Direct conversion of carbon nanofibers and nanotubes into diamond nanofibers and the subsequent growth of large-sized diamonds.

We report a pulsed laser annealing method to convert carbon fibers and nanotubes into diamond fibers at ambient temperature and pressure in air. The conversion of carbon nanofibers and nanotubes into diamond nanofibers involves melting in a super undercooled state using nanosecond laser pulses, and quenching rapidly to convert into phase-pure diamond. The conversion process occurs at ambient temperature and pressure, and can be carried out in air. The structure of diamond fibers has been confirmed by selected-area electron diffraction in transmission electron microscopy, electron-back-scatter-diffraction in high-resolution scanning electron microscopy, all showing characteristic diffraction lines for the diamond structure. The bonding characteristics were determined by Raman spectroscopy with a strong peak near 1332 cm-1, and high-resolution electron-energy-loss spectroscopy in transmission electron microscopy with a characteristic peak at 292 eV for σ* for sp3 bonding and the absence of π* for sp2 bonding. The Raman peak at 1332 cm-1 downshifts to 1321 cm-1 for diamond nanofibers due to the phonon confinement in nanodiamonds. These laser-treated carbon fibers with diamond seeds are used to grow larger diamond crystallites further by using standard hot-filament chemical vapor deposition (HFCVD). We compare these results with those obtained without laser treating the carbon fibers. The details of diamond conversion and HFCVD growth are presented in this paper.

Neutrophil gelatinase-associated lipocalin as a biomarker of disease progression in patients with chronic kidney disease.

Chronic kidney disease (CKD) is associated with early mortality, decreased quality of life and increased health care expenditures. The aim of this study was to determine whether or not urinary NGAL (uNGAL) level is associated with renal damage and kidney disease progression in patients with CKD and to evaluate the predictive value of uNGAL in progression of CKD. Totally, 91 cases of CKD stage II, III, IV, and 50 age-matched healthy controls were enrolled. The follow-up end-point was 18 months; end-point of the study was progression to an estimated glomerular filtration rate (eGFR) of <15 ml/min and/or CKD stage V. Forty-five cases (49.4%) were progressors and 46 were nonprogressors. uNGAL levels were significantly higher in CKD subjects as compared to healthy controls (log 1.09 ± 0.22 µg/ml in controls versus log 1.22 ± 2.08 µg/ml in stage II, log 3.34 ± 2.74 µg/ml in stage III and log 3.70 ± 0.18 µg/ml in stage IV). Univariate Cox proportional hazards model showed that only eGFR (hazard ratio [HR]: 0.95; 95% confidence interval [CI]: 0.93-0.96; P < 0.001) and uNGAL (HR: 1.11; 95% CI: 1.01-1.20; P < 0.001) were significantly associated with end-point of CKD stage V, but multiple Cox proportional regression model showed significant association of uNGAL (HR: 1.11; 95% CI: 1.01-1.20; P < 0.001) and eGFR (HR: 0.962, 95% CI: 0.95-0.98; P < 0.001) with end-point of CKD stage V. This suggests that uNGAL would not be a simple surrogate index of baseline eGFR, but a marker of CKD progression beyond the information provided by eGFR estimation.

Localized surface plasmon sensing based investigation of nanoscale metal oxidation kinetics.

The localized surface plasmon resonance (LSPR) of nanoparticles can be a powerful and sensitive probe of chemical changes in nanoscale volumes. Here we have used the LSPR of silver (Ag) to study the oxidation kinetics of nanoscopic volumes of cobalt (Co) metal. Bimetal nanoparticles of the immiscible Co-Ag system prepared by pulsed laser dewetting were aged in ambient air and the resulting changes to the LSPR signal and bandwidth were used to probe the oxidation kinetics. Co was found to preferentially oxidize first. This resulted in a significant enhancement by a factor of 8 or more in the lifetime of stable Ag plasmons over that of pure Ag. Theoretical modeling based on optical mean field approximation was able to predict the oxidation lifetimes and could help design stable Ag-based plasmonic nanoparticles for sensing applications.

DC electric field induced phase array self-assembly of Au nanoparticles.

In this work we report the discovery of phase array self-assembly, a new way to spontaneously make periodic arrangements of metal nanoparticles. An initially random arrangement of gold (Au) or silver (Ag) nanoparticles on SiO2/Si substrates was irradiated with linearly polarized (P) laser light in the presence of a dc electric (E) field applied to the insulating substrate. For E fields parallel to the laser polarization (E||P), the resulting periodic ordering was single-crystal like with extremely low defect density and covered large macroscopic areas. The E field appears to be modifying the phase between radiation scattered by the individual nanoparticles thus leading to enhanced interference effects. While phase array behavior is widely known in antenna technology, this is the first evidence that it can also aid in nanoscale self-assembly. These results provide a simple way to produce periodic metal nanoparticles over large areas.

