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Category: chemistry

Technical advance ✨

Laszlo Nagy & team define unique regulatory programs of placental Hofbauer cells, advancing understanding of their role in pregnancy health and potential disease:

The image shows enrichment of Hofbauer cells by CD163-based cell sorting Placenta Fetal Development.

1Department of Biochemistry and Molecular Biology, Faculty of Medicine, and.

2Doctoral School of Molecular Cell and Immune Biology, University of Debrecen, Debrecen, Hungary.

3Institute for Fundamental Biomedical Research, Johns Hopkins All Children’s Hospital, St. Petersburg, Florida, USA.

Early vertebrate biomineralization and eye structure determined by synchrotron X-ray analyses of Silurian jawless fish

Complex eyes in vertebrates may have evolved as early as 500 million years ago. Reconstructing the early evolutionary history of vertebrates requires understanding organisms that existed before bone evolved. However, these ‘soft-bodied’ fossils are inherently difficult to study, resulting in conflicting anatomical and evolutionary interpretations. For the first time, researchers used synchrotron-based imaging techniques to examine two Silurian taxa, Jamoytius and Lasanius, that may bridge the gap between the bone-less and boned vertebrates. They recover the first direct evidence of biomineralised apatitic bone in both taxa and of camera-eyes in Jamoytius. The discoveries indicate vertebrate bones and complex eyes evolved earlier than previously thought, and demonstrate the power of these techniques for problematic fossils.

Read the article in Proceedings B.

Abstract. Understanding the origin and early diversification of vertebrates has always been a challenge because of the ambiguous and conflicting interpretations of the soft-bodied, pre-biomineralization fossil record. Here, we apply synchrotron radiation techniques to Jamoytius and Lasanius, two soft-bodied Silurian vertebrates, key taxa for discerning vertebrate bone evolution owing to highly localized, but debated, biomineralization. We map soft-tissue structures and quantify details of biochemical residue impossible to resolve with traditional methods. We present the first unequivocal evidence for biomineralized apatitic scales in Jamoytius by combining synchrotron rapid scanning X-ray fluorescence and Fourier transform infrared spectroscopy (elevated Ca 37% and P 21%). This approach also recovers robust evidence for apatitic biomineralization in Lasanius. Chemical mapping of the optical anatomy of Jamoytius recovers a close correlation with Zn and Cu distribution, providing evidence for a retinal pigmented epithelium and complex eyes. In both taxa, chemical maps reveal original anatomical details not apparent in visible light, including potential evidence of other sensory anatomy in Jamoytius. Our work resolves long-standing fundamental anatomical debates, indicating stem-group origins for bone and complex eyes in vertebrates. We highlight the potential of using a powerful combination of analytical techniques to unlock otherwise inaccessible data in problematic fossils.

Organic molecule stores solar energy for years, then releases it as heat on demand

When the sun goes down, solar panels stop working. This is the fundamental hurdle of renewable energy: how to save the sun’s power for a rainy day—or a cold night. Chemists at UC Santa Barbara have developed a solution that doesn’t require bulky batteries or electrical grids. In a paper published in the journal Science, Associate Professor Grace Han and her team detail a new material that captures sunlight, stores it within chemical bonds and releases it as heat on demand.

The material, a modified organic molecule called pyrimidone, is the latest advancement in molecular solar thermal (MOST) energy storage.

“The concept is reusable and recyclable,” said Han Nguyen, a doctoral student in the Han Group and the paper’s lead author.

Wavelength-resolved heterodimer [2 + 2] photocycloadditions for reversible surface grafting

🔥 New and HOT in Chemical Science!

“” by Kai Mundsinger (Queensland University of Technology, Australia), Christopher Barner-Kowollik (Queensland University of Technology, Australia and Karlsruhe Institute of Technology, Germany), et al.

Read it for free.

We report the first wavelength-dependent quantum yields of a [2 + 2] photocycloaddition generating the heterodimers of 7-hydroxycoumarin (7HCou) and styrene via a photochemical action plot. The wavelength-dependent heterodimer quantum yields are quantified at a constant number of photons at each wavelength between 310 and 370 nm. The resulting wavelength-dependent quantum yields demonstrate that the heterodimer is most efficiently generated at 345 nm, red-shifted by close to 25 nm compared to the absorption maximum of 7HCou at 320 nm. We subsequently translate these findings to photochemical surface functionalization by exploiting heterodimer formation between a surface bound coumarin derivative and para-styrene perfluoroalkyl ether (StyPFA) on surfaces under 345 nm irradiation to reversibly modulate surface hydrophobicity. The reversibility of the surface heterodimerization is demonstrated by removing StyPFA under UVC irradiation, and re-functionalization on the same surface. Functional heterodimer formation and the reversibility of the reaction on surface are followed via surface-sensitive X-ray photoelectron spectroscopy (XPS) and contact angle measurements. We subsequently apply our photochemical surface functionalization strategy to a dual cure photoresin based on a polyurethane-acrylate interpenetrating network, without deterioration of its mechanical properties, thereby confirming the feasibility of a photocycloaddition-based functionalization strategy for photoresins.

