The Reaction of Peroxynitrite with Morpholine (Secondary Amines) Revisited: The Overlooked Hydroxylamine Formation

The reaction of peroxynitrite/peroxynitrous acid with morpholine as a model compound for secondary amines is reinvestigated in the absence and presence of carbon dioxide. The concentration‐ and pH‐dependent formation of N‐nitrosomorpholine and N‐nitromorpholine as reported in three previous papers ([25] [26] [14]) is basically confirmed. However, ¹³C‐NMR spectroscopic product analysis shows that, in the absence of CO₂, N‐hydroxymorpholine is, at pH ≥ 7, the major product of this reaction, even under anaerobic conditions. The formation of N‐hydroxymorpholine has been overlooked in the three cited papers. Additional (ring‐opened) oxidation products of morpholine are also detected. The data account for radical pathways for the formation of these products via intermediate morpholine‐derived aminyl and α‐aminoalkyl radicals. This is further supported by EPR‐spectrometric detection of morpholine‐derived nitroxide radicals, i.e., morpholin‐4‐yloxy radicals. N‐Nitrosomorpholine, however, is very likely formed by electrophilic attack of peroxynitrite‐derived N₂O₄. ¹⁵N‐CIDNP Experiments establish that, in the presence of CO₂, N‐nitro‐ and C‐nitromorpholine are generated by radical recombination. The present results are in full accord with a fractional (28 ± 2%) homolytic decay of peroxynitrite/peroxynitrous acid with release of free hydroxyl and nitrogen dioxide radicals.     

Nickel and zinc complexes with a monodentate heterocycle and tridentate Schiff base ligands: self‐assembly to one‐ and two‐dimensional supramolecular networks via hydrogen bonding

In the complex (morpholine)[2‐hydroxy‐N′‐(5‐nitro‐2‐oxidobenzylidene)benzohydrazidato]nickel(II), [Ni(C₁₄H₉N₃O₅)(C₄H₉NO)], (I), the Ni^II center is in a square‐planar N₂O₂ coordination geometry. The complex bis[μ‐2‐hydroxy‐N′‐(2‐oxidobenzylidene)benzohydrazidato]bis[(morpholine)zinc(II)], [Zn₂(C₁₄H₁₀N₂O₃)₂(C₄H₉NO)₂], (II), consists of a neutral centrosymmetric dimer with a coplanar Zn₂(μ₂‐O)₂ core. The two Zn^II centers are bridged by phenolate O atoms. Each Zn^II center exhibits a distorted square‐pyramidal stereochemistry, in which the four in‐plane donors come from the O,N,O′‐tridentate 2‐hydroxy‐N′‐(2‐oxidobenzylidene)benzohydrazidate(2−) ligand and a symmetry‐related phenolate O atom, and the axial position is coordinated to the N atom from the morpholine molecule. There are intramolecular phenol–hydrazide O—H...N hydrogen bonds present in both (I) and (II). In (I), square‐planar nickel complexes are linked by intermolecular morpholine–morpholine N—H...O hydrogen bonds, leading to a one‐dimensional chain, while in (II) an infinite two‐dimensional network is formed via intermolecular hydrogen bonds between the coordinated morpholine NH groups and the uncoordinated phenolate O atoms.     

Nitric oxide reduction forming hyponitrite triggered by metal-containing complexes

Nitric oxide reduction yielding N₂O is known as a route to detoxify nitric oxide (NO) to relieve nitrosative stress in pathogenic bacteria and fungi. Nitric oxide enzymes are classified into Cu/Fe-heme NO reductases (NORs) and non-heme flavindiiron NO reductases (FNORs). In biological system, the mechanism of NO reduction generating N₂O was proposed to involve NO coordination to metal centers prior to producing cis/trans-hyponitrite-bound intermediate, and the subsequent protonation of hyponitrite-bound-Fe/Cu intermediates releases N₂O. In this review article, we compile the recently published biomimetic model studies of NO-to-[N₂O₂]²⁻ transformation triggered by the designed transition-metal complexes. In biomimetic model study, the ON-NO bond coupling of metal-nitrosyl complexes yielding [N₂O₂]²⁻-bound species may occur via either the inter/intramolecular radical-[NO]⁻-radical-[NO]⁻ coupling or metal-[NO]²⁻ radical coupling with exogenous NO˙. The H-bonding interaction between hyponitrite and protic solvents promoting/stabilizing the formation of hyponitrite complexes was also demonstrated. In addition, the electronic structure of the designed transition-metal-nitrosyl complexes triggering the formation of [N₂O₂]²⁻-bound species and the detailed NO-to-[N₂O₂]²⁻ formation pathways were delineated.     

