Exploring the Accumulation Behavior and Heterogeneity of Perfluorooctanesulfonic Acid in Zebrafish Primary Organ Cells by Single-Cell Mass Cytometry.

Perfluorooctanesulfonic acid (PFOS) is a commonly found environmental pollutant with potential toxicity and health risks to biosystems and ecosystems. Study of the accumulation behavior and heterogeneity of PFOS in biological primary organ cells provides us significant insights to explore its cytotoxicity, carcinogenicity, and mutagenicity. Here a single-cell mass cytometry system was established for the high-throughput analysis of trace PFOS and the exploration of its accumulation behavior and heterogeneity in zebrafish primary organ cells. The single-cell mass cytometry system applied a ∼25 µm constant-inner-diameter capillary as the single-cell generation and transportation channel with an etched tip-end of 40 µm as the nanoelectrospray emitter for mass spectrometric analysis. The single-cell mass cytometry system showed satisfactory semiquantitative performance and sensitivity for analysis of PFOS in single cells, with a high detection throughput of ∼35 cells/min. Subsequently, the liver, intestine, heart, and brain from PFOS-exposed zebrafish (100 pg/µL, 28 days) were dissociated and prepared as cell suspensions, and the cell suspensions were introduced into the single-cell mass cytometry system for high-throughput analysis of PFOS in individual primary organ cells. Significant cellular accumulation heterogeneities were observed, with the highest content in liver cells, followed by intestine cells, then heart cells, and the lowest in brain cells. In addition, the dynamics of PFOS in the zebrafish liver, intestine, heart, and brain cells showed typical violin plot distributions and were well-described using a gamma (γ) function.

Single-cell transcriptomic analysis reveals heterogeneity of the patterns of responsive genes and cell communications in liver cell populations of zebrafish exposed to polystyrene nanoplastics.

Nanoplastics (NPs) are a group of emerging environmental pollutants with potential toxicity and health risk on biosystem and ecosystem. Great efforts have been devoted to describing the uptake, distribution, accumulation, and toxicity of NPs at various aquatic organisms; however, the heterogeneous response patterns in zebrafish (Danio rerio) liver cell populations caused by NP exposure have not yet been clarified. Investigation of the heterogeneous response patterns in zebrafish liver cell populations after NPs exposure provides us significances to explore the NP cytotoxicity. In this article, the heterogeneous response patterns in zebrafish liver cell populations after polystyrene (PS)-NPs exposure were studied. Significantly increased content of malondialdehyde and decreased levels of catalase and glutathione were observed, indicating the oxidative damage of zebrafish liver induced by PS-NPs exposure. Afterwards, the liver tissues were enzymatically dissociated and used for single-cell transcriptomic (scRNA-seq) analysis. Nine cell types were identified based on unsupervised cell cluster analysis followed by their marker genes. Hepatocytes were the cell type most impacted by PS-NP exposure, and heterogeneous response patterns of male and female hepatocytes were observed. The PPAR signaling pathway was up-regulated in hepatocytes from both male and female zebrafish. Lipid metabolism-related functions were altered more notably in male-derived hepatocytes, while female-derived hepatocytes were more sensitive to estrogen stimulus and mitochondria. Macrophages and lymphocytes were also highly responsive cell types, with specific immune pathways activated to suggest immune disruption after exposure. Oxidation-reduction process and immune response were significantly altered in macrophages, and oxidation-reduction process, ATP synthesis, and DNA binding were most altered in lymphocytes. Our study not only integrates scRNA-seq with toxicology effects to identify highly sensitive and specific populations of responding cells, revealing highly specialized interactions between parenchymal and non-parenchymal cells and expanding our current understanding of PS-NPs toxicity, but also highlights the importance of cellular heterogeneity in environmental toxicology.

Microfluidic chip interfacing microdialysis and mass spectrometry for in vivo monitoring of nanomedicine pharmacokinetics in real time.

Although liposomes have demonstrated significant clinical success as drug delivery vehicles, pharmacokinetic (PK) profiling of liposomal nanomedicines remains difficult due to technical challenges accurately measuring low concentrations of free drug in complex biological matrices. Microdialysis (MD) is well established as a powerful in vivo sampling tool for PK studies, but non-volatile salts present in the microdialysate are incompatible with mass spectrometry (MS) analysis without tedious sample pre-treatment. To address this issue, a µSPE-based microfluidic chip was fabricated to interface MD with MS. By incorporating PEG 20,000 as an effective anti-foulant, the µSPE-based microfluidic chip demonstrated excellent efficiencies in drug extraction and de-salting of the microdialysate, providing a promising approach to real-time monitoring of nanomedicine PK profiles.

Quantitation of polymeric-microneedle-delivered HA15 in tissues using liquid chromatography-tandem mass spectrometry.

A rapid and sensitive liquid chromatography-tandem mass spectrometric method was developed and validated for the determination of HA15, an emerging anticancer compound targeting GSPA5/BIP delivered by dissolvable polymeric microneedles. The linear range of quantification for HA15 was 2.5-1000 ng/ml in plasma and tissue homogenate and the limit of detection and lower limit of quantification are 1 and 2.5 ng/ml, respectively. The inter- and intra-day accuracy and precision were within the acceptable range. HA15 was extracted from mouse plasma and organs using protein precipitation and using dabrafenib as an internal standard and the drug was stable under relevant analytical conditions. The method was used to analyze drug loading, dissolution in vitro, and release ex vivo from dissolvable polymeric microneedles and used to compare these materials to subcutaneous injection for the tissue distribution in tumor bearing nude mice.