Methods to detect immuno-labelled molecules at increasingly higher resolution, even when present at low levels, are revolutionizing immunohistochemistry (IHC). These technologies can be valuable for management and examination of rare patient tissue specimens, and for improved accuracy of early disease detection. The purpose of this mini-review is to highlight recent multiplexing methods that are candidates for more prevalent use in clinical research and potential translation to the clinic. Multiplex IHC methods, which permit identification of at least 3 and up to 30 discrete antigens, have been divided into whole section staining and spatially-patterned staining categories. Associated signal enhancement technologies that can enhance performance and throughput of multiplex IHC assays are also discussed. Each multiplex IHC technique, detailed herein, is associated with several advantages as well as tradeoffs that must be taken into consideration for proper evaluation and use of the methods.
Accurate disease diagnosis, patient stratification and biomarker validation require the analysis of multiple biomarkers. This paper describes cross-reactivity-free multiplexing of enzyme-linked immunosorbent assays (ELISAs) using aqueous two-phase systems (ATPSs) to confine detection antibodies at specific locations in fully aqueous environments. Antibody cross-reactions are eliminated because the detection antibody solutions are co-localized only to corresponding surface-immobilized capture antibody spots. This multiplexing technique is validated using plasma samples from allogeneic bone marrow recipients. Patients with acute graft versus host disease (GVHD), a common and serious condition associated with allogeneic bone marrow transplantation, display higher mean concentrations for four multiplexed biomarkers (HGF, elafin, ST2 and TNFR1) relative to healthy donors and transplant patients without GVHD. The antibody co-localization capability of this technology is particularly useful when using inherently cross-reactive reagents such as polyclonal antibodies, although monoclonal antibody cross-reactivity can also be reduced. Because ATPS-ELISA adapts readily available antibody reagents, plate materials and detection instruments, it should be easily transferable into other research and clinical settings.
Engineering
useful mechanical properties into stimuli-responsive soft materials
without compromising their responsiveness is, in many cases, an unresolved
challenge. For example, polymer networks formed within blue-phase
liquid crystals (BPs) have been shown to form mechanically robust
films, but the impact of polymer networks on the response of these
soft materials to chemical stimuli has not been explored. Here, we
report on the response of polymer-stabilized BPs (PSBPs) to volatile
organic compounds (VOCs, using toluene as a model compound) and compare
the response to BPs without polymer stabilization and to polymerized
nematic and cholesteric phases. We find that PSBPs generate an optical
response to toluene vapor (change in reflection intensity under crossed
polars) that is sixfold greater in sensitivity than the polymerized
nematic or cholesteric phases and with a limit of detection (140 ±
10 ppm at 25 °C) that is relevant to the measurement of permissible
exposure limits for humans. Additionally, when compared to BPs that
have not been polymerized, PSBPs respond to a broader range of toluene
vapor concentrations (5000 vs <1000 ppm) over a wider temperature
interval (25–45 vs 45–53 °C). We place these experimental
observations into the context of a simple thermodynamic model to explore
how the PSBP response reflects the effect of toluene on competing
contributions of double-twisted LC cylinders, disclinations, and polymer
network to the free energy that controls the PSBP lattice spacing.
Overall, we conclude that the mechanical and thermal stability of
PSBPs, when combined with their optical responsiveness to toluene,
make this class of self-supporting LCs a promising one as the basis
of passive and compact (e.g., wearable) sensors for VOCs.
We report formation of Janus droplets with coexisting liquid crystalline and isotropic compartments, stable spherical shapes, and widely tunable internal morphologies.
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