Molybdate Sulfuric Acid/NaNO2: A Novel Heterogeneous System for the N‐Nitrosation of Secondary Amines under Mild Conditions

Wet molybdate sulfuric acid (= dioxo[bis(sulfato‐κO)]molybdenum; MSA), a new solid acid, can be used in combination with sodium nitrite (NaNO₂) to transform a variety of secondary amines to the corresponding N‐nitroso compounds under mild, heterogeneous conditions (Table). The process has several advantages: the reagents are inexpensive and non‐hazardous, the reaction is clean, fast, and high‐yielding, and MSA can be readily removed by filtration and re‐used (after treatment with HCl) without loss of activity. Further, only N‐nitrosation was observed, but no C‐ or O‐nitrosation.     

Transformation of the {Fe(NO)2}9 dinitrosyl iron complexes (DNICs) into S-nitrosothiols (RSNOs) triggered by acid-base pairs

S‐Nitrosation of the coordinated thiolate of dinitrosyl iron complexes (DNICs) to generate S‐nitrosothiols (RSNOs) was demonstrated. Transformation of [{(NO)₂Fe(μ‐StBu)}₂] ( 1‐tBuS ) into the {Fe(NO)₂}⁹ DNIC [(NO)₂Fe(StBu)(MeIm)] ( 2‐MeIm ) occurs under addition of 20 equiv of 1‐methylimidazole (MeIm) into a solution of 1‐tBuS in THF. The dynamic interconversion between {Fe(NO)₂}⁹ [(NO)₂Fe(S‐NAP)(dmso)] ( 2‐dmso ) (NAP=N‐acetyl‐D ‐penicillamine) and [{(NO)₂Fe(μ‐S‐NAP)}₂] ( 1‐NAP ) was also observed in a solution of complex 1‐NAP in DMSO. In contrast to the reaction of complex 2‐MeIm and bis(dimethylthiocarbamoyl) disulfide ((DTC)₂) to yield {Fe(NO)}⁷ [(NO)Fe(DTC)₂] ( 3 ) (DTC=S₂CNMe₂) accompanied by (tBuS)₂ and NO_(g), transformation of {Fe(NO)₂}⁹ 2‐MeIm ( 2‐dmso ) into RSNOs (RS=tBuS, NAP‐S) along with complex 3 induced by the Brønsted acid solution of (DTC)₂ demonstrated that Brønsted acid may play a critical role in triggering S‐nitrosation of the coordinated thiolate of DNICs 2‐MeIm (or 2‐dmso ) to produce RSNOs. That is, DNIC‐mediated S‐nitrosation requires a Brønsted acid–Lewis base pair to produce RSNO. Transformation of DNICs into RSNOs may only occur on the one‐thiolate‐containing {Fe(NO)₂}⁹ DNICs, in contrast to protonation of the two‐thiolate‐containing DNICs [(NO)₂Fe(SR)₂]^? by Brønsted acid to yield [{(NO)₂Fe(μ‐SR)}₂]. These results might rationalize that the known protein‐Cys‐SNO sites derived from DNICs were located adjacent to acid and base motifs, and no protein‐bound SNO characterized to date has been directly derived from [protein–(cysteine)₂Fe(NO)₂] in biology.     

