13 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
Artificial Control of Gene Silencing Activity Based on siRNA Conjugation with Polymeric Molecule Having CoilâGlobule Transition Behavior
A new
strategy for controlling gene silencing activity of siRNA
in the cell was developed in the present study. siRNA was linearly
conjugated with PNIPAAm, where coilâglobule transition of the
conjugated PNIPAAm allows thermoresponsive exposure of the vicinal
siRNA molecule; a coil form of PNIPAAm (<i>T</i> < LCST)
inhibits siRNA interaction with gene silencing-related proteins due
to the steric hindrance effect, while a globule form of PNIPAAm (<i>T</i> > LCST) allows a ready access of siRNA to gene silencing
pathway. As a result, at <i>T</i> > LCST, PNIPAAm-siRNA
elicited effective association of siRNA with a gene silencing-related
protein of Ago2, while siRNA recruitment into the gene silencing pathway
was significantly suppressed at <i>T</i> < LCST. Ultimately,
gene silencing efficacy of PNIPAAm-siRNA was close to unconjugated
siRNA at <i>T</i> > LCST (âŒ80%), while it was
dramatically
decreased to âŒ20% at <i>T</i> < LCST, suggesting
that coilâglobule transition of the conjugated polymer can
control the bioactivity of the vicinal siRNA molecule
Modulated Protonation of Side Chain Aminoethylene Repeats in NâSubstituted Polyaspartamides Promotes mRNA Transfection
Fine-tuning of chemical
structures of polycation-based carriers
(polyplexes) is an attractive strategy for safe and efficient mRNA
transfaction. Here, mRNA polyplexes comprising N-substituted polyaspartamides
with varied numbers of side chain aminoethylene repeats were constructed,
and their transfection ability against human hepatoma cells was examined.
Transfection efficacy clearly correlated with the number of aminoethylene
repeats: polyplexes with odd number repeats (PA-Os) produced sustained
increases in mRNA expression compared with those with even number
repeats (PA-Es). This predominant efficacy of PA-Os over PA-Es was
contradictory to our previous findings for pDNA polyplexes prepared
from the same N-substituted polyaspartamides, that is, PA-Es revealed
superior transfection efficacy of pDNA than PA-Os. Intracellular FRET
analysis using flow cytometry and polyplex tracking under confocal
laser scanning microscopy revealed that overall transfection efficacy
was determined through the balance between endosomal escaping capability
and stability of translocated mRNA in cytoplasm. PA-Es efficiently
transported mRNA into the cytoplasm. However, their poor cytoplasmic
stability led to facile degradation of mRNA, resulting in a less durable
pattern of transfection. Alternatively, PA-Os with limited capability
of endosomal escape eventually protect mRNA in the cytoplasm to induce
sustainable mRNA expression. Higher cytoplasmic stability of pDNA
compared to mRNA may shift the limiting step in transfection from
cytoplasmic stability to endosomal escape capacity, thereby giving
an opposite oddâeven effect in transfection efficacy. Endosomal
escaping capability and nuclease stability of polyplexes are correlated
with the modulated protonation behavior in aminoethylene repeats responding
to pH, appealing the substantial importance of chemistry to design
polycation structures for promoted mRNA transfection
Polyion Complex Vesicles for Photoinduced Intracellular Delivery of Amphiphilic Photosensitizer
Polymer vesicles
formed by a pair of oppositely charged polyÂ(ethylene
glycol) (PEG)-based block aniomer and homocatiomer, termed âPICsomesâ,
have tunable size, and are characterized by unique semipermeable property
due to the flexible and tunable hydrophilicity of polyion complex
(PIC) membranes. The PICsomes can encapsulate a variety of molecules
in an inner aqueous phase just by a simple vortex mixing of solution,
expecting their utility as nanocontainers of substances with biomedical
interests. Here, we report on a new functionality of the PICsomes:
photoinduced release of photoactive agents for intracellular drug
delivery. A potent photosensitizer, AlÂ(III) phthalocyanine chloride
disulfonic acid (AlPcS2a), was efficiently incorporated into the PICsomes
