Abstract
Gene therapy is a promising strategy for treatment of genetically caused diseases. Successful gene delivery requires an efficient carrier to transfer the desired gene into host cells. Recently, mesoporous silica nanoparticles (MSNs) functionalized with 25 kD polyethyleneimine (PEI) were extensively used as gene delivery carriers. However, 25 kD PEI could significantly reduce the safety of the modified MSNs although it is efficient for intracellular delivery of nucleic acids. In addition, limited drug loading remains a challenge for conventional MSNs drug carriers. Hollow mesoporous silica nanoparticles (HMSNs) with high pore volume, tunable pore size, and excellent biocompatibility are attractive alternatives. To make them more efficient, a less toxic 1.8 kD PEI polymer was used to functionalize the HMSNs which have large pore size (~10 nm) and form PEI-HMSNs. Scanning and transmission electron microscopic images showed that HMSNs were spherical in shape and approximately 270 nm in diameter with uniform hollow nanostructures. The maximum loading capacity of green fluorescent protein labeled DNA (GFP-DNA) in PEI-HMSNs was found to be 37.98 mg/g. The loading capacity of PEI-HMSNs was nearly three-fold higher than those of PEI modified solid nanoparticles, indicating that both hollow and large pores contributed to the increase in DNA adsorption. The transfection of GFP-DNA plasmid loaded in PEI-HMSNs was increased two-fold in comparison to that of 25 kD PEI. MTT assays in Lovo cells showed that the cell viability was more than 85% when the concentration of PEI-HMSNs was 120 µg/mL, whereas the cell viability was less than 20% when the 25 kD PEI was used at the same concentration. These results indicated that PEI-HMSNs could be used as a delivery system for nucleic acids due to good biocompatibility, high gene loading capacity, and enhanced gene transfer efficiency.
Highlights
Gene therapy is a promising strategy to cure a wide range of inherited diseases, such as cancer, AIDS, and cardiovascular disease
The scanning electron microscope (SEM) images (Figure 1A,B) and transmission electron microscopy (TEM) images (Figure 1C,D) showed that Hollow mesoporous silica nanoparticles (HMSNs) were nearly spherical in shape (~270 nm in diameter) with uniformly distributed hollow nanostructures
PEI-HMSNs synthesized appears to be promising as a gene delivery platform, because of their larger surface area, higher pore volume, favorable pore size, excellent biocompatibility, and optimal stability
Summary
Gene therapy is a promising strategy to cure a wide range of inherited diseases, such as cancer, AIDS, and cardiovascular disease. Transferring a desired gene into host cell nucleus to treat genetic disorders is a complex process with several restrictions. Successful gene delivery requires an efficient system to deliver genes into specific cells, since naked nucleic acids alone can be rapidly degraded by endogenous nucleases and hard to penetrate through cell membranes [1]. Materials 2017, 10, 731 effective gene delivery vector should be able to load a sufficient amount of genes, provide a protective environment, and effectively penetrate into cells. The preparation for an ideal gene carrier should be easy and the carrier system must be non-toxic. There are two main systems for gene delivery: viral and non-viral vector systems
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