Cellular Uptake of Upconversion Nanoparticles Based on Surface Polymer Coatings and Protein Corona.

Upconversion nanoparticles (UCNPs) are materials that provide unique advantages for biomedical applications. There are constantly emerging customized UCNPs with varying compositions, coatings, and upconversion mechanisms. Cellular uptake is a key parameter for the biological application of UCNPs. Uptake experiments have yielded highly varying results, and correlating trends between cellular uptake with different types of UCNP coatings remains challenging. In this report, the impact of surface polymer coatings on the formation of protein coronas and subsequent cellular uptake of UCNPs by macrophages and cancer cells was investigated. Luminescence confocal microscopy and elemental analysis techniques were used to evaluate the different coatings for internalization within cells. Pathway inhibitors were used to unravel the specific internalization mechanisms of polymer-coated UCNPs. Coatings were chosen as the most promising for colloidal stability, conjugation chemistry, and biomedical applications. PIMA-PEG (poly(isobutylene-alt-maleic) anhydride with polyethylene glycol)-coated UCNPs were found to have low cytotoxicity, low uptake by macrophages (when compared with PEI, poly(ethylenimine)), and sufficient uptake by tumor cells for surface-loaded drug delivery applications. Inductively coupled plasma-optical emission spectroscopy (ICP-OES) studies revealed that PIMA-coated NPs were preferentially internalized by the clathrin- and caveolar-independent pathways, with a preference for clathrin-mediated uptake at longer time points. PMAO-PEG (poly(maleic anhydride-alt-1-octadecene) with polyethylene glycol)-coated UCNPs were internalized by energy-dependent pathways, while PAA- (poly(acrylic acid)) and PEI-coated NPs were internalized by multifactorial mechanisms of internalization. The results indicate that copolymers of PIMA-PEG coatings on UCNPs were well suited for the next-generation of biomedical applications.

Enhanced Immunoassay Using a Rotating Paper Platform for Quantitative Determination of Low Abundance Protein Biomarkers.

The changing concentrations of circulating protein biomarkers have been correlated with a variety of diseases. Quantitative bioassays capable of sensitive and specific determination of protein biomarkers at low levels can be essential for therapeutic treatments that can improve outcomes for patients. Herein, we describe the investigation of a rotating paper device (RPD) for quantitative determination of targeted proteins at the fM concentration level. The RPD consists of two circular papers each separately supported with a plastic disc. Protein detection is conducted via enhanced immunoassay using amplification in a sequential workflow, which includes a sandwich immunoassay in the upper paper and a signal amplification reaction in the lower paper. The sandwich immunoassay is conducted using biobarcode nanoparticles (BNPs) and results in the release of reporter oligonucleotides from BNPs. These oligonucleotides are transferred to the bottom paper, where they engage in a target recycling methodology that leads to the production of a colorimetric signal. The assay was evaluated for quantitation of interleukin-6 (IL-6), a cytokine biomarker in serum. A limit of detection of 63 fM and a dynamic range of 200 fM-8 pM was observed for the assay. The specificity of the assay was successfully verified against several common protein biomarkers.

Cancer biomarker determination by resonance energy transfer using functional fluorescent nanoprobes.

The development of bioanalytical methods that provide early detection of the presence of cancer by sensitive and specific determination of biomarkers such as small biomolecules, nucleic acids, proteins, enzymes, and even whole cells are essential to improve opportunity for improved patient treatment and to diminish the rate of cancer mortality. Förster resonance energy transfer (FRET) methods have been increasingly used to develop bioassays that offer speed, selectivity and low detection levels with practicality that is appropriate for providing point-of-care measurements for screening. The unique optical and photophysical properties of fluorescent nanoparticles such as semiconductor quantum dots (QDs), upconversion nanoparticles (UCNPs), graphene quantum dots (GQDs) and other materials have been reported to operate as efficient donors and/or acceptors for replacement of fluorescent organic dye molecules in various FRET-based assays. This review is focused on the recent progress that has been made in the development of nanoparticle-based FRET bioassays, and considers nanoparticle synthesis, design of optical properties, conjugation chemistry and approaches to fluorescence detection that provide for selective and sensitive quantification of cancer biomarkers.

Detection of cystic fibrosis transmembrane conductance regulator ΔF508 gene mutation using a paper-based nucleic acid hybridization assay and a smartphone camera.

