Directed Growth of Polymer Nanorods Using Surface-Initiated Ring-Opening Polymerization of N-Allyl N-Carboxyanhydride.

A stepwise chemistry route was used to prepare arrays of polymer nanostructures of poly(N-allyl glycine) on Si(111) using particle lithography. The nanostructures were used for studying surface reactions with advanced measurements of atomic force microscopy (AFM). In the first step to fabricate the surface platform, isolated nanopores were prepared within a thin film of octadecyltrichlorosilane (OTS). The OTS served as a surface resist, and the areas of nanopores provided multiple, regularly shaped sites for further reaction. An initiator, (3-aminopropyl)triethoxysilane (APTES), was grown selectively inside the nanopores to define sites for polymerization. The initiator attached selectively to the sites of nanopores indicating OTS prevented nonspecific adsorption. Surface-initiated ring-opening polymerization of N-allyl N-carboxyanhydride with APTES produced polymer nanorods on the nanodots of APTES presenting amine functional groups. The surface changes for each step were monitored using high resolution atomic force microscopy (AFM). Slight variations in the height of the poly(N-allyl glycine) nanorods were observed which scale correspondingly to the initial dimensions of nanopores. The distance between adjacent polymer nanorods was controlled by the size of mesoparticle masks used in the experiment. This surface platform has potential application in biotechnology for smart coatings or biosensors.

Syntheses and Photodynamic Activity of Pegylated Cationic Zn(II)-Phthalocyanines in HEp2 Cells.

Di-cationic Zn(II)-phthalocyanines (ZnPcs) are promising photosensitizers for the photodynamic therapy (PDT) of cancers and for photoinactivation of viruses and bacteria. Pegylation of photosensitizers in general enhances their water-solubility and tumor cell accumulation. A series of pegylated di-cationic ZnPcs were synthesized from conjugation of a low molecular weight PEG group to a pre-formed Pc macrocycle, or by mixed condensation involving a pegylated phthalonitrile. All pegylated ZnPcs were highly soluble in polar organic solvents but were insoluble in water; they have intense Q absorptions centered at 680 nm and fluorescence quantum yields of ca. 0.2 in DMF. The non-pegylated di-cationic ZnPc 6a formed large aggregates, which were visualized by atomic force microscopy. The cytotoxicity, cellular uptake and subcellular distribution of all cationic ZnPcs were investigated in human carcinoma HEp2 cells. The most phototoxic compounds were found to be the α-substituted Pcs. Among these, Pcs 4a and 16a were the most effective (IC(50) ca. 10 µM at 1.5 J/cm(2)), in part due to the presence of a PEG group and the two positive charges in close proximity (separated by an ethylene group) in these macrocycles. The ß-substituted ZcPcs 6b and 4b accumulated the most within HEp2 cells but had low photocytoxicity (IC(50) > 100 µM at 1.5 J/cm(2)), possibly as a result of their lower electron density of the ring and more extended conformations compared with the α-substituted Pcs. The results show that the charge distribution about the Pc macrocycle and the intracellular localization of the cationic ZnPcs mainly determine their photodynamic activity.

Effects of peptides derived from terminal modifications of the aß central hydrophobic core on aß fibrillization.

Considerable research effort has focused on the discovery of mitigators that block the toxicity of the ß-amyloid peptide (Aß) by targeting a specific step involved in Aß fibrillogenesis and subsequent aggregation. Given that aggregation intermediates are hypothesized to be responsible for Aß toxicity, such compounds could likely prevent or mitigate aggregation, or alternatively cause further association of toxic oligomers into larger nontoxic aggregates. Herein we investigate the effect of modifications of the KLVFF hydrophobic core of Aß by replacing N- and C-terminal groups with various polar moieties. Several of these terminal modifications were found to disrupt the formation of amyloid fibrils and in some cases induced the disassembly of preformed fibrils. Significantly, mitigators that incorporate MiniPEG polar groups were found to be effective against Aß(1-40) fibrilligonesis. Previously, we have shown that mitigators incorporating alpha,alpha-disubstituted amino acids (ααAAs) were effective in disrupting fibril formation as well as inducing fibril disassembly. In this work, we further disclose that the number of polar residues (six) and ααAAs (three) in the original mitigator can be reduced without dramatically changing the ability to disrupt Aß(1-40) fibrillization in vitro.

Structure-activity relationships in peptide modulators of ß-amyloid protein aggregation: variation in α,α-disubstitution results in altered aggregate size and morphology.