Quantum Calculations Boosted By Doubling Computational Space For Complex Molecules

Researchers have developed a new computational method, DOCI-QSCI-AFQMC, which accurately simulates complex molecular systems by effectively doubling the number of orbitals considered in standard quantum simulations and overcoming limitations of existing single-reference techniques, as demonstrated through successful modelling of chemical bonds and reactions.

New 3D printing ink uses 70% lignin and recycles with water

Additive manufacturing (AM) methods, such as 3D printing, enable the realization of objects with different geometric properties, by adding materials layer-by-layer to physically replicate a digital model. These methods are now widely used to rapidly create product prototypes, as well as components for vehicles, consumer goods and medical technologies.

A particularly effective AM technique, called direct ink writing (DIW), entails the 3D printing of objects at room temperature using inks with various formulations. Most of these inks are based on fossil-derived polymers, materials that are neither recyclable nor biodegradable. Recently introduced lignin-derived inks could be a more sustainable alternative. However, they typically need to be treated at high heat or undergo permanent chemical bonding processes to reliably support 3D printing. This prevents them from being re-utilized after objects are printed, limiting their sustainability.

A microfluidic chip monitors gases using integrated, motionless pumps

A new microscale gas chromatography system integrates all fluidic components into a single chip for the first time. The design leverages three Knudsen pumps that move gas molecules using heat differentials to eliminate the need for valves, according to a new University of Michigan Engineering study published in Microsystems & Nanoengineering. The monolithic gas sampling and analysis system, or monoGSA system for short, could offer reliable, low-cost monitoring for industrial chemical or pharmaceutical synthesis, natural gas pipelines, or even at-home air quality.

Gas chromatography has long been considered the gold standard for measuring and quantifying volatile organic compounds—gases emitted from industrial processes, fuels, household products and more. Recently, micro gas chromatography miniaturized the technology to briefcase-size or smaller, bringing gas analysis from the laboratory to the source.

Most micro gas chromatography systems use pumps and valves to move gas molecules from an input port to a preconcentrator, which extracts and concentrates samples, then from the preconcentrator to a column for chemical separation, and then to the detector and finally to an exhaust port. Up to this point, pumps and valves have been fabricated and assembled separately, which increases device size, assembly cost and risk of failure at connection points.

A New Way to Build 2D Materials Without Harsh Chemicals Pays Off Big

MXenes are an emerging class of two-dimensional materials whose properties depend sensitively on the atoms bound to their surfaces. A new synthesis approach now allows researchers to control these surface terminations with unprecedented precision. First identified in 2011, MXenes are a fast-expan

Scientific Notation Explained | Large & Small Numbers + Practice Questions

Scientific notation is a system developed to represent extremely large and extremely small numbers in a way that is easy to read, write, and understand. In chemistry and physics, many values such as the mass of an electron are too large or too small to be written conveniently in standard notation.

In this video, you will learn:

What scientific notation is and why it is used.
How to write numbers in the form a × 10ⁿ, where a is between 1 and 10
How to convert large numbers into scientific notation.
How to convert small numbers into scientific notation.

The LARS rule:
Left → Add to the exponent.
Right → Subtract from the exponent.

We also discuss how the direction of decimal movement affects the exponent and why the same rules apply to both very large and very small numbers.

📌 At the end of the video, you’ll find practice multiple-choice questions (MCQs) to test your understanding, including a real-life chemistry example involving the mass of an electron.

Continue reading “Scientific Notation Explained | Large & Small Numbers + Practice Questions” | >

Water-based electrolyte helps create safer and long-lasting Zn-Mn batteries

Many countries worldwide are increasingly investing in new infrastructure that enables the production of electricity from renewable energy sources, particularly wind and sunlight. To make the best of these energy solutions, one should also be able to reliably store the excess energy created during periods of intense sunlight or wind, so that it can be used later in times of need.

One promising type of battery for this purpose is based on zinc-manganese (Zn-Mn) and utilizes aqueous (i.e., water-based) electrodes instead of flammable organic electrolytes. These batteries rely on processes known as electrodeposition and dissolution, via which solid materials form and dissolve on electrodes as the battery is charging and discharging.

In Zn-Mn batteries, Zn serves as the anode (i.e., the electrode that releases electrons) and manganese dioxide (MnO₂) the cathode (i.e., the electrode from which electrons are gained). A key chemical reaction prompting their functioning, known as the MnO₂/Mn²⁺ conversion reaction, typically can only occur in acidic conditions.

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