Unexpected reactions associated with the xanthate‐mediated polymerization of N‐vinylpyrrolidone

The monomer N‐vinylpyrrolidone (NVP) undergoes side reactions in the presence of R group functional xanthates and impurities. The fate of the monomer NVP and a selection of six O‐ethyl xanthates during xanthate‐mediated polymerization were studied via NMR spectroscopy. A high number of by‐products were identified. Significant side reactions affecting NVP include the formation of an unsaturated dimer and hydration products in bulk or in solution in C₆D₆. In addition, the xanthate adjacent to a NVP unit was found to undergo elimination at moderate temperature (60–70 °C), resulting in unsaturated species and the formation of new xanthate species. The presence of the chlorinated compound α‐chlorophenyl acetic acid, ethyl ester, a precursor in the synthesis of the xanthate S‐(2‐ethyl phenylacetate) O‐ethyl xanthate, resulted in a dramatic increase in the rate of side reactions such as unsaturated dimer formation and a high ratio of unsaturated chain ends. The conditions for the occurrence of such side reactions are discussed in this article, with relevance to increasing the control over the polymerization kinetics, endgroup functionality, and control over the molar mass distribution. © 2008 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 46: 6575–6593, 2008     

Structure–Function Relationships of New Lipids Designed for DNA Transfection

Cationic liposome/DNA complexes can be used as nonviral vectors for direct delivery of DNA‐based biopharmaceuticals to damaged cells and tissues. To obtain more effective and safer liposome‐based gene transfection systems, two cationic lipids with identical head groups but different chain structures are investigated with respect to their in vitro gene‐transfer activity, their cell‐damaging characteristics, and their physicochemical properties. The gene‐transfer activities of the two lipids are very different. Differential scanning calorimetry and synchrotron small‐ and wide‐angle X‐ray scattering give valuable structural insight. A subgel‐like structure with high packing density and high phase‐transition temperature from gel to liquid‐crystalline state are found for lipid 7 (N′‐2‐[(2,6‐diamino‐1‐oxohexyl)amino]ethyl‐2,N‐bis(hexadecyl)propanediamide) containing two saturated chains. Additionally, an ordered head‐group lattice based on formation of a hydrogen‐bond network is present. In contrast, lipid 8 (N′‐2‐[(2,6‐diamino‐1‐oxohexyl)amino]ethyl‐2‐hexadecyl‐N‐[(9Z)‐octadec‐9‐enyl]propanediamide) with one unsaturated and one saturated chain shows a lower phase‐transition temperature and a reduced packing density. These properties enhance incorporation of the helper lipid cholesterol needed for gene transfection. Both lipids, either pure or in mixtures with cholesterol, form lamellar phases, which are preserved after addition of DNA. However, the system separates into phases containing DNA and phases without DNA. On increasing the temperature, DNA is released and only a lipid phase without intercalated DNA strands is observed. The conversion temperatures are very different in the two systems studied. The important parameter seems to be the charge density of the lipid membranes, which is a result of different solubility of cholesterol in the two lipid membranes. Therefore, different binding affinities of the DNA to the lipid mixtures are achieved.     

Crystal Structure Analysis of the Repair of Iron Centers Protein YtfE and Its Interaction with NO

Molecular mechanisms underlying the repair of nitrosylated [Fe–S] clusters by the microbial protein YtfE remain poorly understood. The X‐ray crystal structure of YtfE, in combination with EPR, magnetic circular dichroism (MCD), UV, and ¹⁷O‐labeling electron spin echo envelope modulation measurements, show that each iron of the oxo‐bridged Fe^II–Fe^III diiron core is coordinatively unsaturated with each iron bound to two bridging carboxylates and two terminal histidines in addition to an oxo‐bridge. Structural analysis reveals that there are two solvent‐accessible tunnels, both of which converge to the diiron center and are critical for capturing substrates. The reactivity of the reduced‐form Fe^II–Fe^II YtfE toward nitric oxide demonstrates that the prerequisite for N₂O production requires the two iron sites to be nitrosylated simultaneously. Specifically, the nitrosylation of the two iron sites prior to their reductive coupling to produce N₂O is cooperative. This result suggests that, in addition to any repair of iron centers (RIC) activity, YtfE acts as an NO‐trapping scavenger to promote the NO to N₂O transformation under low NO flux, which precedes nitrosative stress.     

