Trackable spheres of similar size to those typically used for sustained protein delivery are prepared by incorporating superparamagnetic iron oxide (SPIO) nanoparticles into the core of poly(lactide‐co‐glycolide) microspheres. The visibility of injections in static and temporally in dynamic tissue systems is demonstrated. This method improves upon other, less sensitive imaging modalities in their ability to track injectable delivery systems. The results obtained confirm the localization of microspheres to the injected target area and highlight the novelty of tracking delivery vehicles for other applications.
The kinetics of the reaction of molecular oxygen with hydroperoxyalkyl radicals have been studied theoretically. These reactions, often referred to as second O(2) addition, or O(2) + QOOH reactions, are believed to be responsible for low-temperature chain branching in hydrocarbon oxidation. The O(2) + propyl system was chosen as a model system. High-level ab initio calculations of the C(3)H(7)O(2) and C(3)H(7)O(4) potential energy surfaces are coupled with RRKM master equation methods to compute the temperature and pressure dependence of the rate coefficients. Variable reaction coordinate transition-state theory is used to characterize the barrierless transition states for the O(2) + QOOH addition reactions as well as subsequent C(3)H(6)O(3) dissociation reactions. A simple kinetic mechanism is developed to illustrate the conditions under which the second O(2) addition increases the number of radicals. The sequential reactions O(2) + QOOH → OOQOOH → OH + keto-hydroperoxide → OH + OH + oxy-radical and the corresponding formally direct (or well skipping) reaction O(2) + QOOH → OH + OH + oxy-radical increase the total number of radicals. Chain branching through this reaction is maximized in the temperature range 600-900 K for pressures between 0.1 and 10 atm. The results confirm that n-propyl is the smallest alkyl radical to exhibit the low-temperature combustion properties of larger alkyl radicals, but n-butyl is perhaps a truer combustion archetype. 相似文献
Granular media are frequently found in nature and in industry and their transport by a fluid flow is of great importance to human activities. One case of particular interest is the transport of sand in open-channel and river flows. In many instances, the shear stresses exerted by the fluid flow are bounded to certain limits and some grains are entrained as bed-load: a mobile layer which stays in contact with the fixed part of the granular bed. Under these conditions, an initially flat granular bed may be unstable, generating ripples and dunes such as those observed on the bed of rivers. In free-surface water flows, dunes are bedforms that scale with the flow depth, while ripples do not scale with it. This article presents a model for the formation of ripples and dunes based on the proposition that ripples are primary linear instabilities and that dunes are secondary instabilities formed from the competition between the coalescence of ripples and free surface effects. Although simple, the model is able to explain the growth of ripples, their saturation (not explained in previous models) and the evolution from ripples to dunes, presenting a complete picture for the formation of dunes. 相似文献
The crystal structure of 2-[(phenylamino) methyl]-isoindole-1,3-dione, C15H12N2O2, crystallizes in the triclinic space group Pī with cell parameters of a = 7.1176 (2) ?, b = 8.5533 (3) ?, c = 10.9163 (4) ?, α = 95.937 (2)°, β = 102.975 (2)°, γ = 108.474 (2)°, V = 603.18 (4) ?3 and Z = 2. This indole derivative is a Mannich base in which a methyl group bridges the molecules of phthalimide and aniline molecules.
The dihedral angle between the phthalimide and aniline is 75.47 (3)°. The molecules of the title compound forms a centrosymmetric
hydrogen-bonded dimer through a pair of N–H···O hydrogen bonds. C–H···π and an extensive π···π interactions, in addition,
stabilize the molecular structure. The compound presented here is V-shaped, the angle at the methyl bridge [N–C–N] being 115.04
(12)°. Present study reports the conformation and hydrogen bonding interactions which play an important role in biological
functions. Vibration analysis complement the structure analysed. 相似文献
In the emerging field of biomolecular design, the introduction of metal-binding sites into loop or turn regions of known protein scaffolds has been utilized to create unique metalloprotein and metallopeptide systems for study. This Forum Article highlights examples of the modular-turn-substitution approach to design and the range of structural and mechanistic questions to which this tool can be applied. Examples from the authors' laboratory are given to show that lanthanide-binding metallopeptides, and now a full metallohomeodomain, can be generated by modular substitution of a Ca-binding EF-hand loop into the unrelated scaffold, the engrailed helix-turn-helix motif. We have previously shown that these peptides bind trivalent Ln(III) ions and promote DNA and phosphate hydrolysis, the targeted function. Here, a series of chimeric peptides are presented that differ only in the ninth loop position [given in parentheses; Peptides P3N (Asn), P3E (Glu), P3A (Ala), and P3W(D) (Asp]. This residue, a putative second-shell ligand stabilizing a coordinated water, was found to influence not only metal affinity but also peptide folding. The affinity for Tb(III) was determined by Trp-Tb fluorescence resonance energy transfer and followed the order Ka = P3W(D) > P3A approximately P3E > P3N. However, circular dichroism (CD) titrations with EuCl3 showed that only P3W(D) and P3N folded to any extent upon metal binding, indicating that the Asp/Asn side chains stabilize the central loop structure and thus propagate folding of the peripheral helices, whereas neither Ala nor Glu appears to be interacting with the metal to organize the loop. Finally, we investigated the longer range context of a given loop substitution by cloning and expressing a lanthanide-binding homeodomain (C2), whose loop insertion sequence is analogous to that of peptide P3W(D). We find by CD that apo-C2 has a significant helical structure (approximately 25% alphahelicity), which increases further upon the addition of Tb(III) (approximately 32% alpha helicity). The protein's Tb(III) affinity is similar to that of the chimeric peptides. However, unlike previously reported metallopeptides, we find that EuC2 does not appreciably promote phosphate or DNA cleavage, which suggests a difference in metal accessibility in the context of the full domain. We have demonstrated that substituting beta turns with metal-binding turns does not necessarily require homologous parental scaffolds or small flexible peptides but rather relies on the structural similarity of the motifs flanking the turn. 相似文献
A concise total asymmetric synthesis of the tetrahydronaphthyridine alkaloid (-)-normalindine has been accomplished via the addition of a laterally metalated 4-methyl-3-cyanopyridine to a sulfinimine (N-sulfinyl imine) as the key step. 相似文献
This account reviews our efforts over the past 37 years to understand the chemistry of a select group of sulfur-nitrogen compounds including sulfinimines (N-sulfinyl imines) and N-sulfonyloxaziridines. Our early exploration of the thermal properties of sulfenamides, a class of sulfur-nitrogen compounds about which little was known, resulted in a new procedure, the silver-assisted method, for the construction of sulfenimines (N-sulfenyl imines). Selective oxidations of these compounds resulted in the production of N-sulfinyl imines (sulfinimines) and N-sulfonyloxaziridines. N-Sulfonyloxaziridines turned out to be a new class of aprotic neutral oxidizing reagents. Enantiomerically pure examples afford high ee values in the oxidation of enolates to alpha-hydroxy carbonyl compounds and in the oxidation of sulfides and selenides to sulfoxides and selenoxides. Additions of organometallic reagents to enantiomerically pure sulfinimines provide the best and most versatile method for the asymmetric construction of the carbon-nitrogen stereocenters found in many biologically active compounds. Sulfinimine-derived chiral building blocks provide efficient access to many classes of nitrogen heterocycles including aziridines, 2H-azirines, pyrrolidines, and piperidines. 相似文献
