Nanoparticles for death‑induced gene therapy in cancer (Review)

Abstract: Due to the high toxicity and side effects of the use of traditional chemotherapy in cancer, scientists are working on the development of alternative therapeutic technologies. An example of this is the use of death‑induced gene therapy. This therapy consists of the killing of tumor cells via transfection with plasmid DNA (pDNA) that contains a gene which produces a protein that results in the apoptosis of cancerous cells. The cell death is caused by the direct activation of apoptosis (apoptosis‑induced gene the… Show more

“…Nanoparticles with a diameter smaller than 5.5 nm results in a rapid urinary excretion [41]. A disadvantage of larger particles is that they are easily recognized by the macrophages from the immune system, while smaller sizes have a longer circulation time in blood [4]. In fact, agglomeration of coated nanoparticles is demonstrated in DLS results, but SEM images shows well defined nanoparticles in the nanometer scale.…”

“…There was a difference between bare magnetite nanoparticles, which were non-hemolytic at the concentration of 1000 µg/mL, against nanoparticles coated with PEG 3350-Tween 80, which were high hemolytic at the same concentration. This grade of hemotoxicity can be attributed to the positive charges in the coated nanoparticle surface [4].…”

“…There was a difference between bare magnetite nanoparticles, which were non-hemolytic at the concentration of 1000 µg/mL, against nanoparticles coated with PEG 3350-Tween 80, which were high hemolytic at the same concentration. This grade of hemotoxicity can be attributed to the positive charges in the coated nanoparticle surface [4]. Although there are many advantages of the use of PEG 3350 and Tween 80, such as prolonging the circulation time in the body [12], the correct formulations and concentrations in the use of the coating must be measured and tested because excess of coating can cause several problems at the cellular level.…”

“…MNPs must be designed taking into consideration their physical characteristics to be biocompatible with blood elements and not cause cytotoxicity to other tissues. Nanoparticle size should be from 30 to 150 nm because nanoparticles with smaller sizes are immediately discarded from the blood by the kidneys and large sizes hardly cross biological barriers like epithelia [4]. Due to these characteristics, MNPs have a potential to be applied as an alternative in the diagnosis or treatment of several diseases, such as cancer.…”

“…However, a common problem with some polymeric nanoparticles in blood is their high surface charge, which can interact with erythrocytes causing lysis. Polyethylene glycol (PEG) is a nontoxic and non-electrostatic-charge linear polymer [4] that has already been used to coat MNPs. Although there is a common use of PEG in medicine [10,11], the interaction of the PEG molecule with the human body is still being studied [12][13][14].…”

Magnetite Nanoparticles Coated with PEG 3350-Tween 80: In Vitro Characterization Using Primary Cell Cultures

“…Nanoparticles with a diameter smaller than 5.5 nm results in a rapid urinary excretion [41]. A disadvantage of larger particles is that they are easily recognized by the macrophages from the immune system, while smaller sizes have a longer circulation time in blood [4]. In fact, agglomeration of coated nanoparticles is demonstrated in DLS results, but SEM images shows well defined nanoparticles in the nanometer scale.…”

“…There was a difference between bare magnetite nanoparticles, which were non-hemolytic at the concentration of 1000 µg/mL, against nanoparticles coated with PEG 3350-Tween 80, which were high hemolytic at the same concentration. This grade of hemotoxicity can be attributed to the positive charges in the coated nanoparticle surface [4].…”

“…There was a difference between bare magnetite nanoparticles, which were non-hemolytic at the concentration of 1000 µg/mL, against nanoparticles coated with PEG 3350-Tween 80, which were high hemolytic at the same concentration. This grade of hemotoxicity can be attributed to the positive charges in the coated nanoparticle surface [4]. Although there are many advantages of the use of PEG 3350 and Tween 80, such as prolonging the circulation time in the body [12], the correct formulations and concentrations in the use of the coating must be measured and tested because excess of coating can cause several problems at the cellular level.…”

“…MNPs must be designed taking into consideration their physical characteristics to be biocompatible with blood elements and not cause cytotoxicity to other tissues. Nanoparticle size should be from 30 to 150 nm because nanoparticles with smaller sizes are immediately discarded from the blood by the kidneys and large sizes hardly cross biological barriers like epithelia [4]. Due to these characteristics, MNPs have a potential to be applied as an alternative in the diagnosis or treatment of several diseases, such as cancer.…”

“…However, a common problem with some polymeric nanoparticles in blood is their high surface charge, which can interact with erythrocytes causing lysis. Polyethylene glycol (PEG) is a nontoxic and non-electrostatic-charge linear polymer [4] that has already been used to coat MNPs. Although there is a common use of PEG in medicine [10,11], the interaction of the PEG molecule with the human body is still being studied [12][13][14].…”

Magnetite Nanoparticles Coated with PEG 3350-Tween 80: In Vitro Characterization Using Primary Cell Cultures

Biological nanoparticles: Relevance as novel target drug delivery systems and leading chromatographic isolation approaches

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