Neuronal cytotoxicity observed in Alzheimer's disease (AD) is linked to the aggregation of ß-amyloid peptide (Aß) into toxic forms. Increasing evidence points to oligomeric materials as the neurotoxic species, not Aß fibrils; disruption or inhibition of Aß self-assembly into oligomeric or fibrillar forms remains a viable therapeutic strategy to reduce Aß neurotoxicity. We describe the synthesis and characterization of amyloid aggregation mitigating peptides (AAMPs) whose structure is based on the Aß "hydrophobic core" Aß(17-20), with α,α-disubstituted amino acids (ααAAs) added into this core as potential disrupting agents of fibril self-assembly. The number, positional distribution, and side-chain functionality of ααAAs incorporated into the AAMP sequence were found to influence the resultant aggregate morphology as indicated by ex situ experiments using atomic force microscopy (AFM) and transmission electron microscopy (TEM). For instance, AAMP-5, incorporating a sterically hindered ααAA with a diisobutyl side chain in the core sequence, disrupted Aß(1-40) fibril formation. However, AAMP-6, with a less sterically hindered ααAA with a dipropyl side chain, altered fibril morphology, producing shorter and larger sized fibrils (compared with those of Aß(1-40)). Remarkably, ααAA-AAMPs caused disassembly of existing Aß fibrils to produce either spherical aggregates or protofibrillar structures, suggesting the existence of equilibrium between fibrils and prefibrillar structures.

Detecting the magnetic response of iron oxide capped organosilane nanostructures using magnetic sample modulation and atomic force microscopy.

A new imaging strategy using atomic force microscopy (AFM) is demonstrated for mapping magnetic domains at size regimes below 100 nm. The AFM-based imaging mode is referred to as magnetic sample modulation (MSM), since the flux of an AC-generated electromagnetic field is used to induce physical movement of magnetic nanomaterials on surfaces during imaging. The AFM is operated in contact mode using a soft, nonmagnetic tip to detect the physical motion of the sample. By slowly scanning an AFM probe across a vibrating area of the sample, the frequency and amplitude of vibration induced by the magnetic field is tracked by changes in tip deflection. Thus, the AFM tip serves as a force and motion sensor for mapping the vibrational response of magnetic nanomaterials. Essentially, MSM is a hybrid of contact mode AFM combined with selective modulation of magnetic domains. The positional feedback loop for MSM imaging is the same as that used for force modulation and contact mode AFM; however, the vibration of the sample is analyzed using channels of a lock-in amplifier. The investigations are facilitated by nanofabrication methods combining particle lithography with organic vapor deposition and electroless deposition of iron oxide, to prepare designed test platforms of magnetic materials at nanometer length scales. Custom test platforms furnished suitable surfaces for MSM characterizations at the level of individual metal nanostructures.

Synthesis, aggregation and cellular investigations of porphyrin-cobaltacarborane conjugates.

A new series of porphyrin-cobaltacarborane conjugates (1-5) that contain four to sixteen carborane clusters per porphyrin macrocycle, were prepared in excellent yields (90-97 %) by means of a ring-opening reaction of the zwitterionic cobaltacarborane [3,3'-Co(8-C(4)H(8)O(2-)-1,2-C(2)B(9)H(10))(1',2'-C(2)B(9)H(11))]. The X-ray structure of one conjugate (3) is presented. The aggregation properties of these conjugates were investigated by using absorption and fluorescence spectrophotometry, and the stages of microcrystal formation were captured by using atomic force microscopy. All conjugates were found to aggregate in aqueous solutions, to form a broad dispersity of particle sizes. The cellular uptake, cytotoxicity, and preferential sites of subcellular localization of this series of conjugates were evaluated in human carcinoma HEp2 cells. The extent of conjugate cellular uptake depends on the number of cobaltacarborane units at the porphyrin periphery, their distribution, and the conjugate aggregation behavior. Conjugates 2 and 4, bearing either two adjacent or three 3,5-dicobaltacarboranephenyl groups, accumulated the most within HEp2 cells and are, therefore, the most promising boron neutron capture therapy agents. All conjugates showed very low dark- and photo-toxicity, probably due to their strong tendency for aggregation in aqueous solutions, and localized subcellularly within vesicles that correlated, to some extent, with the cell lysosomes.

A general methodology for the synthesis of transition metal pnictide nanoparticles from pnictate precursors and its application to iron-phosphorus phases.

Nanoparticles of iron phosphide have been prepared through a new strategy involving the reductive annealing of nanoparticulate iron phosphate precursors cast onto atomically flat mica surfaces. This route appears to be general for a range of transition metals and pnicogens and avoids the use of highly toxic and pyrophoric agents such as Pn(SiMe3)3 (Pn = P, As), which are commonly employed in the synthesis of pnictide nanoparticles.