Imagine Catching A Comet.
COMETS Are Clusters of Frozen GASES PASSING CLOSE TO The Earth at High Speed, Whose Fate is to gradually evaporate unit disappearing. Hence, it is not easy to capture one (The Hunter Should be Very Fast…) and it is not possible to observe a comet for very long.
Now Imagine the Comet is as Small as a Few Billionths of Meters and it is made of Elements from the Periodic Table that do not like each Other; Whose Fate is that of Separate in Space and Dissolve in Biological Environmentments or Just in Air. Before this happens, the elements are trapped in what is called a non-Equilibrium alloy nanoparticle.
Sayte this nanoalloy changes over time, it is not enfuk to provide its composition and size at a give time, but one should Know also how it will change in the near future, or how it changed in the near past.
A way to describe this behavior is to say that it is a 4d nanosystem, where the traditional three-dimensional shape evolves Along a 4th dimension that is time.
Why is important to catch this '4d nano-comet'? Because, contrary to real comets, metastable nanoalloys promised to improve current capabilitities in the diagnosis and treat of cancer and other diseases.
Nanomaterials can revolutionize Current MEDICAL PROCESTURES but only a tiny fraction of the thousands of nanomedicines proposed to date are progressing towards clinical applications.
The Limiting Factor is in the 'Nanomedicine Dilemma': Only Those Nanoparticles with sizes of tens of nanometers are efficiently accumulated in target sites without for a large excess of drug dose; whereas ultrasmall nanoparticles below that are cleared from the body in a short time, which minimize the interaction with tissue and immune system.
Ideally, nanomedicines should behave as a 4d matterial, capable of size reduction only after to allow rapid body clearance.
As for comes, The Hunter of 'Nano-Comets' Must Be Very Fast. In a recent article published in acs nano ("4d multimodal nanomedicines made of nonsequilibrium au-fe alloy nanoparticles"), the nanoalloys were achieved by a Quick Process Running in Non-Equilibrium Conditions, Called 'laser ablation in liquid' (LAL).
Lal proven to be an efficient and versatile synthesis technique for freezing elements in non-equilibrium structures, produced free of chemical contaminants and with an environmentally friendly procedure. LAL ALSO HAS The Advantage of A Self-Running Set-Up that can be controlled remotaly, for instance with a smartphone or a tablet.
This Study Evidenced the Main Parameters being to Catch Non-Equilibrium Nanoalloys With Appealing Features for A 4D Nanomedicine, Such As Being Composed of Biocompatible Au and Fe Elements Only.
Then, the 4d behavior of the nanoalloys was monitored over time in conditions of lift for biomedical applications, and the best class of nanoparticles for the realization of 4d nanomedicines was identified in alloys with Equimolar Composition.
Successively, The Authors Verified the Ability of the Selected Nanoalloys to Provide Advantages for Widespread Bioimaging Techniques Like Magnetic Resonance Imaging (MRI) and X-Ray Compuded Tomography (CT) in Animal Models.
IMPORTANTLY, THE NANOALLOYS WERE MONITED OVER A Period of Two Months in Animals, and Their Biodistribution Compared to that of Benchmark Equivalents Like Pure Au Nanoparticles or Iron-Oxide Contrast Agents Approved for Clinical Use.
The Results Showed that the 4D Au-Fe nanomedicines were able to Leave the Organm in a Shorter Time Compared to 'Standard' Nanoparticles, Without Side Effects.
These results open the way to the easy realization of inorganic contrast agents, Drug Delivery Carriers, or sensitizers for radiotherapy that are safe and have limited biopersistence, as required for clinical use.