Conversion of Nitric Oxide into Nitrous Oxide as Triggered by the Polarization of Coordinated NO by Hydrogen Bonding

Reduction of the {Co(NO)}⁸ cobalt–nitrosyl N‐confused porphyrin (NCP) [Co(CTPPMe)(NO)] ( 1 ) produced electron‐rich {Co(NO)}⁹ [Co(CTPPMe)(NO)][Co(Cp*)₂] ( 2 ), which was necessary for NO‐to‐N₂O conversion. Complex 2 was NO‐reduction‐silent in neat THF, but was partially activated to a hydrogen‐bonded species 2 ??? MeOH in THF/MeOH (1:1, v/v). This species coupling with 2 transformed NO into N₂O, which was fragmented from an [N₂O₂]‐bridging intermediate. An intense IR peak at 1622 cm^?1 was ascribed to ν(NO) in an [N₂O₂]‐containing intermediate. Time–course ESI(?) mass spectra supported the presence of the dimeric [Co(NCP)]₂(N₂O₂) intermediate. Five complete NO‐to‐N₂O conversion cycles were possible without significant decay in the amount of N₂O produced.     

Formation of the Distinct Redox‐Interrelated Forms of Nitric Oxide from Reaction of Dinitrosyl Iron Complexes (DNICs) and Substitution Ligands

Release of the distinct NO redox‐interrelated forms (NO⁺, ^.NO, and HNO/NO^?), derived from reaction of the dinitrosyl iron complex (DNIC) [(NO)₂Fe(C₁₂H₈N)₂]^? ( 1 ) (C₁₂H₈N=carbazolate) and the substitution ligands (S₂CNMe₂)₂, [SC₆H₄‐o‐NHC(O)(C₅H₄N)]₂ ((PyPepS)₂), and P(C₆H₃‐3‐SiMe₃‐2‐SH)₃ ([P(SH)₃]), respectively, was demonstrated. In contrast to the reaction of (PyPepS)₂ and DNIC 1 in a 1:1 stoichiometry that induces the release of an NO radical and the formation of complex [PPN][Fe(PyPepS)₂] ( 4 ), the incoming substitution ligand (S₂CNMe₂)₂ triggered the transformation of DNIC 1 into complex [(NO)Fe(S₂CNMe₂)₂] ( 2 ) along with N‐nitrosocarbazole ( 3 ). The subsequent nitrosation of N‐acetylpenicillamine (NAP) by N‐nitrosocarbazole ( 3 ) to produce S‐nitroso‐N‐acetylpenicillamine (SNAP) may signify the possible formation pathway of S‐nitrosothiols from DNICs by means of transnitrosation of N‐nitrosamines. Protonation of DNIC 1 by [P(SH)₃] triggers the release of HNO and the generation of complex [PPN][Fe(NO)P(C₆H₃‐3‐SiMe₃‐2‐S)₃] ( 5 ). In a similar fashion, the nucleophilic attack of the chelating ligand P(C₆H₃‐3‐SiMe₃‐2‐SNa)₃ ([P(SNa)₃]) on DNIC 1 resulted in the direct release of [NO]^? captured by [(¹⁵NO)Fe(SPh)₃]^?, thus leading to [(¹⁵NO)(¹⁴NO)Fe(SPh)₂]^?. These results illustrate one aspect of how the incoming substitution ligands ((S₂CNMe₂)₂ vs. (PyPepS)₂ vs. [P(SH)₃]/[P(SNa)₃]) in cooperation with the carbazolate‐coordinated ligands of DNIC 1 function to control the release of NO⁺, ^.NO, or [NO]^? from DNIC 1 upon reaction of complex 1 and the substitution ligands. Also, these results signify that DNICs may act as an intermediary of NO in the redox signaling processes by providing the distinct redox‐interrelated forms of NO to interact with different NO‐responsive targets in biological systems.     

Phenol Photonitration and Photonitrosation upon Nitrite Photolysis in basic solution

Nitrophenols have been detected in some Antarctic lakes, the water of which is basic and rich in nitrate, nitrite and other nutrients. Nitrate or nitrite photolysis could be a possible reaction to explain the presence of these compounds. This work presents evidence for the formation of 2-nitrophenol (2NP), 4-nitrophenol (4NP) and 4-nitrosophenol (4NOP) upon UV irradiation of phenol and nitrite in aerated basic solutions.