Oxidation-resistant silver nanostructures for ultrastable plasmonic applications.

Reduced degradation (oxidation) of silver nanoparticles (NPs) is achieved by contacting Ag with immiscible Co NPs. The relative decay of the plasmon peak (plot) shows that pure Ag NPs (blue dashed curve) decay by 25% in ca 20 days, whereas AgCo NPs last about 10 times longer, requiring nearly five months for a similar decay (red solid curve). The TEM images for both Ag and AgCo were taken after 50 days of storage under ambient conditions.

Self-organized bimetallic Ag-Co nanoparticles with tunable localized surface plasmons showing high environmental stability and sensitivity.

We demonstrate a promising synthesis route based on pulsed laser dewetting of bilayer films (Ag and Co) to make bimetallic nanoparticle arrays. By combining experiment and theory we establish a parameter space for the independent control of composition and diameter for the bimetallic nanoparticles. As a result, physical properties, such as the localized surface plasmon resonance (LSPR), that depend on particle size and composition can be readily tuned over a wavelength range one order of magnitude greater than for pure Ag nanoparticles. The LSPR detection sensitivity of the bimetallic nanoparticles with narrow size distribution was found to be high-comparable with pure Ag (∼60 nm/RIU). Moreover, they showed significantly higher long-term environmental stability over pure Ag.

Thickness-dependent spontaneous dewetting morphology of ultrathin Ag films.

We show here that the morphological pathway of spontaneous dewetting of ultrathin Ag films on SiO2 under nanosecond laser melting is dependent on film thickness. For films with thickness h of 2 nm < or = h < or = 9.5 nm, the morphology during the intermediate stages of dewetting consisted of bicontinuous structures. For films with 11.5 nm < or = h < or = 20 nm, the intermediate stages consisted of regularly sized holes. Measurement of the characteristic length scales for different stages of dewetting as a function of film thickness showed a systematic increase, which is consistent with the spinodal dewetting instability over the entire thickness range investigated. This change in morphology with thickness is consistent with observations made previously for polymer films (Sharma and Khanna 1998 Phys. Rev. Lett. 81 3463-6; Seemann et al 2001 J. Phys.: Condens. Matter 13 4925-38). Based on the behavior of free energy curvature that incorporates intermolecular forces, we have estimated the morphological transition thickness for the intermolecular forces for Ag on SiO2. The theory predictions agree well with observations for Ag. These results show that it is possible to form a variety of complex Ag nanomorphologies in a consistent manner, which could be useful in optical applications of Ag surfaces, such as in surface enhanced Raman sensing.

Genetic variants of interleukin-1RN and interleukin-1beta genes and risk of cervical cancer.

OBJECTIVES: Inflammation plays a major role in pathogenesis of cervical cancer. We planned to study whether polymorphisms in inflammation-related genes, IL-1RN (VNTR) and IL-1beta (-511C/T), are associated with risk of cervical cancer. DESIGN: Case-control study. SETTING: Uttar Pradesh state in India. SAMPLE: One hundred and fifty, histopathologically confirmed cases with cervical cancer and 162 age-, ethnicity-matched, cervical cytology negative, healthy controls were recruited to this study. METHODS: Genotyping of IL-1RN (VNTR) and IL-1beta (-511C/T) polymorphisms was performed using polymerase chain reaction (PCR)/PCR-restriction fragment length polymorphism. Power of study was 80% with type 1 error of 0.05. Haplotypes frequencies were obtained by computer package 'Arlequin'. MAIN OUTCOME MEASURES: Haplotype IL-1RN*2/IL-1beta*T is associated with higher risk and of cervical cancer. RESULTS: IL-1RN genotypes 1/2 and 2/2 were associated with significantly elevated risk of cervical cancer (OR = 3.3; P= 4.9 x 10(-6) and OR = 2.9, P= 0.02). Similarly, TT genotype of IL-1betapolymorphism was significantly higher in cases compared with controls (57.7 versus 38.3%; OR = 2.8; P = 0.012). 2/2 genotype of IL-1RN (OR = 4.8, P = 0.0006) and TT genotype of IL-1beta(OR = 5.2; P = 0.02) were associated with the higher stages (III) of cervical cancer. Haplotypes 1T (IL-1RN*1/IL-1beta*T) and 2T (IL-1RN*2/IL-1beta*T) were also significantly associated with higher susceptibility to cervical cancer and its progression. Logistic regression analysis suggests IL-1RN allele 2 and IL-1beta-511T were independently associated with increased risk for cervical cancer. CONCLUSION: IL-1RN*2 and IL-1beta -511*T in various combinations of genotypes and haplotypes are associated with higher susceptibility for cervical cancer.