(11%(w/w)), and its quick release was induced by photoirradiation
possibly due to the photochemical damage of the PIC membranes. The
combination of a high-resolution fluorescent confocal microscopy and
a lysosome membrane-specific staining method revealed that such photoinduced
release of AlPcS2a occurred even in the lysosomes of living cells
after endocytic internalization. Simultaneously, the released AlPcS2a
photochemically affected the integrity of the lysosomal membranes,
leading to the translocation of AlPcS2a and PICsomes themselves to
the cytoplasm. Consequently, the AlPcS2a-encapsulated PICsomes (AlPcS2a-PICsomes)
exhibited appreciably stronger photocytotoxicity compared with free
AlPcS2a alone. Thus, the AlPcS2a-PICsomes have promising feasibility
for the photodynamic therapy or the photoinduced cytoplasmic delivery
of therapeutic molecules
Polyion Complex Vesicles for Photoinduced Intracellular Delivery of Amphiphilic Photosensitizer
Polymer vesicles
formed by a pair of oppositely charged polyÂ(ethylene
glycol) (PEG)-based block aniomer and homocatiomer, termed âPICsomesâ,
have tunable size, and are characterized by unique semipermeable property
due to the flexible and tunable hydrophilicity of polyion complex
(PIC) membranes. The PICsomes can encapsulate a variety of molecules
in an inner aqueous phase just by a simple vortex mixing of solution,
expecting their utility as nanocontainers of substances with biomedical
interests. Here, we report on a new functionality of the PICsomes:
photoinduced release of photoactive agents for intracellular drug
delivery. A potent photosensitizer, AlÂ(III) phthalocyanine chloride
disulfonic acid (AlPcS2a), was efficiently incorporated into the PICsomes
(11%(w/w)), and its quick release was induced by photoirradiation
possibly due to the photochemical damage of the PIC membranes. The
combination of a high-resolution fluorescent confocal microscopy and
a lysosome membrane-specific staining method revealed that such photoinduced
release of AlPcS2a occurred even in the lysosomes of living cells
after endocytic internalization. Simultaneously, the released AlPcS2a
photochemically affected the integrity of the lysosomal membranes,
leading to the translocation of AlPcS2a and PICsomes themselves to
the cytoplasm. Consequently, the AlPcS2a-encapsulated PICsomes (AlPcS2a-PICsomes)
exhibited appreciably stronger photocytotoxicity compared with free
AlPcS2a alone. Thus, the AlPcS2a-PICsomes have promising feasibility
for the photodynamic therapy or the photoinduced cytoplasmic delivery
of therapeutic molecules
Lipid Envelope-Type Nanoparticle Incorporating a Multifunctional Peptide for Systemic siRNA Delivery to the Pulmonary Endothelium
A system that permits the delivery of cargoes to the lung endothelium would be extraordinarily useful in terms of curing a wide variety of lung-related diseases. This study describes the development of a multifunctional envelope-type nanodevice (MEND) that targets the lung endothelium, delivers its encapsulated siRNA to the cytoplasm, and eradicates lung metastasis. The key to the success can be attributed to the presence of a surface-modified GALA peptide that has dual functions: targeting the sialic acid-terminated sugar chains on the pulmonary endothelium and subsequently delivering the encapsulated cargoes to the cytosol <i>via</i> endosomal membrane fusion, analogous to the influenza virus. The active targeting of MENDs without the formation of large aggregates was verified by intravital real-time confocal laser scanning microscopy in living lung tissue. The GALA-modified MEND is a promising carrier that opens a new generation of therapeutic approaches for satisfying unmet medical needs in curing lung diseases
Lipid Envelope-Type Nanoparticle Incorporating a Multifunctional Peptide for Systemic siRNA Delivery to the Pulmonary Endothelium