The pH dependence of the 2NP initial formation rate is different from those of 4NP and 4NOP. The dependence of the first mainly reflects the phenol/phenolate equilibrium, with phenol yielding 2NP at a higher rate than phenolate. In the case of 4NOP, the initial formation rate vs pH has a maximum at pH 9.5. The pH dependence of 4NOP formation rate suggests that three pathways are likely to operate: nitrosation of undissociated phenol by N₂O₃, prevailing at pH<8.7, nitrosation of phenolate by N₂O₃, prevailing in the pH interval 8.7–10.8, and reaction between phenoxyl radical and ^?NO, prevailing at pH>10.8. Phenol nitrosation by N₂O₃ is favoured when phenol is negatively charged (phenolate), but it is also disfavoured at alkaline pH values, owing to the depletion of N₂O₃ (the nitrosating agent) by basic hydrolysis. Differently from 2NP, the initial formation rate vs pH of 4NP is very similar to that of 4NOP, suggesting that 4NP may originate from the oxidation of 4NOP. Moreover, while in neutral and acidic solutions the formation rate of 2NP is slightly higher than that of 4NP, in the pH interval 8–12 the formation of 4NP is much more rapid than that of 2NP. This indicates that the pH of natural waters influences the ratio of nitroisomers.     

Elementary reaction step model of the N‐nitrosation of ammonia

This contribution develops a comprehensive kinetic model of the N-nitrosation reaction mechanism, consisting almost entirely of elementary reaction steps and applies it to study the nitrosation of ammonia. The reaction mechanism features 26 species and 22 reactions, with 8 parallel reaction pathways for ammonia nitrosation and a side pathway for nitrous acid decomposition. We compiled forward and reverse rate constants for each of the reactions, either from the literature sources or by correlation with known rate and equilibrium constants. The concentration of each reaction species with respect to time can be obtained for any set of initial concentrations by invoking a simultaneous solution to the system of ordinary differential equations describing the reaction mechanism. The model successfully predicts previous experimental results for ammonia nitrosation, with and without the addition of the catalyst thiocyanate. The effect of pH on the rate and mechanism of ammonia nitrosation was studied with the model. For uncatalyzed nitrosation, the results indicate that between pH 6.0 and 1.5 the reaction proceeds predominantly via reaction with N₂O₃, whereas ON⁺ nitrosation becomes the preferred pathway below pH 1.5. ONSCN is the dominant nitrosating agent across the entire pH range studied when the nucleophile thiocyanate was added in appreciable quantities. However, with the weak nucleophile Cl⁻, nitrosation by N₂O₃ and ON⁺ governed the reaction kinetics at high and low pH, respectively. We demonstrate that nitrosating agent formation is rapid and does not limit the rate of ammonia nitrosation; however, nitrosating agent formation could become the rate-limiting step for the nitrosation of highly reactive substrates. © 2007 Wiley Periodicals, Inc. Int J Chem Kinet 39: 645–656, 2007     

Synthesis of N4‐substituted[1,3,4]oxadiazinan‐2‐ones derived from norephedrine

[1,3,4]‐Oxadiazinan‐2‐ones bearing substitution at the N₄‐position have been synthesized from norephedrine in good yield via N‐alkylation, nitrosation, reduction and cyclization.     

Bis‐Bromine‐1,4‐Diazabicyclo[2.2.2]Octane (Br2‐DABCO) as an Efficient Promoter for One‐Pot Conversion of N‐Arylglycines to N‐Arylsydnones in the Presence of NaNO2/Ac2O Under Neutral Conditions

Bis‐Bromin‐1,4‐diazabicyclo[2.2.2]octane (Br₂‐DABCO)‐promoted one‐pot conversion of various N‐arylglycines to sydnones using a combination of NaNO₂ and Ac₂O has been achieved efficiently through N‐nitrosation followed by cyclization in high yields (90‐96%) under mild and neutral conditions.     

