In Situ Cellular Localization of Nonfluorescent [60]Fullerene Nanomaterial in MCF-7 Breast Cancer Cells

Sensitive and Facile Detection of Vitamin D Based on Fluorescent Labeled Aptamer Probe and Exonuclease I-Assisted Signal Amplification

This study presents a rapid, simple aptamer-based fluorescence sensor using fullerenes as a quencher for detecting vitamin D3. Fullerenes, with its π-electron cloud, acts as a powerful electron acceptor, facilitating Förster resonance energy transfer (FRET) from carboxyfluorescein (FAM). The aptamer, labeled with 5'6-FAM, adsorbs onto the fullerenes surface through hydrogen bonding and π-π stacking interactions, leading to fluorescence quenching. Upon vitamin D3 binding, the aptamer forms a hairpin structure that prevents adsorption onto the fullerenes surface, restoring fluorescence. The fullerenes were characterized using UV-Vis, FT-IR, Raman spectroscopy, SEM, TEM, and zeta potential measurements. The sensor's response to varying vitamin D3 concentrations was analyzed with a fluorescence spectrometer, revealing a linear detection range of 0-600 nM and a detection limit of 200 nM, which improved to 50 nM with exonuclease I. The sensor demonstrated a recovery rate of 88.4%-96.3% for vitamin D3 in water samples, confirming its feasibility for practical applications. In addition, our proposed sensor exhibited good repeatability (3.27%) and stability (90%). The innovative use of fullerenes as a fluorescence quencher, along with the aptamer's specific binding to vitamin D3, provides a novel and highly sensitive avenue for vitamin D3 detection.

Aminofullerenes as targeted inhibitors of EGFR: from pancreatic cancer inhibitors to Drosophila m. Toxicology

AIM

Pancreatic ductal adenocarcinoma (PDAC) is recognized as one of the most formidable cancers, largely due to its distinct microenvironment characterized predominantly by extensive desmoplastic stroma. In this study, we synthesized three novel water-soluble fullerene-based nanomaterials targeting EGFR protein.

METHODS

The direct amination of fullerene carbon atoms, was followed by conjugation with a modified derivative of the EGFR inhibitor-erlotinib, resulting in the formation of novel water-soluble fullerene derivatives.

RESULTS

Further investigation into PAN02 and AsPC-1 cell lines revealed that these fullerene nanomaterials could induce cell cycle arrest in the G0/G1 phase, corroborated by alterations in the expression levels of the p27 and cyclin E1 proteins. Additionally, mechanisms of cell death were identified as autophagy for C60BUT and C70BUT-ERL, and apoptosis for Gd@C82EDA-ERL nanomaterials.

CONCLUSIONS

Crucially, the study uncovered the efficacy of synthesized aminofullerenes in inhibiting the EGFR signaling pathway. The further toxicological studies of Gd@C82EDA-ERL fullerene on Drosophila melanogaster, underscored its potential for theranostic applications.

Toxicity mechanism of engineered nanomaterials: Focus on mitochondria

With the rapid development of nanotechnology, engineered nanomaterials (ENMs) are widely used in various fields. This has exacerbated the environmental pollution and human exposure of ENMs. The study of toxicity of ENMs and its mechanism has become a hot research topic in recent years. Mitochondrial damage plays an important role in the toxicity of ENMs. This paper reviews the structural damage, dysfunction, and molecular level perturbations caused by different ENMs to mitochondria, including ZnO NPs, Ag NPs, TiO2 NPs, iron oxide NPs, cadmium-based quantum dots, CuO NPs, silica NPs, carbon-based nanomaterials. Among them, mitochondrial quality control plays an important role in mitochondrial damage. We further summarize the cellular level outcomes caused by mitochondrial damage, mainly including, apoptosis, ferroptosis, pyroptosis and inflammation response. In addition, we concluded that reducing mitochondrial damage at source as well as accelerating recovery from mitochondrial damage through ENMs modification and pharmacological intervention are two feasible strategies. This review further provides new insights into the mitochondrial toxicity mechanisms of ENMs and provides a new foothold for predicting human health and environmental risks of ENMs.

Package delivered: folate receptor-mediated transporters in cancer therapy and diagnosis

Neoplasias pose a significant threat to aging society, underscoring the urgent need to overcome the limitations of traditional chemotherapy through pioneering strategies. Targeted drug delivery is an evolving frontier in cancer therapy, aiming to enhance treatment efficacy while mitigating undesirable side effects. One promising avenue utilizes cell membrane receptors like the folate receptor to guide drug transporters precisely to malignant cells. Based on the cellular folate receptor as a cancer cell hallmark, targeted nanocarriers and small molecule-drug conjugates have been developed that comprise different (bio) chemistries and/or mechanical properties with individual advantages and challenges. Such modern folic acid-conjugated stimuli-responsive drug transporters provide systemic drug delivery and controlled release, enabling reduced dosages, circumvention of drug resistance, and diminished adverse effects. Since the drug transporters' structure-based de novo design is increasingly relevant for precision cancer remediation and diagnosis, this review seeks to collect and debate the recent approaches to deliver therapeutics or diagnostics based on folic acid conjugated Trojan Horses and to facilitate the understanding of the relevant chemistry and biochemical pathways. Focusing exemplarily on brain and breast cancer, recent advances spanning 2017 to 2023 in conjugated nanocarriers and small molecule drug conjugates were considered, evaluating the chemical and biological aspects in order to improve accessibility to the field and to bridge chemical and biomedical points of view ultimately guiding future research in FR-targeted cancer therapy and diagnosis.

Uncovering nanotoxicity of a water-soluble and red-fluorescent [70]fullerene nanomaterial

Engineered fullerene materials have attracted the attention of researchers in the biomedical sciences, especially when their synthetic methodology is developed to endow them with significant levels of water-solubility and bioavailability. In this study, we synthesized and characterized a water-soluble and red-fluorescent [70]fullerene nanomaterial, which fluoresced at 693 nm with a quantum yield of 0.065 and a large Stokes shift (around 300 nm). The fullerene nanomaterial generated mainly singlet oxygen after illumination with blue LED light, while superoxide anion radical production was minimal. The transmission electron microscopy as well as fluorescent studies of Drosophila melanogaster revealed that prepared [70]fullerene nanoparticles had better bioavailability than pristine [70]fullerene nanoparticles. The designed nanomaterials were observed in the apical, perinuclear, and basal regions of digestive cells, as well as the basal lamina of the digestive system's epithelium, with no damage to cell organelles and no activation of degenerative processes and cell death. Our findings provide a new perspective for understanding the in vivo behavior of fullerene nanomaterials and their future application in bioimaging and light-activated nanotherapeutics.