Square wave voltammetry based electrochemical determination of affinity of cholesterol triethylene glycol modified DNA-aptamers for protoporphyrin IX.

Recent advancement in molecular medicine has seen applications of advanced biotechnology tools such as aptamer technology in therapeutics and diagnostics. Aptamer technology has witnessed various approaches including "Click-Chemistry" towards modifying aptamer structure to improve its potentials, but limited studies have reported the influence of such alteration on aptamer's specificity and affinity for their targets. Here, we utilized square wave voltammetry (SWV) electrochemical sensing based on heme to show the effects of cholesterol-triethylene-glycol (COL-TEG) modification of protoporphyrin-IX DNA-aptamers (OKA_24 and OKA_26) on their affinity for heme. Binding was evaluated by immobilizing 5 µM of heme onto cysteamine-glutaraldehyde-coated gold-electrode to construct electrochemical biosensor. Sensing of native/modified-aptamer was achieved by incubating their varying concentrations (9.76 nM - 10 µM) with heme-coated gold-electrode in HKSCM buffer pH 5, for 15 min. Chloroquine (2.5 µM) and non-binding HPIX-aptamer (2.5 µM) served as controls. Ferrocene was the redox solution used for SWV analysis. Protoporphyrin-IX DNA-aptamers specificity for heme was not tarnish by lipid conjugation. Selective binding of 2.5 µM of COL-TEG-OKA_24 and COL-TEG-OKA_26 to heme induced peak-current reduction by 30.68% and 24% respectively. Incubation of OKA_24 and OKA_26 aptamers produced resistance to current flow through the heme-coated gold-electrode by 23.21% and 14.4 8% respectively. Affinity SWV reveals that cholesterol conjugation decreases the affinity of COL-TEG-OKA_24 (KD = 4 7.13 ± 3.767 nM) and COL-TEG-OKA_24 (KD = 84.6 ± 8.7 nM) by 3- fold. There is a need to check the impact of such alteration on inhibition of heme to hemozoin polymerization, a process mediated by Plasmodium falciparum.

Colorimetric Approach for Nucleic Acid Salmonella spp. Detection: A Systematic Review.

Water- and food-related health issues have received a lot of attention recently because food-poisoning bacteria, in particular, are becoming serious threats to human health. Currently, techniques used to detect these bacteria are time-consuming and laborious. To overcome these challenges, the colorimetric strategy is attractive because it provides simple, rapid and accurate sensing for the detection of Salmonella spp. bacteria. The aim of this study is to review the progress regarding the colorimetric method of nucleic acid for Salmonella detection. A literature search was conducted using three databases (PubMed, Scopus and ScienceDirect). Of the 88 studies identified in our search, 15 were included for further analysis. Salmonella bacteria from different species, such as S. Typhimurium, S. Enteritidis, S. Typhi and S. Paratyphi A, were identified using the colorimetric method. The limit of detection (LoD) was evaluated in two types of concentrations, which were colony-forming unit (CFU) and CFU per mL. The majority of the studies used spiked samples (53%) rather than real samples (33%) to determine the LoDs. More research is needed to assess the sensitivity and specificity of colorimetric nucleic acid in bacterial detection, as well as its potential use in routine diagnosis.

Prognostic prospect of soluble programmed cell death ligand-1 in cancer management.

Aggressive tissue biopsy is commonly unavoidable in the management of most suspected tumor cases to conclusively verify the presence of cancerous cells through histological assessment. The extracted tissue is also immunostained for detection of antigens (tissue tumor markers) of potential prognostic or therapeutic importance to assist in treatment decision. Although liquid biopsies can be a powerful tool for monitoring treatment response, they are still excluded from standard cancer diagnostics, and their utility is still being debated in the scientific community. With a myriad of soluble tissue tumor markers now being discovered, liquid biopsies could completely change the current paradigms of cancer management. Recently, soluble programmed cell death ligand-1 (sPD-L1), which is found in the peripheral blood, i.e. serum and plasma, has shown potential as a pre-therapeutic predictive marker as well as a prognostic biomarker to monitor treatment efficacy. Thus, this review focuses on the emergence of sPD-L1 and promising technologies for its detection in order to support liquid biopsies for future cancer management.