Activation of B–C Bonds in [BArF₂₄]⁻ (BArF₂₄ = Tetrakis(3,5-bis(trifluoromethyl)phenyl)borate) By Gold(I) Compounds With 1,1′-bis(phosphino)metallocene Ligands

Author: Nataro, Chip ; Katz, Ava G. ; Roberts, Tyler J. ; Reinheimer, Eric W. ; Boggess, Anna E. ; Soika, Jennifer K.

Tetrakis(3,5-bis(trifluoromethyl)phenyl)borate ([BArF₂₄]^-) stabilizes reactive cations; however, compounds capable of activating a B-C bond in this anion exist.We investigated the catalytic activity of gold(I) compounds with bis(phosphino)metallocene ligands, [(AuCl)₂(μ-PP)] (PP = 1,1′-bis(diphenylphosphino)ferrocene (dppf), 1,1′-bis(diiso-propylphosphino)ferrocene (dippf), 1,1′-bis(dicyclohexylphosphino)ferrocene (dcpf), 1,1′-bis(ditert-butylphosphino)ferrocene (dtbpf), 1-diphenylphosphino-1′- ditert-butylphosphino-ferrocene (dppdtbpf), or 1,1′-bis(diphenylphosphino)ruthenocene (dppr)).These compounds displayed minimal catalytic activity unless Na[BArF₂₄] was added, though the active species remains unidentified.Reactions of Na[BArF₂₄] with [(AuCl)₂(μ-PP)] revealed [(AuCl)₂(μ-PP)] (PP = dppf, dippf, dcpf, dtbpf, or dppdtbpf), gave single products, [(AuAr^F)₂(μ-PP)] (Ar^F = 3,5-C₆H₃(CF₃)₂), by ³¹P{¹H} NMR spectroscopy.These were characterized, and X-ray structures of three compounds (PP = dppf, dippf, or dtbpf) were determinedFor dtbpf, an intermediate compound, [Au₂(μ-Ar^F)(μ-dtbpf)][BArF₂₄], was isolated and structurally characterized.The [(AuAr^F)₂(μ-PP)] and related [(AuPh)₂(μ-PP)] compounds were also prepared by the addition of RB(OH)₂ (R = Ar^F or Ph) to [(AuCl)₂(μ-PP)].X-ray structures of [(AuPh)₂(μ-PP)] (PP = dppf or dcpf) were determinedTheir electrochem. was investigated by cyclic voltammetry.The role of the ferrocenyl backbone of the ligands was examined by performing reactions in the presence of chem. oxidants.These reactions provide suggest a combination of the ferrocenyl backbone, the substituents on the phosphorus atoms, and the [B(aryl)₄]^- play significant roles in this chem.

22 Apr 2025·CHEMISTRY OF MATERIALS

Controlled Growth and Interconversion of Photoluminescent Metal–Organic Frameworks under High-Concentration Conditions

Author: Del Campo, Mark ; Musser, Andrew J. ; Bain, David C. ; Milner, Phillip J. ; Pitt, Tristan A.

A major drawback to the implementation of metal-organic frameworks (MOFs) on scale is the vast quantity of organic solvents, typically N,N-dimethylformamide (DMF), required to synthesize even small quantities of MOF under traditional dilute (∼0.01 M) solvothermal conditions.High-concentration solvothermal methods offer the opportunity to synthesize MOFs with minimal solvent use but are currently limited by a lack of understanding of how dynamic self-assembly operates under these conditions.Herein, we systematically investigate the crystallization of a series of MOFs under variable concentration (0.01-0.2 M) and temperature (80-160 °C) conditions based on the dilute synthesis of the canonical framework Mg₂(dobdc) (dobdc^4- = 2,5-dioxido-1,4-terephthalate).Through this anal., we identify controlling factors that lead to isolation of the highly photoluminescent phases Mg(DHT)(DMF)₂ (DHT = dihydroxyterephthalate) and CORN-MOF-1 (Mg) (CORN = Cornell University) or Mg₂(dobdc).Ultimately, we connect the preference for specific MOF phases to the extent of acid-catalyzed DMF hydrolysis and the competing influences of dimethylamine (Me₂NH) and formate (HCO₂^-) at high concentrations, which is likewise affected by temperature, pH, and solvent compositionWe use the insights gained to synthesize the Fe, Co, Ni, and Zn analogs of CORN-MOF-1 for the first time, as well as a second series of related MOFs, CORN-MOF-6 (M) (M = Mg, Mn, Fe, Co, Ni), based on the linker 2-hydroxyterephthalic acid (H₃hbdc).Both series exhibit tunable luminescence properties based on the metal composition and crystal structure, making them potentially useful materials for optoelectronic applications.Overall, this work contributes to a clearer understanding of the factors that control MOF formation under high-concentration conditions.

