Cytotoxicity and cell imaging of six types of carbon nanodots prepared through carbonization and hydrothermal processing of natural plant materials

Yu-Yu Chen; Wen-Ping Jiang; Huan-Luen Chen; Hui-Chi Huang; Guan-Jhong Huang; Hsiu-Mei Chiang; Chang-Cheng Chang; Cheng-Liang Huang; Tzong-Yuan Juang

doi:10.1039/d1ra01318a

Cytotoxicity and cell imaging of six types of carbon nanodots prepared through carbonization and hydrothermal processing of natural plant materials

RSC Adv. 2021 May 7;11(27):16661-16674. doi: 10.1039/d1ra01318a. eCollection 2021 Apr 30.

Authors

Yu-Yu Chen¹, Wen-Ping Jiang^{2

3}, Huan-Luen Chen¹, Hui-Chi Huang^{4

5}, Guan-Jhong Huang⁴, Hsiu-Mei Chiang¹, Chang-Cheng Chang^{6

7}, Cheng-Liang Huang⁸, Tzong-Yuan Juang¹

Affiliations

¹ Department of Cosmeceutics, China Medical University Taichung Taiwan tyjuang@mail.cmu.edu.tw.
² Department of Occupational Therapy, Asia University Taichung Taiwan.
³ Department of Pharmacy, Chia Nan University of Pharmacy and Science Tainan Taiwan.
⁴ Department of Chinese Pharmaceutical Sciences and Chinese Medicine Resources, China Medical University Taichung Taiwan.
⁵ Master Program for Food and Drug Safety, China Medical University Taichung Taiwan.
⁶ Aesthetic Medical Center, China Medical University Hospital Taichung Taiwan.
⁷ School of Medicine, China Medical University Taichung Taiwan.
⁸ Department of Applied Chemistry, National Chiayi University Chiayi Taiwan.

Abstract

In this study we prepared six types of carbon nanodots (CNDs) from natural plant materials - through carbonization of two species of bamboo (Bamboo-I, Bamboo-II) and one type of wood (Wood), and through hydrothermal processing of the stem and root of the herb Mahonia oiwakensis Hayata (MO) and of the agricultural waste of two species of pineapple root (PA, PB). The resulting CNDs were spherical with dimensions on the nanoscale (3-7 nm); furthermore, CND-Bamboo I, CND-Wood, CND-Bamboo II, CND-MO, CND-PA, and CND-PB displayed fluorescence quantum yields of 9.63, 12.34, 0.90, 10.86, 0.35, and 0.71%, respectively. X-ray diffraction revealed that the carbon nanostructures possessed somewhat ordered and disordered lattices, as evidenced by broad signals at values of 2θ between 20 and 30°. CND-Bamboo I, CND-Wood, and CND-Bamboo II were obtained in yields of 2-3%; CND-MO, CND-PA, and CND-PB were obtained in yields of 17.64, 9.36, and 22.47%, respectively. Cytotoxicity assays for mouse macrophage RAW264.7 cells treated with the six types of CNDs and a commercial sample of Ag nanoparticles (NPs) revealed that each of our CNDs provided a cell viability of 90% at 2000 μg mL^-1, whereas it was only 20% after treatment with the Ag NPs at 62.5 μg mL^-1. The six types of CNDs also displayed low cytotoxicity toward human keratinocyte HacaT cells, human MCF-7 breast cancer cells, and HT-29 colon adenocarcinoma cells when treated at 500 μg mL^-1. Moreover, confocal microscopic cell imaging revealed that the fluorescent CND-Bamboo I particles were located on the MCF-7 cell membrane and inside the cells after treatment for 6 and 24 h, respectively. We have thoroughly investigated the photoluminescence properties and carbon nanostructures of these highly dispersed CNDs. Because of the facile green synthesis of these six types of CNDs and their sourcing from abundant natural plants, herbs, and agriculture waste, these materials provide a cost-effective method, with low cytotoxicity and stable fluorescence, for biolabeling and for developing cell nanocarriers.