Diagnostic technology that makes use of paper platforms in conjunction with the ubiquitous availability of digital cameras in cellular telephones and personal assistive devices offers opportunities for development of bioassays that are cost effective and widely distributed. Assays that operate effectively in aqueous solution require further development for implementation in paper substrates, overcoming issues associated with surface interactions on a matrix that offers a large surface-to-volume ratio and constraints on convective mixing. This report presents and compares two related methods for determination of oligonucleotides that serve as indicators of cystic fibrosis, differentiating between the normal wild-type sequence, and a mutant-type sequence that has a 3-base replacement. The transduction strategy operates by selective hybridization of oligonucleotide probes that are conjugated to fluorescent quantum dots, where hybridization of target sequences causes a molecular fluorophore to approach the quantum dot and become emissive through fluorescence resonance energy transfer. Detection can rely on hybridization of a target that is labelled with Cy3 fluorophore, or in the presence of an unlabelled target when a sandwich assay format is implemented with a labelled reporter oligonucleotide. Selectivity to determine the presence of mismatched sequences involves appropriate selection of nucleotide sequences to set melt temperatures, in conjunction with control of stringency conditions using formamide as a chaotrope. It was determined that both direct and sandwich assays on paper substrates are able to distinguish between wild-type and mutant-type samples.

Detection of a cancer biomarker protein on modified cellulose paper by fluorescence using aptamer-linked quantum dots.

The development of point-of-care bioassays for sensitive screening of protein-based cancer biomarkers would improve the opportunity for early stage diagnosis. A strategy for a fluorescence resonance energy transfer (FRET)-based bioassay has been investigated that makes use of modified cellulose paper for the detection of an epithelial cell adhesion molecule (EpCAM), which is a transmembrane glycoprotein that is overexpressed in several tumors of epithelial origin. The paper matrix was a substrate for immobilized aptamer-linked quantum dots (QDs-Apt) and Cy3 labeled complementary DNA (cDNA), which served as a donor and an acceptor, respectively. Competitive binding of EpCAM displaced the cDNA, resulting in the reduction of FRET. The paper-based bioassay was able to detect EpCAM in buffer solution as well as in 10% bovine serum solution using a reaction time of no more than 60 minutes. The dynamic range was 1-100 nM in buffer with a precision better than 4%, and the limit of detection was 250 pM in buffer and 600 pM in 10% serum.

Paper-based biodetection using luminescent nanoparticles.

Point-of-care and in-field technologies for rapid, sensitive and selective detection of molecular biomarkers have attracted much interest. Rugged bioassay technology capable of fast detection of markers for pathogens and genetic diseases would in particular impact the quality of health care in the developing world, but would also make possible more extensive screening in developed countries to tackle problems such as those associated with water and food quality, and tracking of infectious organisms in hospitals and clinics. Literature trends indicate an increasing interest in the use of nanomaterials, and in particular luminescent nanoparticles, for assay development. These materials may offer attributes for development of assays and sensors that could achieve improvements in analytical figures of merit, and provide practical advantages in sensitivity and stability. There is opportunity for cost-efficiency and technical simplicity by implementation of luminescent nanomaterials as the basis for transduction technology, when combined with the use of paper substrates, and the ubiquitous availability of cell phone cameras and associated infrastructure for optical detection and transmission of results. Luminescent nanoparticles have been described for a broad range of bioanalytical targets including small molecules, oligonucleotides, peptides, proteins, saccharides and whole cells (e.g., cancer diagnostics). The luminescent nanomaterials that are described herein for paper-based bioassays include metal nanoparticles, quantum dots and lanthanide-doped nanocrystals. These nanomaterials often have broad and strong absorption and narrow emission bands that improve opportunity for multiplexed analysis, and can be designed to provide emission at wavelengths that are efficiently processed by conventional digital cameras. Luminescent nanoparticles can be embedded in paper substrates that are designed to direct fluid flow, and the resulting combination of technologies can offer competitive analytical performance at relatively low cost.

Near-infrared-triggered anticancer drug release from upconverting nanoparticles.