03 Mar 2025·MOLECULAR PHARMACEUTICS

Modulating the Physical Form of Mannitol Crystallizing in Frozen Solutions: The Role of Cosolute and Processing

Article

Author: Suryanarayanan, Raj ; Zeng, Chaowang ; Li, Jinghan ; Shi, Jiawanjun ; Munjal, Bhushan ; Bates, Simon

Mannitol is widely employed as a bulking agent in lyophilized formulations. Our goal was to evaluate the role of noncrystallizing cosolutes in inhibiting mannitol crystallization and preventing the formation of mannitol hemihydrate (MHH) in frozen solutions. The individual influence of two common stabilizers (sucrose and trehalose) and three model proteins (lysozyme, bovine serum albumin, and immunoglobulin G) on the crystallization behavior of mannitol was investigated by differential scanning calorimetry (DSC) and X-ray diffractometry (XRD). Sugars exerted a more pronounced crystallization inhibitory effect than proteins. In the presence of sugars, mannitol predominantly crystallized as MHH while the proteins facilitated the crystallization of δ-mannitol. Annealing the frozen solutions at -25 °C favored MHH crystallization. A higher annealing temperature of -10 °C accelerated mannitol crystallization and promoted the formation of the anhydrous δ-polymorph. The crystallization inhibitory effect of proteins was surmounted with annealing, while at a high sugar concentration, a substantial fraction of mannitol was retained amorphous even after annealing.

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22 Feb 2024

·www.sciencedaily.com

Chemists synthesize unique anticancer molecules using novel approach

Nearly 30 years ago, scientists discovered a unique class of anticancer molecules in a family of bryozoans, a phylum of marine invertebrates found in tropical waters. The chemical structures of these molecules, which consist of a dense, highly complex knot of oxidized rings and nitrogen atoms, has attracted the interest of organic chemists worldwide, who aimed to recreate these structures from scratch in the laboratory. However, despite considerable effort, it has remained an elusive task. Until now, that is. A team of chemists has succeeded in synthesizing eight of the compounds for the first time using an approach that combines inventive chemical strategy with the latest technology in small molecule structure determination. Nearly 30 years ago, scientists discovered a unique class of anticancer molecules in a family of bryozoans, a phylum of marine invertebrates found in tropical waters. The chemical structures of these molecules, which consist of a dense, highly complex knot of oxidized rings and nitrogen atoms, has attracted the interest of organic chemists worldwide, who aimed to recreate these structures from scratch in the laboratory. However, despite considerable effort, it has remained an elusive task. Until now, that is. A team of Yale chemists, writing in the journal Science, has succeeded in synthesizing eight of the compounds for the first time using an approach that combines inventive chemical strategy with the latest technology in small molecule structure determination. "These molecules have been an outstanding challenge in the field of synthetic chemistry," said Seth Herzon, the Milton Harris '29 Ph.D. Professor of Chemistry in Yale's Faculty of Arts and Sciences and corresponding author of the new study. "A number of research groups have tried to recreate these molecules in the lab, but their structures are so dense, so intricately connected, that it hasn't been possible. I've been reading about efforts to synthesize these compounds since I was a graduate student in the early 2000s." In nature, the molecules are found in some species of bryozoa -- small, aquatic animals that feed by filtering prey from the water via tiny tentacles. Researchers worldwide consider bryozoans to be a potentially valuable source of new medications, and many molecules isolated from bryozoans have been studied as novel anticancer agents. However, the complexity of the molecules often limits their further development. Herzon's team looked at a particular species of bryozoa called Securiflustra securifrons. "We worked on these molecules about a decade ago, and though we were not successful in recreating them at that time, we gleaned insight into their structure and chemical reactivity, which informed our thinking," Herzon said. The new approach involved three key strategic elements. First, Herzon and his team avoided constructing a reactive heterocyclic ring, known as an indole, until the end of the process. A heterocyclic ring contains two or more elements -- and this specific ring is known to be reactive and create problems, Herzon said. Second, the researchers used methods known as oxidative photocyclizations to construct some of the key bonds in the molecules. One of these photocyclizations involved the reaction of a heterocycle with molecular oxygen, which was first studied by Yale's Harry Wasserman in the 1960s. Lastly, Herzon and his team employed microcrystal electron diffraction (MicroED) analysis to help visualize the structure of the molecules. Herzon said conventional methods for structure determination were inadequate in this context. The result of the new approach is eight new synthetic molecules with therapeutic potential -- and the promise of more new chemistry to come. "These molecules hit right at my love of complex synthetic challenges," said Herzon, who is also a member of the Yale Cancer Center and holds joint appointments in pharmacology and therapeutic radiology at Yale School of Medicine. "On a molecular weight basis, they are modest relative to other molecules we've studied in my lab. But from the vantage point of chemical reactivity, they present some of the greatest challenges we've ever taken on." Co-first authors of the new study are Yale chemistry graduate students Brandon Alexander and Noah Bartfield. Co-authors are Vaani Gupta, a Yale chemistry graduate student; Brandon Mercado, a Yale X-ray crystallographer and lecturer in the Department of Chemistry; and Mark Del Campo of Rigaku Americas Corporation. The National Science Foundation helped fund the research.

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