Electroanalytical Determination of N‐Nitrosamines in Aqueous Solution Using a Boron‐Doped Diamond Electrode

The electrochemical methods cyclic and square‐wave voltammetry were applied to develop an electroanalytical procedure for the determination of N‐nitrosamines (N‐nitrosopyrrolidine, N‐nitrosopiperidine and N‐nitrosodiethylamine) in aqueous solutions. Cyclic voltammetry was used to evaluate the electrochemical behaviors of N‐nitrosamines on boron‐doped diamond electrodes. It was observed an irreversible electrooxidation peak located in approximately 1.8 V (vs. Ag/AgCl) for both N‐nitrosamines. The optimal electrochemical response was obtained using the following square‐wave voltammetry parameters: f=250 Hz, E_sw=50 mV and E_s=2 mV using a Britton–Robinson buffer solution as electrolyte (pH 2). The detection and quantification limits determined for total N‐nitrosamines were 6.0×10^?8 and 2.0×10^?7 mol L^?1, respectively.     

Kinetic studies on the formation of N-nitroso compounds

Acetic acid/acetate ion buffer acts catalytically upon the nitrosation of amines under conditions in which the only nitrosating agents are N₂O₃ and NOBr, but inhibits nitrosation by H₂NO ₂ ⁺ . The kinetic characteristics of these phenomena have been analysed quantitatively and compared with similar effects caused by the solventsTHF, DMSO and dioxane. The experimental results show that this behaviour is an effect of the medium.

---

Kinetische Untersuchungen zur Bildung von N-Nitroso-Verbindungen, 8. Mitt.: Nachweis eines Medium-Effekts von Essigsäure/Acetat-Puffer auf die Geschwindigkeitskonstante der Nitrosierung

Zusammenfassung Essigsäure/Acetat-Puffer wirkt bei der Nitrosierung von Aminen katalytisch, unter Bedingungen, wo die alleinigen nitrosierenden Agentien N₂O₃ und NOBr sind; andererseits wird die Nitrosierung durch H₂NO ₂ ⁺ unterbunden. Die kinetischen Charakteristika dieses Phänomens wurden quantitativ analysiert und mit ähnlichen Effekten der LösungsmittelTHF, DMSO und Dioxan verglichen. Die experimentellen Ergebnisse zeigen, daß dieses Verhalten auf einen Mediumeffekt zurückzuführen ist.

     

Two (Z)‐N‐aryl‐3‐benzylideneisoindolin‐1‐ones

Two isoindolin‐1‐one derivatives, (Z)‐3‐benzyl­idene‐N‐phenyl­isoindolin‐1‐one, C₂₁H₁₅NO, (II), and (Z)‐3‐benzyl­idene‐N‐(4‐methoxy­phenyl)­isoindolin‐1‐one, C₂₂H₁₇NO₂, (III), were synthesized by the palladium‐catalysed heteroannulation. The mol­ecules of both compounds have a Z configuration. The interplanar angles between the five‐ and six‐membered rings of the isoindolinone moiety in (II) and (III) are 1.66 (11) and 2.26 (7)°, respectively. The phenyl rings at the N‐position in (II) and (III) are twisted out of the C₄N ring plane by 62.77 (11) and 67.10 (7)°, respectively. The substitutions at the N and C‐3 positions of the isoindolinone system have little influence on the molecular dimensions of the resulting compounds.     

Structural and Magnetic Study of N2, NO,NO2, and SO2 Adsorbed within a Flexible Single‐Crystal Adsorbent of [Rh2(bza)4(pyz)]n

