Several examples
of nanosized therapeutic and imaging agents have
been proposed to date, yet for most of them there is a low chance
of clinical translation due to long-term in vivo retention
and toxicity risks. The realization of nanoagents that can be removed
from the body after use remains thus a great challenge. Here, we demonstrate
that nonequilibrium gold–iron alloys behave as shape-morphing
nanocrystals with the properties of self-degradable multifunctional
nanomedicines. DFT calculations combined with mixing enthalpy-weighted
alloying simulations predict that Au–Fe solid solutions can
exhibit self-degradation in an aqueous environment if the Fe content
exceeds a threshold that depends upon element topology in the nanocrystals.
Exploiting a laser-assisted synthesis route, we experimentally confirm
that nonequilibrium Au–Fe nanoalloys have a 4D behavior, that
is, the ability to change shape, size, and structure over time, becoming
ultrasmall Au-rich nanocrystals. In vivo tests show
the potential of these transformable Au–Fe nanoalloys as efficient
multimodal contrast agents for magnetic resonance imaging and computed
X-ray absorption tomography and further demonstrate their self-degradation
over time, with a significant reduction of long-term accumulation
in the body, when compared to benchmark gold or iron oxide contrast
agents. Hence, Au–Fe alloy nanoparticles exhibiting 4D behavior
can respond to the need for safe and degradable inorganic multifunctional
nanomedicines required in clinical translation.
The combination of multiple functions in a single nanoparticle (NP) represents a key advantage of nanomedicine compared to traditional medical approaches. This is well represented by radiotherapy in which the dose of ionizing radiation should be calibrated on sensitizers biodistribution. Ideally, this is possible when the drug acts both as radiation enhancer and imaging contrast agent. Here, an easy, one‐step, laser‐assisted synthetic procedure is used to generate iron–boron (Fe–B) NPs featuring the set of functions required to assist neutron capture therapy (NCT) with magnetic resonance imaging. The Fe–B NPs exceed by three orders of magnitude the payload of boron isotopes contained in clinical sensitizers. The Fe–B NPs have magnetic properties of interest also for magnetophoretic accumulation in tissues and magnetic hyperthermia to assist drug permeation in tissues. Besides, Fe–B NPs are biocompatible and undergo slow degradation in the lysosomal environment that facilitates in vivo clearance through the liver–spleen–kidneys pathway. Overall, the Fe–B NPs represent a new promising tool for future exploitation in magnetic resonance imaging‐guided boron NCT at higher levels of efficacy and tolerability.
In spite of tremendous advances made in the comprehension of mechanotransduction, implementation of mechanobiology assays remains challenging for the broad community of cell biologists. Hydrogel substrates with tunable stiffness are essential tool in mechanobiology, allowing to investigate the effects of mechanical signals on cell behavior. A bottleneck that slows down the popularization of hydrogel formulations for mechanobiology is the assessment of their stiffness, typically requiring expensive and sophisticated methodologies in the domain of material science. Here we overcome such barriers offering the reader protocols to set-up and interpret two straightforward, low cost and high-throughput tools to measure hydrogel stiffness: static macroindentation and micropipette aspiration. We advanced on how to build up these tools and on the underlying theoretical modeling. Specifically, we validated our tools by comparing them with leading techniques used for measuring hydrogel stiffness (atomic force microscopy, uniaxial compression and rheometric analysis) with consistent results on PAA hydrogels or their modification. In so doing, we also took advantage of YAP/TAZ nuclear localization as biologically validated and sensitive readers of mechanosensing, all in all presenting a suite of biologically and theoretically proven protocols to be implemented in most biological laboratories to approach mechanobiology.
Metastable alloy nanoparticles are investigated for their variety of appealing properties exploitable for photonics, magnetism, catalysis and nanobiotechnology. Noteworthy, nanophases out of thermodynamic equilibrium are featured by a complex “ultrastructure”...
Mechanical signals are pivotal ingredients in how cells perceive and respondto their microenvironments, and to synthetic biomaterials that mimic them. In spite of increasing interest in mechanobiology, probing the effects of physical cues on cell behavior remains challenging for a cell biology laboratory without experience in fabrication of biocompatible materials. Hydrogels are ideal biomaterials recapitulating the physical cues that natural extracellular matrices (ECM) deliver to cells. Here, protocols are streamlined for the synthesis and functionalization of cell adhesive polyacrylamide-based (PAA-OH) and fully-defined polyethyleneglycol-based (PEG-RGD) hydrogels tuned at various rigidities for mechanobiology experiments, from 0.3 to >10 kPa. The mechanosignaling properties of these hydrogels are investigated in distinct cell types by monitoring the activation state of YAP/TAZ. By independently modulating substrate stiffness and adhesiveness, it is found that although ECM stiffness represents an overarching mechanical signal, the density of adhesive sites does impact on cellular mechanosignaling at least at intermediate rigidity values, corresponding to normal and pathological states of living tissues. Using these tools, it is found that YAP/TAZ nuclear accumulation occurs when the projected area of the nucleus surpasses a critical threshold of approximatively 150 μm 2 . This work suggests the existence of distinct checkpoints for cellular mechanosensing.
Mechanobiology
Hydrogels are biomaterials that recapitulate the physical cues that natural extracellular matrices deliver to cells. In article number 2102276 by Giovanna Brusatin and co‐workers, hydrogels' mechanosignaling is monitored by the activation state of YAP/TAZ, revealing distinct checkpoints for cellular mechanosensing: stiffness, adhesiveness and nuclear projected area.
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