AI Article Synopsis
- Plasma is the fourth state of matter, consisting of an ionized gaseous mix, and has applications in biology and medicine, particularly through low-temperature plasma (LTP) which can be used at body temperature.
- LTP interacts with water and produces plasma-activated lactate (PAL), which contains reactive molecules like HO and NO, showing potential for creating oxidative stress in cancer cells.
- Studies indicate that LTP and PAL can selectively damage cancer cells more than non-cancerous ones, potentially serving as an additional cancer treatment alongside existing therapies, with the mode of cell death varying by cancer type.
Article Abstract
Plasma is the fourth physical state of matter, characterized by an ionized gaseous mixture, after solid, liquid, and gas phases, and contains a wide array of components such as ions, electrons, radicals, and ultraviolet ray. Whereas the sun and thunder are typical natural plasma, recent progress in the electronics enabled the generation of body-temperature plasma, designated as low-temperature plasma (LTP) or non-thermal plasma since the 1990s. LTP has attracted the attention of researchers for possible biological and medical applications. All the living species on earth utilize water as essential media for solvents and molecular transport. Thus, biological application of LTP naturally intervenes water whether LTP is exposed directly or indirectly, where plasma-activated lactate (PAL) is a standard, containing HO, NO and other identified molecules. Electron spin resonance and immunohistochemical studies demonstrated that LTP exposure is a handy method to load local oxidative stress. Cancer cells are characterized by persistent self-replication and high cytosolic catalytic Fe(II). Therefore, both direct exposure of LTP and PAL can provide higher damage to cancer cells in comparison to non-tumorous cells, which has been demonstrated in a variety of cancer types. The cell death mode is either apoptosis or ferroptosis, depending on the cancer-type. Thus, LTP and PAL are expected to work as an additional cancer therapy to the established guideline protocols, especially for use in somatic cavities or surgical margins.
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| http://dx.doi.org/10.1080/10715762.2023.2190860 | DOI Listing |
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