The crystalline one‐dimensional compound, [Rh^II₂(bza)₄(pyz)]_n ( 1 ) (bza=benzoate, pyz=pyrazine) demonstrates gas adsorbency for N₂, NO, NO₂, and SO₂. These gas‐inclusion crystal structures were characterized by single‐crystal X‐ray crystallography as 1 ?1.5 N₂ (298 K), 1 ?2.5 N₂ (90 K), and 1 ?1.95 NO (90 K) under forcible adsorption conditions and 1 ?2 NO₂ (90 K) and 1 ?3 SO₂ (90 K) under ambient pressure. Crystal‐phase transition to the P space group that correlates with gas adsorption was observed under N₂, NO, and SO₂ conditions. The C2/c space group was observed under NO₂ conditions without phase transition. All adsorbed gases were stabilized by the host lattice. In the N₂, NO, and SO₂ inclusion crystals at 90 K, short interatomic distances within van der Waals contacts were found among the neighboring guest molecules along the channel. The adsorbed NO molecules generated the trans‐NO???NO associated dimer with short intermolecular contacts but without the conventional chemical bond. The magnetic susceptibility of the NO inclusion crystal indicated antiferromagnetic interaction between the NO molecules and paramagnetism arising from the NO monomer. The NO₂ inclusion crystal structure revealed that the gas molecules were adsorbed in the crystal in dimeric form, N₂O₄.     

Synthesis,structure and biological activity of four new picolinohydrazonamide derivatives

Four new picolinohydrazonamide derivatives, namely, 6‐methyl‐N′‐(morpholine‐4‐carbonothioyl)picolinohydrazonamide, C₁₂H₁₇N₅OS, 6‐chloro‐N′‐(morpholine‐4‐carbonothioyl)picolinohydrazonamide methanol monosolvate, C₁₁H₁₄ClN₅OS·CH₃OH, 6‐chloro‐N′‐(4‐phenylpiperazine‐1‐carbonothioyl)picolinohydrazonamide, C₁₇H₁₉ClN₆S, and 6‐chloropicolinohydrazonamide, C₆H₇ClN₄, have been synthesized and characterized by NMR spectroscopy and single‐crystal low‐temperature X‐ray diffraction. In addition, their antibacterial and anti‐yeast activities have been determined. The first three compounds adopt the zwitterionic form in the crystal structure regardless of the presence or absence of solvent molecules in the structure. They also adopt the same symmetry, i.e. P2₁/c (P2₁/n), unlike the fourth structure which is chiral and has the space group P2₁2₁2₁. For all the studied cases, intermolecular N—H…O and N—H…N hydrogen bonds play an essential role in the formation of the structures.     

Models for potential dendritic nitric oxide donors: crystal structures of two 2‐nitroanilino precursors and nitric oxide‐release behavior of the nitrosated derivatives

Two molecular precursors to dendrimeric materials that could serve as slow and sustained NO‐releasing therapeutic agents have been synthesized and characterized. N¹,N⁴‐Bis(2‐nitrophenyl)butane‐1,4‐diamine, C₁₆H₁₈N₄O₄, (I), crystallizes in a lattice with equal populations of two molecules of different conformations, both of which possess inversion symmetry through the central C—C bond. One molecule has exclusively anti conformations along the butyl chain, while the other has a gauche conformation of the substituents on the first C—C bond. N²,N²‐Bis[2‐(2‐nitroanilino)ethyl]‐N¹‐(2‐nitrophenyl)ethane‐1,2‐diamine, C₂₄H₂₇N₇O₆, (II), crystallizes with one unique molecule in the asymmetric unit. Neighboring pairs of molecules are linked into dimers via N—H…O amine–nitro hydrogen bonds. The dimers are assembled into layers that stack in an A–B–A–B sequence such that the repeat distance in the stacking direction is over 46 Å. Molecular NO‐release agents N¹,N⁴‐bis(2‐nitrophenyl)‐N¹,N⁴‐dinitrosobutane‐1,4‐diamine, C₁₆H₁₆N₆O₆, (III), and N¹‐(2‐nitrophenyl)‐N²,N²‐bis{2‐[(2‐nitrophenyl)(nitroso)amino]ethyl}‐N¹‐nitrosoethane‐1,2‐diamine, C₂₄H₂₄N₁₀O₉, (IV), were prepared via treatment of (I) and (II), respectively, with NaNO₂ and acetic acid. The release of NO from solid‐phase samples of (III) and (IV) suspended in phosphate buffer was monitored spectroscopically over a period of 21 days. Although (IV) released a greater amount of NO, as expected due to it having three NO moieties for every two in (III), the (IV):(III) ratio of the rate and extent of NO release was significantly less than 1.5:1, suggesting that some combination of electronic, chemical, and/or steric factors may be affecting the release process.