Virus-Shaped Mesoporous Silica Nanostars to Improve the Transport of Drugs across the Blood-Brain Barrier.
Alessandra PinnaIeva RagaisyteWilliam MortonStefano Angioletti-UbertiAlizé ProustRocco D'AntuonoChak Hon LukMaximiliano G GutierrezMaddalena CerroneKatalin A WilkinsonAli A MohammedCatriona M McGilveryAlejandro Suárez-BonnetMatthew ZimmermanMartin GengenbacherRobert J WilkinsonAlexandra E PorterPublished in: ACS applied materials & interfaces (2024)
Conditions affecting the brain are the second leading cause of death globally. One of the main challenges for drugs targeting brain diseases is passing the blood-brain barrier (BBB). Here, the effectiveness of mesoporous silica nanostars (MSiNSs) with two different spike lengths to cross an in vitro BBB multicellular model was evaluated and compared to spherical nanoparticles (MSiNP). A modified sol-gel single-micelle epitaxial growth was used to produce MSiNS, which showed no cytotoxicity or immunogenicity at concentrations of up to 1 μg mL -1 in peripheral blood mononuclear and neuronal cells. The nanostar MSiNS effectively penetrated the BBB model after 24 h, and MSiNS-1 with a shorter spike length (9 ± 2 nm) crossed the in vitro BBB model more rapidly than the MSiNS-2 with longer spikes (18 ± 4 nm) or spherical MSiNP at 96 h, which accumulated in the apical and basolateral sides, respectively. Molecular dynamic simulations illustrated an increase in configurational flexibility of the lipid bilayer during contact with the MSiNS, resulting in wrapping, whereas the MSiNP suppressed membrane fluctuations. This work advances an effective brain drug delivery system based on virus-like shaped MSiNS for the treatment of different brain diseases and a mechanism for their interaction with lipid bilayers.
Keyphrases
- blood brain barrier
- peripheral blood
- resting state
- cerebral ischemia
- white matter
- functional connectivity
- photodynamic therapy
- induced apoptosis
- systematic review
- molecular dynamics
- oxidative stress
- cell cycle arrest
- drug delivery
- cell proliferation
- molecular dynamics simulations
- single molecule
- cell death
- subarachnoid hemorrhage
- multiple sclerosis
- wound healing
- endoplasmic reticulum stress