Androgenetic alopecia (AGA) is highly prevalent in current society but lacks effective treatments. The dysregulation of the hair follicle niche induced by excessive reactive oxygen species (ROS) and insufficient vascularization in the perifollicular microenvironment is the leading cause of AGA. Herein, we designed a ceria nanozyme (CeNZ)-integrated microneedles patch (Ce-MNs) that can alleviate oxidative stress and promote angiogenesis simultaneously to reshape the perifollicular microenvironment for AGA treatment. On the basis of the excellent mechanical strength of Ce-MNs, the encapsulated CeNZs with catalase-and superoxide-mimic activities can be efficiently delivered into skin to scavenge excessive ROS. Moreover, the mechanical stimulation induced by the administration of MNs can remodel the microvasculature in the balding region. Compared with minoxidil, a widely used clinical drug for AGA treatment, Ce-MNs exhibited accelerated hair regeneration in the AGA mouse model at a lower administration frequency without inducing significant skin damage. Consequently, such a safe and perifollicular microenvironment-shaping MNs patch shows great potential for clinical AGA treatment.
Nanomedicine-based
photodynamic therapy (PDT) for melanoma treatment
has attracted great attention. However, the complex design of polymer
nanoparticles and high doses of photosensitizers used in intravenous
injections (for sufficient accumulation of drugs in tumor lesions)
pose a huge challenge to the commercialization and further clinical
application. Herein, we fabricated the carrier-free nanoassemblies
of a chlorin e6 (L-Ce6 NAs)-integrated fast-dissolving microneedles
patch (L-Ce6 MNs) enriching only about 3 μg of Ce6 in the needle
tips via a facile fabrication method. The L-Ce6 MNs
had sufficient mechanical strength to penetrate the skin and facilitated
the transportation of L-Ce6 NAs to a depth of 200–500 μm
under the skin, thereby achieving efficient and accurate drug delivery
to tumor lesions. In a xenograft mouse melanoma model, the L-Ce6 MNs-based
PDT with low dose of Ce6 (0.12 mg/kg) exerted efficient ablation of
the primary lesions in situ through reactive oxygen
species (ROS) generation. More importantly, a significant abscopal
effect was also elicited by activating immunogenic cell death (ICD)
and releasing danger-associated molecular patterns (DAMPs), which
in turn promoted dendritic cells (DCs) maturation and the subsequent
antigen presentation, thereby facilitating the T-cell-mediated immune
response without synergetic immunotherapies. Collectively, our findings
indicate the facile, controllable, and fast-dissolving microneedles
patch with a low dose of photosensitizers presented great therapeutic
potential for enhanced photoimmunotherapy.
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