NANOMEDICINE A.A. 2011-2012. An expanding field, Nanomedicine represents an active field of pharmacological research. However, only a small part of nanodrugs.
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NANOMEDICINENANOMEDICINE
A.A. 2011-2012A.A. 2011-2012
An expanding field,
Nanomedicine represents an active field of
pharmacological research.
However, only a small part of nanodrugs and
nanosized devices potentially usefull for the
exploitation in humans have reached the
clinical experimental phase; even fewer are
approved for use in humans.
Nanosized drugs: main properties.
1. Enhanced Permeabilization and Retention (EPR): accumulation in newly forming endothelia
2. Compartimentalization3. Accessibility to districts with blood barriers
(e.g. brain, posterior pole of the eye)
Main results: changes of the bioavailability and of other pharmacological paramenters in comparison with traditional formulations.
The STHEALTH technology.
The EPR effect, while useful for targeting newly vascularized tissues, can be indesirable if it reduces the half life of the nanodrug.En efficient way to reduce this effect is to cover the nanoparticle with a layer of PEG.This procedure is a technology customized under the name STHEALTH®.
STHEALTH nAu
Uncoated nAu (on the left ) enters the phagocyte in very larger amount than PEG-coated nAu (on the right) of similar size and shape.
Surface functionalization
In addition to the STHEALTH, nanodrugs can be functionalized through the addition of layers of antibodies directed to protein specifically expressed by the targed tissue, or of the substrate for specificaly bounding receptors.Modular molecules are designed, able to disassemble gradually when approaching their target.
Clinical advantages
The main clinical advantages of therapy with nanosized and functionalized drugs are:
• Higher concentrations of the active drug at the site of action
• Possible targeting to desired cellular type to be targeted, or even to selected cellular districts
• Lower general toxicity of the active principle
Major toxicity hazard
• The toxicity of the nanomaterial itself is mostly unknown, it is not possible to infer it from the properties of the equivalent bulk material
• Adequate models for toxicity studies “in vivo” and in humans are mostly lacking
• The dissolvation of elements from complex nanomaterials is at the present unpredictable, especially in complex environment like the fluids of the body.
Nanoparticles can enter the cell.
Co3O4 nanoparticles form small aggregates inside the cell.
Courtesy Lab. Cell Biol. University of Insubria
Nanoparticles can be toxic for the cells
Courtesy Lab. Cell Biol. University of Insubria
Main fields of exploitation in human clinics
• Cancer, especially if advanced, refractory or affecting poorly accessible tissues
• Drug-resistant, life-threatening bacterial and parasite infections
• Diseases affecting the posterior pole of the eye and the Central Nervous System (CNS)
Carriers for nanodrugs: lipid-based.From the left: liposomes and STHEALTH
liposomes (embedded with PEG), liquid and
solid lipid nanoparticles (LLN, SLN).
Cattaneo et al. 2010. J. Appl. Toxicol. 30: 730–744. DOI 10.1002/jat.1609
A multilamellar liposome in equilibrium with planar membrane.
This technology was conceived to get a system similar to the cell membrane bilayer, possibly integrated with it when used to carry chemicals inside the cell. Updated, customized technologies use both multi- and monolayered liposomes.
(Pidgeon & McNeely, 1987, Biochemistry 26:17-29, modified)
Liposomes
Sucrose
TEM image of doxorubicine, an antineoplastic agent, embeddedin bilayered liposomes (Doxil).
(Gabizion et al., Eur. J. Pharm. Sci, 45: 388–398)
Pharmacokinetics
Liposomal doxorubicin is partially protected from rapid renal clearance after three cycles (B), therefore the plasma levels increase (A).Data are taken in cancer experimentally induced in mice.
(Gabizion et al., Eur. J. Pharm. Sci, 45: 388–398)
Effect on experimental cancer
Doxorubicin in tissues appears red-orange.
Soluble doxorubicin (A) does not accumulate in tumoral nodules.
The nanoformulation of the drug, embedded in bilayered liposomes (B), clearly accumulates.
