A consultation and work-up diagnosis protocol for a multicancer early detection test: a case series study.

The emergence of multicancer early detection (MCED) tests holds promise for improving early cancer detection and public health outcomes. However, positive MCED test results require confirmation through recommended cancer diagnostic imaging modalities. To address these challenges, we have developed a consultation and work-up protocol for definitive diagnostic results post MCED testing, named SPOT-MAS.

Carbon Nanomaterial-Based Nanofluids for Direct Thermal Solar Absorption.

Recently, many scientists have been making remarkable efforts to enhance the efficiency of direct solar thermal absorption collectors that depends on working fluids. There are a number of heat transfer fluids being investigated and developed. Among these fluids, carbon nanomaterial-based nanofluids have become the candidates with the most potential by the heat absorbing and transfer properties of the carbon nanomaterials.

Dynamic Covalent Chemistry as a Facile Route to Unusual Main-Group Thiolate Assemblies and Disulfide Hoops and Cages.

Dynamic Covalent Chemistry (DCC) - combining the robustness of covalent bonds with the self-correcting nature of supramolecular chemistry - facilitates the modular synthesis of complex molecular assemblies in high yields. Although numerous reactions form covalent bonds, only a small set of chemical transformations affect covalent bond formation reversibly under suitable conditions for DCC. Further progress in this area still requires the identification of dynamic motifs and greater insights into their reversibility.

Self-sorting in dynamic disulfide assembly: new biphenyl-bridged "nanohoops" and unsymmetrical cyclophanes.

We expand on our approach combining dynamic covalent self-assembly and sulfur extrusion to synthesize new biphenyl-linked disulfide and thioether macrocycles, which are variants of the venerable phenyl-bridged paracyclophanes. We then advance this strategy further to use two different thiols in tandem to provide new, elusive unsymmetrical disulfides which can also be trapped as unsymmetrical thioether "nanohoops". This approach enables substantial amplification of two unsymmetrical trimers out of a library of at least 21 possible macrocycles of various sizes.

Copper(ii) serves as an efficient additive for metal-directed self-assembly of over 20 thiacyclophanes.

Cu2+ salts are presented as an alternative to previously reported pnictogen additives in the self-assembly of 23 different thiacyclophanes. This process allows for further tuning of library equilibrium mixtures: for instance, by altering additive types and concentrations, trimeric macrocycles are amplified. These trimeric disulfides can then be covalently trapped to form 2 novel thioethers, highlighting the facile route to access these new naphthalene-bridged cyclophanes.

Coupling Metaloid-Directed Self-Assembly and Dynamic Covalent Systems as a Route to Large Organic Cages and Cyclophanes.

The synthesis of large cyclic and caged disulfide structures was achieved by pnictogen-assisted iodine oxidation starting from self-assembled pnictogen thiolate complexes. The directing behavior of pnictogen enables rapid and selective syntheses of many discrete disulfide assemblies over competing oligomers/polymers, ranging from structures that are small and strained to those that are large and multifaceted, including 3D cages. Traditional cyclization reactions carried out under kinetic control are generally low-yielding, which often results in the formation of insoluble oligomers and polymers as unwanted side products.

Direct measurement of the absolute absorption spectrum of individual semiconducting single-wall carbon nanotubes.

The optical properties of single-wall carbon nanotubes are very promising for developing novel opto-electronic components and sensors with applications in many fields. Despite numerous studies performed using photoluminescence or Raman and Rayleigh scattering, knowledge of their optical response is still partial. Here we determine using spatial modulation spectroscopy, over a broad optical spectral range, the spectrum and amplitude of the absorption cross-section of individual semiconducting single-wall carbon nanotubes.