20 research outputs found
EDITORIAL
Ligand-mediated drug delivery systems have enormous potential for improving the efficacy of cancer treatment. In particular, Arg-Gly-Asp peptides are promising ligand molecules for targeting α<sub>v</sub>ÎČ<sub>3</sub>/α<sub>v</sub>ÎČ<sub>5</sub> integrins, which are overexpressed in angiogenic sites and tumors, such as intractable human glioblastoma (U87MG). We here achieved highly efficient drug delivery to U87MG tumors by using a platinum anticancer drug-incorporating polymeric micelle (PM) with cyclic Arg-Gly-Asp (cRGD) ligand molecules. Intravital confocal laser scanning microscopy revealed that the cRGD-linked polymeric micelles (cRGD/m) accumulated rapidly and had high permeability from vessels into the tumor parenchyma compared with the PM having nontargeted ligand, âcyclic-Arg-Ala-Aspâ (cRAD). As both cRGD/m- and cRAD-linked polymeric micelles have similar characteristics, including their size, surface charge, and the amount of incorporated drugs, it is likely that the selective and accelerated accumulation of cRGD/m into tumors occurred <i>via</i> an active internalization pathway, possibly transcytosis, thereby producing significant antitumor effects in an orthotopic mouse model of U87MG human glioblastoma
Dual Nanofriction Force Microscopy/Fluorescence Microscopy Imaging Reveals the Enhanced Force Sensitivity of Polydiacetylene by pH and NaCl
Polydiacetylene (PDA) is a popular mechanochromic material
often
used in biosensing. The effect of its headgroupâheadgroup interactions
on thermochromism such as pH or salt concentration dependency has
been extensively studied before; however, their effect on mechanochromism
at the nanoscale is left unstudied. In this work, nanofriction force
microscopy and fluorescence microscopy were combined to study the
effect of pH and ionic strength on the polydiacetylene (PDA) force
sensitivity at the nanoscale. We found that the increase in pH from
5.7 to 8.2 caused an 8-fold enhancement in force sensitivity. The
elevation of NaCl concentration from 10 to 200 mM also made the PDA
5 times more force-sensitive. These results suggest that the PDA force
sensitivity at the nanoscale can be conveniently enhanced by âpre-stimulationâ
with pH or ionic strength
Intracellular Delivery of Charge-Converted Monoclonal Antibodies by Combinatorial Design of Block/Homo Polyion Complex Micelles
Direct
intracellular delivery of antibodies has gained much attention,
although only a few agents have been developed, and none of them has
reached clinical stages. The main obstacles here are the insufficient
characteristics of delivery systems including stability and appropriate
ability for intracellular antibody release. We tailored the structure
of polyion complex (PIC) micelles by loading transiently charge-converted
antibody derivatives for achieving enhanced stability, delivery to
cytosol, and precise antigen recognition inside cells. Citraconic
anhydride was used for the charge conversion of the antibody; the
optimized degree of modification was identified to balance the stability
of PIC micelles in the extracellular compartment and prompt pH-triggered
disintegration after their translocation into the acidic endosomal
compartment of target cells. The use of a mixture of homo- and block-catiomers
in an appropriate ratio to construct PIC micelles substantially enhanced
the endosomal escaping efficacy of the loaded antibody, leading to
improved recognition of intracellular antigens
Bundled Assembly of Helical Nanostructures in Polymeric Micelles Loaded with Platinum Drugs Enhancing Therapeutic Efficiency against Pancreatic Tumor
Supramolecular assemblies of amphiphilic block copolymers having polypeptide segments offer significant advantages for tailoring spatial arrangement based on secondary structures in their optically active backbones. Here, we demonstrated the critical effect of α-helix bundles in cisplatin-conjugated poly(l- (or d-)glutamate) [P(l(or d)Glu)-CDDP] segment on the packaging of poly(ethylene glycol) (PEG)-P(l(or d)Glu)-CDDP block copolymers in the core of polymeric micelles (CDDP/m) and enhanced micelle tolerability to harsh <i>in vivo</i> conditions for accomplishing appreciable antitumor efficacy against intractable pancreatic tumor by systemic injection. CDDP/m prepared from optically inactive PEG-poly(d,l-glutamate) (P(d,lGlu)), gradually disintegrated in the bloodstream, resulting in increased accumulation in liver and spleen and reduced antitumor efficacy. Alternatively, CDDP/m from optically