A system that permits the delivery of cargoes to the lung endothelium would be extraordinarily useful in terms of curing a wide variety of lung-related diseases. This study describes the development of a multifunctional envelope-type nanodevice (MEND) that targets the lung endothelium, delivers its encapsulated siRNA to the cytoplasm, and eradicates lung metastasis. The key to the success can be attributed to the presence of a surface-modified GALA peptide that has dual functions: targeting the sialic acid-terminated sugar chains on the pulmonary endothelium and subsequently delivering the encapsulated cargoes to the cytosol <i>via</i> endosomal membrane fusion, analogous to the influenza virus. The active targeting of MENDs without the formation of large aggregates was verified by intravital real-time confocal laser scanning microscopy in living lung tissue. The GALA-modified MEND is a promising carrier that opens a new generation of therapeutic approaches for satisfying unmet medical needs in curing lung diseases
Lipid Envelope-Type Nanoparticle Incorporating a Multifunctional Peptide for Systemic siRNA Delivery to the Pulmonary Endothelium
A system that permits the delivery of cargoes to the lung endothelium would be extraordinarily useful in terms of curing a wide variety of lung-related diseases. This study describes the development of a multifunctional envelope-type nanodevice (MEND) that targets the lung endothelium, delivers its encapsulated siRNA to the cytoplasm, and eradicates lung metastasis. The key to the success can be attributed to the presence of a surface-modified GALA peptide that has dual functions: targeting the sialic acid-terminated sugar chains on the pulmonary endothelium and subsequently delivering the encapsulated cargoes to the cytosol <i>via</i> endosomal membrane fusion, analogous to the influenza virus. The active targeting of MENDs without the formation of large aggregates was verified by intravital real-time confocal laser scanning microscopy in living lung tissue. The GALA-modified MEND is a promising carrier that opens a new generation of therapeutic approaches for satisfying unmet medical needs in curing lung diseases
Lipid Envelope-Type Nanoparticle Incorporating a Multifunctional Peptide for Systemic siRNA Delivery to the Pulmonary Endothelium
A system that permits the delivery of cargoes to the lung endothelium would be extraordinarily useful in terms of curing a wide variety of lung-related diseases. This study describes the development of a multifunctional envelope-type nanodevice (MEND) that targets the lung endothelium, delivers its encapsulated siRNA to the cytoplasm, and eradicates lung metastasis. The key to the success can be attributed to the presence of a surface-modified GALA peptide that has dual functions: targeting the sialic acid-terminated sugar chains on the pulmonary endothelium and subsequently delivering the encapsulated cargoes to the cytosol <i>via</i> endosomal membrane fusion, analogous to the influenza virus. The active targeting of MENDs without the formation of large aggregates was verified by intravital real-time confocal laser scanning microscopy in living lung tissue. The GALA-modified MEND is a promising carrier that opens a new generation of therapeutic approaches for satisfying unmet medical needs in curing lung diseases
Lipid Envelope-Type Nanoparticle Incorporating a Multifunctional Peptide for Systemic siRNA Delivery to the Pulmonary Endothelium
A system that permits the delivery of cargoes to the lung endothelium would be extraordinarily useful in terms of curing a wide variety of lung-related diseases. This study describes the development of a multifunctional envelope-type nanodevice (MEND) that targets the lung endothelium, delivers its encapsulated siRNA to the cytoplasm, and eradicates lung metastasis. The key to the success can be attributed to the presence of a surface-modified GALA peptide that has dual functions: targeting the sialic acid-terminated sugar chains on the pulmonary endothelium and subsequently delivering the encapsulated cargoes to the cytosol <i>via</i> endosomal membrane fusion, analogous to the influenza virus. The active targeting of MENDs without the formation of large aggregates was verified by intravital real-time confocal laser scanning microscopy in living lung tissue. The GALA-modified MEND is a promising carrier that opens a new generation of therapeutic approaches for satisfying unmet medical needs in curing lung diseases