Autonomous self-propelled micromachines, taking energy from surrounding environment and converting it to their motion, are on the forefront of the research for smart materials in the recent years. Owing to their self-propulsion mechanism, they have demonstrated to be more efficient drug carriers than passive particles. Here, multifunctional superparamagnetic/catalytic microrobots (PM/Pt microrobots) for cell manipulation, anticancer drug loading, and delivery to breast cancer cells are presented. These PM/Pt microrobots are fabricated from superparamagnetic polymer particles with iron oxide in their interior and an external tosylated surface, which is half-covered by a catalytic platinum (Pt) layer. This result in a triple-functionality-tosyl group-rich polymer layer can bind molecules and biological materials, Pt layer can catalyze decomposition of hydrogen peroxide, providing propulsion to the microrobots and magnetic part allows for manipulation by magnetic field. PM/Pt microrobots are able to move as individual robots and to "team-up" under influence of weak magnetic field by forming chains of the micromachines to perform collective actions, such as capture and transportation of cancer cells. The efficacy of PM/Pt microrobots to perform several tasks without complex surface functionalization steps simplifies the applicability of such multifunctional devices toward diverse biomedical applications.
The threat of a worldwide influenza pandemic has greatly increased over the past decade with the emergence of highly virulent avian influenza strains. The increased frequency of drug-resistant influenza strains against currently available antiviral drugs requires urgent development of new strategies for antiviral therapy, too. The research in the field of therapeutic peptides began to develop extensively in the second half of the 20th century. Since then, the mechanisms of action for several peptides and their antiviral prospect received large attention due to the global threat posed by viruses. Here, we discussed the therapeutic properties of peptides used in influenza treatment. Peptides with antiviral activity against influenza can be divided into three main groups. First, entry blocker peptides such as a Flupep that interact with influenza hemagglutinin, block its binding to host cells and prevent viral fusion. Second, several peptides display virucidal activity, disrupting viral envelopes, e.g., Melittin. Finally, a third set of peptides interacts with the viral polymerase complex and act as viral replication inhibitors such as PB1 derived peptides. Here, we present a review of the current literature describing the antiviral activity, mechanism and future therapeutic potential of these influenza antiviral peptides.
Nano/micromachines with autonomous motion are the frontier of nanotechnology and nanomaterial research. These self‐propelled nano/micromachines convert chemical energy obtained from their surroundings to propulsion. They have shown great potential in diagnostic and therapeutic applications. This work introduces a high‐speed tubular electrically conductive micromachine based on reduced nanographene oxide (n‐rGO) as a platform for drug delivery and platinum (Pt) as the catalytic inner layer. n‐rGO/Pt micromachines are loaded with doxorubicin (DOX) by a simple physical adsorption with a very high loading efficiency, displaying single‐ or multistrand wrapping of DOX monomers on the micromachine cylinders. More importantly, it is found that electron injection into DOX@n‐rGO/Pt micromachines via electrochemistry leads to expulsion of DOX from micromachines in motion within only a few seconds. An in vitro study confirms this efficient release mechanism in the presence of cancerous cells. The unique properties of the n‐rGO/Pt micromotor enable the effective management of DOX release at the tumor site and thus enhances the therapeutic efficiency and reduces the side toxicity toward the healthy tissue. These micromachine drug carriers combine the high loading capacity of conventional carbon‐based drug carriers with a fast and efficient electrochemical drug‐release mechanism.
Self-propelled
microrobots are seen as the next step of micro-
and nanotechnology. The biomedical and environmental applications
of these robots in the real world need their motion in the confined
environments, such as in veins or spaces between the grains of soil.
Here, self-propelled trilayer microrobots have been prepared using
electrodeposition techniques, coupling unique properties of green
bismuth (Bi) with a layered crystal structure, magnetic nickel (Ni),
and a catalytic platinum (Pt) layer. These Bi-based microrobots are
investigated as active self-propelled platforms that can load, transfer,
and release both doxorubicin (DOX), as a widely used anticancer drug,
and arsenic (As) and chromium (Cr), as hazardous heavy metals. The
significantly high loading capability for such variable cargoes is
due to the high surface area provided by the rhombohedral layered
crystal structure of bismuth, as well as the defects introduced through
the oxide layer formed on the surface of bismuth. The drug release
is based on an ultrafast electroreductive mechanism in which the electron
injection into microrobots and consequently into the loaded objects
causes an electrostatic repulsion between them and thus an ultrafast
release of the loaded cargos. Remarkably, we have presented magnetic
control of the Bi-based microrobots inside a microfluidic system equipped
with an electrochemical setup as a proof-of-concept to demonstrate
(i) heavy metals/DOX loading, (ii) a targeted transport system, (iii)
the on-demand release mechanism, and (iv) the recovery of the robots
for further usage.
Guanosine derivatives are important for diagnosis of oxidative DNA damage including 8-hydroxy-2'-deoxyguanosine (8-OHdG) as one of the most abundant products of DNA oxidation. This compound is commonly determined in urine, which makes 8-OHdG a good non-invasive marker of oxidation stress. In this study, we optimized and tested the isolation of 8-OHdG from biological matrix by using paramagnetic particles with an antibody-modified surface. 8-OHdG was determined using 1-naphthol generated by alkaline phosphatase conjugated with the secondary antibody. 1-Naphthol was determined by stopped flow injection analysis (SFIA) with electrochemical detector using a glassy carbon working electrode and by stationary electrochemical detection using linear sweep voltammetry. A special modular electrochemical SFIA system which needs only 10 μL of sample including working buffer for one analysis was completely designed and successfully verified. The recoveries in different matrices and analyte concentration were estimated. Detection limit (3 S/N) was estimated as 5 pg/mL of 8-OHdG. This method promises to be very easily modified to microfluidic systems as "lab on valve". The optimized method had sufficient selectivity and thus could be used for determination of 8-OHDG in human urine and therefore for estimation of oxidative DNA damage as a result of oxidation stress in prostate cancer patients.
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