tetraacetylated N-azidoacetyl-d-mannosamine (Ac4ManNAz) to generate unnatural azide groups (−N3) on their surface via metabolic glycoengineering. Then, the azide groups were labeled with near-infrared fluorescent dye-conjugated dibenzylcyclooctyne (DBCO-Cy5) via bioorthogonal click chemistry. After 2 days of incubation, the DBCO-Cy5-labeled exosomes (Cy5-Exo) were successfully secreted from the donor cancer cells and were isolated via classical ultracentrifugation, providing a high-yield of fluorescent dye-labeled exosomes. This in situ one-step bioorthogonal click chemistry offers improved labeling efficiency, biocompatibility, and imaging sensitivy compared to standard exosomes (ST-Exo), purified with classical ultracentrifugation or carbocyanine lipophilic dye (DiD)-labeled exosomes (DiD-Exo) in vitro. In particular, the Cy5-Exo were successfully taken up by A549 cells in a time-dependent manner, and they could escape from lysosome confinement, showing their possible use as a delivery carrier of therapeutic drugs or imaging agents. Finally, intraveneously injected Cy5-Exo were noninvasively tracked and imaged via near-infrared fluorescence (NIRF) imaging in tumor-bearing mice. This new fluorescence labeling strategy for natural exosomes may be useful to provide better understanding of their theranostic effects in many biomedical applications.
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