AI Article Synopsis
- A study examined industrial chitosans for residual heavy metals, revealing many insoluble microparticles in chitosan solutions through optical microscopy and detailed structures in electron microscopy.
- Filtering methods indicated the presence of iron, silicon, aluminum, nitrogen, and sulfur remnants on filters, along with heavy metals like iron, chromium, and nickel in both the filters and chitosan solutions, using advanced analysis techniques like SEM-EDXS and ICP-MS.
- The findings emphasize the importance of carefully selecting industrial chitosan to avoid negative effects on pharmaceuticals and biomaterials, and caution against using stainless-steel equipment for making medical-grade chitosan due to corrosion risks.
Article Abstract
A series of industrial chitosans were analyzed on the presence of residual heavy metals. For the first time, optical microscopy data showed that chitosan solution retained a huge number of insoluble microparticles while transmittance electron microscopy revealed that insoluble fibrous microparticles were incrusted by crystalline nanoparticles with the sizes 5-50 nm. A series of filters used for chitosan solution filtration was analyzed on the presence of retained heavy metal and other residuals by scanning electron microscopy with energy dispersive X-ray spectroscopy (SEM-EDXS) and mass-spectrometry with inductively coupled plasma (ICP-MS) methods. The SEM-EDXS analysis revealed the presence of Fe residuals together with Si, Al, N and S in the particles found on the filters. ICP-MS analysis found the presence of heavy metals (mainly Fe, Cr and Ni) both on the filter surfaces and in the effluent chitosan solution passed though the filters. This study draws attention to the necessity of a careful selection of industrially manufactured chitosan in order to avoid hidden undesirable effects of chitosan on pharmaceuticals and biomaterials and gives a warning of inapplicability of a stainless-steel made apparatus as a reactor susceptible to caustic soda corrosion for chitin deacetylation and production of medical and food grade chitosan.
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| http://dx.doi.org/10.1016/j.ijbiomac.2019.11.059 | DOI Listing |
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