(Gabizon et al., Eur. J. Pharm. Sci, 45: 388–398)
1. Nanogold, nAu2. Nanosilver, nAg 3. UltraSmall Paramagnetic Iron Oxides
(USPIO)
For diagnostics and therapeutics.USPIO greatly enhance the signal of (Magnetic Resonance Imaging (MRI)
Some metallic nanodrugs.
nAu coated with TNF (Aurimune) in oncology
Au nanoparticles aggregates inside the tumoral cells
The Combidex: an USPIO for cancer diagnostics.
Combidex is a customized formulation of dextran-coated USPIO. The pictures show its 3D structure (the iron oxide cluster at the center of dextran molecules is in violet-blue) and the aspect of particles at TEM.The particles mean diameter is 21 nm.
Control Contrast: Gd Contrast: Combidex
USPIO in cancer diagnostics.
Enhanced MRI of metastatic cancer in the brain.From the left: without contrasting agents, with Gd as contrast, with USPIO (Combidex).
Functionalized Iron oxide as a targeted carrier for drugs
Boyer et al., NPG Asia Materials , 23–30 (2010) | doi:10.1038/asiamat.2010.6
Size-dependent Magnetic properties of IONPs
doi:10.1038/asiamat.2010.6;doi: 10.1021/ja0422155
A) TEM of differently sized Iron Oxide NanoParticles (IONPs)
B) Size-dependent T2-weighted MR images of IONPs in aqueous solution at 1.5 T
C) As before, color-codedD) Graph of T2 value versus
size of water soluble IONPs.E) Magnetization of water
soluble IONPs measured by a SQUID magnetometer.
Mesoporous silicon, with nanopores, shows
properties useful for:
1. Sustained, localized and prolonged release of drugs
2. Enhanced reconstruction of tissues through cell growth stimulation or promoting accelerated mineralization of bones.
Carriers for nanodrugs: bioactive silicon.
Carriers for nanodrugs: organic compounds.
Those exploited for the use in humans are in
the following categories:
1. Polymers (polylactide, polyglycolide)
2. Dendrimers (polyamidoamides)
3. Albumin nanotubes
2 3
J. Appl. Toxicol. 2010, 30:730-744; wileyonlinelibrary.com/journal/pat
Theranostics and “modular” nanoparticles.
Theranostics: combining diagnosis with therapy.
NPs with high imaging properties and able to kill the cell when activated (es. light sensitive molecules) are coated to prolonge their half-life, conjugated at the surface to be targeted to specific cells (e.g. tumoral) and with molecules improving the uptake into the target cell.Or:NPs able to kill the cells (e.g. radioactive isotopes) are coated and functionalized for targeting, and injected locally in the bloody supply of the tumor.Or:NPs with high imaging properties (e.g. USPIO) are coated and functionalized for targeting and killing the cell, than directed to the target by functionalization or by a directional magnetic field.
NP
Protective coating
Cell permeabilization agentSensor
(e.g. Ab to recognize tumor cell)
An hypothetical modular nanocarrier.
And a scheme of how it works….
Degradation
Signal for imagingDIAGNOSIS
Activation
Cell damage:THERAPY
Binding to the target
A modular nanoparticle for “in situ” cancer treatment
Cai & Chen, 2007, Small, 3: 1840 (modified)
Monoclonal antibodies(ChL6)
PEG
Dextran
Isotope: In111(with chelator, DOTA)
20 nm
Iron oxide
Binding to the target
Ionizing radiation:Cell deathTherapy
Degradation
Internalization of IONPsInternalization of In111
Enhanced signal for NMIDiagnosis
1. Tissues and coating releasing nanometals (e.g. nAg, with antibacteric properties)
2. Creams eluting active, nanosized compounds (nAg for antibacteric gels, nTiO2 for solar creams)
3. Drugs eluting devices (silicon scaffolds for wluting drugs to the the posterior pole of the eye, central venous catheter with nAg).
Other nanosized materials
How to test toxicity?
• “in silico”: nano-QSAR and PSAR (pseudo-structure-activity-relationships)
• “in vitro”: toxicity test on monocellular organisms, tissues and cells
• “in vivo”: toxicity tests on model organisms
• Metabolomics: newer methodology to get contemporary informations on a complete panel of biological parameters
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