active PEG-P(l(or d)Glu) maintained micelle structure during circulation, and eventually attained selective tumor accumulation while reducing nonspecific distribution to liver and spleen. Circular dichroism and small-angle X-ray scattering measurements indicated regular bundled assembly of α-helices in the core of CDDP/m from PEG-P(l(or d)Glu), which is suggested to stabilize the micelle structure against dilution in physiological condition. CDDP/m suffered corrosion by chlorides in medium, yet the optically active micelles with α-helix bundles kept the micelle structure for prolonged time, with slowly releasing unimers and dimers from the surface of the bundled core in an erosion-like process, as verified by ultracentrifugation analysis. This is in sharp contrast with the abrupt disintegration of CDDP/m from PEG-P(d,lGlu) without secondary structures. The tailored assembly in the core of the polymeric micelles through regular arrangement of constituting segments is key to overcome their undesirable disintegration in bloodstream, thereby achieving efficient delivery of loaded drugs into target tissues
Polyplex Micelles with Phenylboronate/Gluconamide Cross-Linking in the Core Exerting Promoted Gene Transfection through Spatiotemporal Responsivity to Intracellular pH and ATP Concentration
Polyplexes
as gene delivery carriers require integrated functionalities
to modulate intracellular trafficking for efficient gene transfection.
Herein, we developed plasmid DNA (pDNA)-loaded polyplex micelles (PMs)
from polyÂ(ethylene glycol)-based block catiomers derivatized with
4-carboxy-3-fluoroÂphenylÂboronic acid (FPBA) and d-gluconÂamide to form pH- and ATP-responsive cross-linking in
the core. These PMs exhibited robustness in the extracellular milieu
and smooth endosomal escape after cellular uptake, and they facilitated
pDNA decondensation triggered by increased ATP concentration inside
of the cell. Laser confocal microscopic observation revealed that
FPBA installation enhanced the endosomal escapability of the PMs;
presumably, this effect resulted from the facilitated endo-/lysosomal
membrane disruption triggered by the released block catiomers with
hydrophobic FPBA moieties in the side chain from the PM at lower pH
condition of endo-/lysosomes. Furthermore, the profile of intracellular
pDNA decondensation from the PMs was monitored using FoÌrster
resonance energy transfer measurement by flow cytometry; these observations
confirmed that PMs optimized for ATP-responsivity exerted effective
intracellular decondensation of loaded pDNA to attain promoted gene
transfection
Nanomedicines Eradicating Cancer Stem-like Cells <i>in Vivo</i> by pH-Triggered Intracellular Cooperative Action of Loaded Drugs
Nanomedicines
capable of control over drug functions have potential for developing
resilient therapies, even against tumors harboring recalcitrant cancer
stem cells (CSCs). By coordinating drug interactions within the confined
inner compartment of coreâshell nanomedicines, we conceived
multicomponent nanomedicines directed to achieve synchronized and
synergistic drug cooperation within tumor cells as a strategy for
enhancing efficacy, overcoming drug resistance, and eradicating CSCs.
The approach was validated by using polymeric micellar nanomedicines
co-incorporating the pan-kinase inhibitor staurosporine (STS), which
was identified as the most potent CSC inhibitor from a panel of signaling-pathway
inhibitors, and the cytotoxic agent epirubicin (Epi), through rationally
contriving the affinity between the drugs. The micelles released both
drugs simultaneously, triggered by acidic endosomal pH, attaining
concurrent intracellular delivery, with STS working as a companion
for Epi, down-regulating efflux transporters and resistance mechanisms
induced by Epi. These features prompted the nanomedicines to eradicate
orthotopic xenografts of Epi-resistant mesothelioma bearing a CSC
subpopulation
Nanomedicines Eradicating Cancer Stem-like Cells <i>in Vivo</i> by pH-Triggered Intracellular Cooperative Action of Loaded Drugs
Nanomedicines
capable of control over drug functions have potential for developing
resilient therapies, even against tumors harboring recalcitrant cancer
stem cells (CSCs). By coordinating drug interactions within the confined
inner compartment of coreâshell nanomedicines, we conceived
multicomponent nanomedicines directed to achieve synchronized and
synergistic drug cooperation within tumor cells as a strategy for
enhancing efficacy, overcoming drug resistance, and eradicating CSCs.
