Affiliation:
1. Laboratory of Nanostructured Polymers (NANOPOL) Federal University of Amazonas (UFAM) Manaus AM Brazil
2. Graduate Program in Biotechnology (PPGBIOTEC) Federal University of Amazonas (UFAM) Manaus AM Brazil
3. São Carlos Institute of Physics (IFSC) University of São Paulo (USP) São Carlos SP Brazil
4. Graduate Program in Physics (PPGFIS) Federal University of Amazonas (UFAM) Manaus AM Brazil
5. Laboratory of Infectious Diseases and Immunology Fundação Oswaldo Cruz ‐ Instituto Leônidas e Maria Deane (FIOCRUZ‐ILMD) Manaus AM Brazil
6. Graduate Program in Basic and Applied Immunology (PPGIBA) Federal University of Amazonas (UFAM) Manaus AM Brazil
7. Analytical Center, Federal Institute of Education Science and Technology of Amazonas (IFAM) Manaus AM Brazil
8. Department of Food Technology Federal University of Viçosa (UFV) Viçosa MG Brazil
9. The Directorate of Research, Development and Innovation Management (DMCDI) Technical University of Cluj‐Napoca Cluj‐Napoca Romania
10. Laboratory of Genomics (LABGEN) Hospital Foundation of Hematology and Hemotherapy of Amazonas (HEMOAM) Manaus AM Brazil
Abstract
AbstractThe environment preservation has been an important motivation to find alternative, functional, and biodegradable materials to replace polluting petrochemicals. The production of nonbiodegradable face masks increased the concentration of microplastics in the environment, highlighting the need for sustainable alternatives, such as the use of local by‐products to create efficient and eco‐friendly filtering materials. Furthermore, the use of smart materials can reduce the risk of contagion and virus transmission, especially in the face of possible mutations. The development of novel materials is necessary to ensure less risk of contagion and virus transmission, as well as to preserve the environment. Taking these factors into account, 16 systems were developed with different combinations of precursor materials (holocellulose, polyaniline [ES‐PANI], graphene oxide [GO], silver nanoparticles [AgNPs], and activated carbon [AC]). Adsorption tests of the spike protein showed that the systems containing GO and AC were the most efficient in the adsorption process. Similarly, plate tests conducted using the VSV‐IN strain cultured in HepG2 cells showed that the system containing all phases showed the greatest reduction in viral titer method. In agreement, the biocompatibility tests showed that the compounds extracted from the systems showed low cytotoxicity or no significant cytotoxic effect in human fibroblasts. As a result, the adsorption tests of the spike protein, viral titration, and biocompatibility tests showed that systems labeled as I and J were the most efficient. In this context, the present research has significantly contributed to the technological development of antiviral systems, with improved properties and increased adsorption efficiency, reducing the viral titer and contributing efficiently to public health. In this way, these alternative materials could be employed in sensors and devices for filtering and sanitization, thus assisting in mitigating the transmission of viruses and bacteria.Research Highlights
Sixteen virus adsorbent systems were developed with different combinations of precursor materials (holocellulose, polyaniline (ES‐PANI), graphene oxide (GO), silver nanoparticles (AgNPs), and activated carbon (AC)).
The system that included all of the nanocomposites holocellulose, PANI, GO, AgNPs, and AC showed the greatest reduction in viral titration.
The biocompatibility tests revealed that all systems caused only mild or moderate cytotoxicity toward human fibroblasts.
Funder
Fundação de Amparo à Pesquisa do Estado de São Paulo