Abstract
In the last years, great advances have been made in therapies based in cold atmospheric plasmas (CAP). CAP generate reactive oxygen and nitrogen species (RONS) which can be transferred to liquids. These CAP activated liquids display the same biological efficacy (i.e. on killing cancer cells) as CAP themselves, opening the door for minimally invasive therapies. However, injection of a liquid in the body results in fast diffusion due to extracellular fluids and blood flow. Therefore, the development of efficient vehicles which allow local confinement and delivery of RONS to the diseased site is a fundamental requirement. In this work, we investigate the generation of RONS (H2O2, NO2−, short-lived RONS) in alginate hydrogels by comparing two atmospheric pressure plasma jets: kINPen and a helium needle, at a range of plasma treatment conditions (time, gas flow, distance to the sample). The physic-chemical properties of the hydrogels remain unchanged by the plasma treatment, while the hydrogel shows several-fold larger capacity for generation of RONS than a typical isotonic saline solution. Part of the RONS are quickly released to a receptor media, so special attention has to be put on the design of hydrogels with in-situ crosslinking. Remarkably, the hydrogels show capacity for sustained release of the RONS. The plasma-treated hydrogels remain fully biocompatible (due the fact that the species generated by plasma are previously washed away), indicating that no cytotoxic modifications have occurred on the polymer. Moreover, the RONS generated in alginate solutions showed cytotoxic potential towards bone cancer cells. These results open the door for the use of hydrogel-based biomaterials in CAP-associated therapies.
Highlights
In the last years, great advances have been made in therapies based in cold atmospheric plasmas (CAP)
In this work alginate hydrogels have been shown to be suitable vehicles for reactive oxygen and nitrogen species (RONS) produced by atmospheric pressure plasma jets
It is widely admitted that the CAP-generated RONS are basic anti-cancer factors supressing cancer cell proliferation in in vitro cell cultures[18,19,20,21,22,23] and are essential in the treatment of chronic wounds[24]
Summary
Great advances have been made in therapies based in cold atmospheric plasmas (CAP). The RONS generated in alginate solutions showed cytotoxic potential towards bone cancer cells These results open the door for the use of hydrogel-based biomaterials in CAP-associated therapies. Plasma-activated liquids (PAL) display different biological actions which have been mainly attributed to the generation of RONS such as hydrogen peroxides (H2O2), nitrites (NO2−), peroxynitrites, etc These reactive species are known to be involved in a wide range of intracellular and intercellular processes[5]. We analyse whether there are any chemical modifications in the structure of the alginate and its hydrogel-forming ability In views of their possible therapeutic applications, their biological properties are investigated: biocompatibility of the plasma-treated polymer and cytotoxicity of the RONS generated therein
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