The approach was validated by using polymeric micellar nanomedicines
co-incorporating the pan-kinase inhibitor staurosporine (STS), which
was identified as the most potent CSC inhibitor from a panel of signaling-pathway
inhibitors, and the cytotoxic agent epirubicin (Epi), through rationally
contriving the affinity between the drugs. The micelles released both
drugs simultaneously, triggered by acidic endosomal pH, attaining
concurrent intracellular delivery, with STS working as a companion
for Epi, down-regulating efflux transporters and resistance mechanisms
induced by Epi. These features prompted the nanomedicines to eradicate
orthotopic xenografts of Epi-resistant mesothelioma bearing a CSC
subpopulation
Nanomedicines Eradicating Cancer Stem-like Cells <i>in Vivo</i> by pH-Triggered Intracellular Cooperative Action of Loaded Drugs
Nanomedicines
capable of control over drug functions have potential for developing
resilient therapies, even against tumors harboring recalcitrant cancer
stem cells (CSCs). By coordinating drug interactions within the confined
inner compartment of coreâshell nanomedicines, we conceived
multicomponent nanomedicines directed to achieve synchronized and
synergistic drug cooperation within tumor cells as a strategy for
enhancing efficacy, overcoming drug resistance, and eradicating CSCs.
The approach was validated by using polymeric micellar nanomedicines
co-incorporating the pan-kinase inhibitor staurosporine (STS), which
was identified as the most potent CSC inhibitor from a panel of signaling-pathway
inhibitors, and the cytotoxic agent epirubicin (Epi), through rationally
contriving the affinity between the drugs. The micelles released both
drugs simultaneously, triggered by acidic endosomal pH, attaining
concurrent intracellular delivery, with STS working as a companion
for Epi, down-regulating efflux transporters and resistance mechanisms
induced by Epi. These features prompted the nanomedicines to eradicate
orthotopic xenografts of Epi-resistant mesothelioma bearing a CSC
subpopulation
Nanomedicines Eradicating Cancer Stem-like Cells <i>in Vivo</i> by pH-Triggered Intracellular Cooperative Action of Loaded Drugs
Nanomedicines
capable of control over drug functions have potential for developing
resilient therapies, even against tumors harboring recalcitrant cancer
stem cells (CSCs). By coordinating drug interactions within the confined
inner compartment of coreâshell nanomedicines, we conceived
multicomponent nanomedicines directed to achieve synchronized and
synergistic drug cooperation within tumor cells as a strategy for
enhancing efficacy, overcoming drug resistance, and eradicating CSCs.
The approach was validated by using polymeric micellar nanomedicines
co-incorporating the pan-kinase inhibitor staurosporine (STS), which
was identified as the most potent CSC inhibitor from a panel of signaling-pathway
inhibitors, and the cytotoxic agent epirubicin (Epi), through rationally
contriving the affinity between the drugs. The micelles released both
drugs simultaneously, triggered by acidic endosomal pH, attaining
concurrent intracellular delivery, with STS working as a companion
for Epi, down-regulating efflux transporters and resistance mechanisms
induced by Epi. These features prompted the nanomedicines to eradicate
orthotopic xenografts of Epi-resistant mesothelioma bearing a CSC
subpopulation
Phenylboronic Acid-Installed Polymeric Micelles for Targeting Sialylated Epitopes in Solid Tumors
Ligand-mediated targeting of nanocarriers
to tumors is an attractive
strategy for increasing the efficiency of chemotherapies. Sialylated
glycans represent a propitious target as they are broadly overexpressed
in tumor cells. Because phenylboronic acid (PBA) can selectively recognize
sialic acid (SA), herein, we developed PBA-installed micellar nanocarriers
incorporating the parent complex of the anticancer drug oxaliplatin,
for targeting sialylated epitopes overexpressed on cancer cells. Following
PBA-installation, the micelles showed high affinity for SA, as confirmed
by fluorescence spectroscopy even at intratumoral pH conditions, i.e.,
pH 6.5, improving their cellular recognition and uptake and enhancing
their <i>in vitro</i> cytotoxicity against B16F10 murine
melanoma cells. <i>In vivo</i>, PBA-installed micelles effectively
reduced the growth rate of both orthotopic and lung metastasis models
of melanoma, suggesting the potential of PBA-installed nanocarriers
for enhanced tumor targetin