Targeted drug delivery using functional nanoparticles has provided new strategies for improving therapeutic efficacy while concurrently minimizing toxicity. Photodynamic therapy is an approach that offers control of drug delivery by use of an external photon source to allow active therapeutic release to a target area. Upconverting nanoparticles (UCNPs) have potential to operate as integral components of photodynamic therapeutic platforms based on the resonant absorption of near-infrared (NIR) radiation and emission at shorter wavelengths. NIR radiation is minimally absorbed and scattered by biological tissues, and the NIR excitation of UCNPs can generate anti-Stokes emission in the ultraviolet-visible wavelength range at intensities that can be used to trigger cleavage of bonds linking therapeutics at the nanoparticle interface. Herein, we describe an investigation of photocleavage at the surface of UCNPs to release the chemotherapeutic 5-fluorouracil (5-FU). Core-shell UCNPs composed of a ß-NaYF4: 4.95% Yb, 0.08% Tm core and a ß-NaYF4 shell were coated with o-phosphorylethanolamine ligands and coupled to an o-nitrobenzyl (ONB) derivative of 5-FU. NIR excitation of the UCNPs resulted in photoluminescence (PL) emission bands centered at 365, 455, and 485 nm. The UV-blue PL was in resonance with the absorption band of the ONB-FU derivative resulting in photocleavage and subsequent release of the 5-FU drug from the UCNPs for these in vitro studies. The release of 5-FU was complete in <14 min using a NIR laser source centered at 980 nm that operated at a power of <100 mW. The efficiency of triggered release was as high as 77% of the total ONB-FU conjugate, while the rate of drug release could be tuned with the laser power output. This work provides an important first step in the development of a UCNP platform capable of targeted chemotherapy.

Quantum dots as contrast agents for in vivo tumor imaging: progress and issues.

Quantum dots (QDs) have shown promise as imaging agents in cancer, heart disease, and gene therapy research. This review focuses on the design of QDs, and modification using peptides and proteins for mediated targeting of tissues for fluorescence imaging of tumors in vivo. Recent examples from the literature are used to illustrate the potential of QDs as effective imaging agents. The distribution and ultimate fate of QDs in vivo is considered, and considerations of designs that minimize potential toxicity are presented.

Fluorescence anisotropy: from single molecules to live cells.

The polarization of light emitted by fluorescent probes is an easily accessible physical quantity that is related to a multitude of molecular parameters including conformation, orientation, size and the nanoscale environment conditions, such as dynamic viscosity and temperature. In analytical biochemistry and analytical chemistry applied to biological problems, fluorescence anisotropy is widely used for measuring the folding state of proteins and nucleic acids, and the affinity constant of ligands through titration experiments. The emphasis of this review is on new multi-parameter single-molecule detection schemes and their bioanalytical applications, and on the use of ensemble polarization assays to study binding and conformational dynamics of proteins and aptamers and for high-throughput discovery of small-molecule drugs.

Synthesis and fluorescence studies of thiazole orange tethered onto oligonucleotide: development of a self-contained DNA biosensor on a fiber optic surface.

Thiazole orange dyes were derivatized with ethylene glycol linkers of various lengths, and were covalently linked to the 5' end of the oligonucleotides after solid-phase synthesis. The labeled oligonucleotides exhibited enhanced fluorescence upon hybridization to complementary DNA sequences at the surfaces of optical fibers, providing for a self-contained labeling strategy. It was determined that the melt temperatures of DNA hybrids using one mixed polypyrimidine base oligonucleotide sequence were dependent on the length of the tethers, and that the melt temperature could be shifted by more than 10 degrees C when tethers were introduced.

Real-time PCR for quantification of Giardia and Cryptosporidium in environmental water samples and sewage.

The protozoan pathogens Giardia lamblia and Cryptosporidium parvum are major causes of waterborne enteric disease throughout the world. Improved detection methods that are very sensitive and rapid are urgently needed. This is especially the case for analysis of environmental water samples in which the densities of Giardia and Cryptosporidium are very low. Primers and TaqMan probes based on the beta-giardin gene of G. lamblia and the COWP gene of C. parvum were developed and used to detect DNA concentrations over a range of 7 orders of magnitude. It was possible to detect DNA to the equivalent of a single cyst of G. lamblia and one oocyst of C. parvum. A multiplex real-time PCR (qPCR) assay for simultaneous detection of G. lamblia and C. parvum resulted in comparable levels of detection. Comparison of DNA extraction methodologies to maximize DNA yield from cysts and oocysts determined that a combination of freeze-thaw, sonication, and purification using the DNeasy kit (Qiagen) provided a highly efficient method. Sampling of four environmental water bodies revealed variation in qPCR inhibitors in 2-liter concentrates. A methodology for dealing with qPCR inhibitors that involved the use of Chelex 100 and PVP 360 was developed. It was possible to detect and quantify G. lamblia in sewage using qPCR when applying the procedure for extraction of DNA from 1-liter sewage samples. Numbers obtained from the qPCR assay were comparable to those obtained with immunofluorescence microscopy. The qPCR analysis revealed both assemblage A and assemblage B genotypes of G. lamblia in the sewage. No Cryptosporidium was detected in these samples by either method.