Oscar Marin-Flores

Synthesis and applications of molybdenum (IV) oxide

Molybdenum dioxide (MoO2) is a transition metal oxide with unusual metal-like electrical conductivity and high catalytic activity toward reforming hydrocarbons. This review covers the synthesis techniques used to fabricate MoO2 in a variety of morphologies and particle sizes. Processing from molybdenum ore and reduction from MoO3 are also covered, with emphasis on reduction mechanisms and kinetic considerations. Discussions of various solution-based and gas phase synthesis techniques shed light on strategies to achieve various unique morphologies, which leads into a brief discussion of nanoscale MoO2. Nanoscale MoO2 is of interest for important technological applications including catalysts for partial oxidation of hydrocarbons, solid oxide fuel cell anodes, and high-capacity reversible lithium ion battery anodes.

Silica nanostructured platform for affinity capture of tumor-derived exosomes

Early diagnosis of prostate cancer and evaluation of appropriate treatment options requires development of effective and high-throughput selective capture technology for exosomes that are positive for the expression of enzyme-biomarker, prostate-specific membrane antigen (PSMA). Exosomes are small secreted vesicles that play a key role in intercellular communication and cancer progression. PSMA is highly enriched in exosomes excreted by PSMA+ prostate cancer cells. Using PSMA+ cells from the well-established prostate cancer cell line (LNCaP), the secreted exosomes were collected and isolated from the culture medium. The tumor-derived exosomes were selectively captured using a novel silica nanostructure support that had been functionalized with the small-molecule ligand TG97, a known inhibitor of PSMA enzymatic activity that binds irreversibly in the active site of PSMA. The concept was demonstrated using a single cancer type (i.e., prostate cancer), but based on the data obtained the approach may be applicable to a broad panel of biomarker ligands for selective capture of biomarker-positive exosomes from an array of cell types. The approach demonstrated herein overcomes many of the limitations of alternative methods that are often ineffective in isolating tumor-derived exosomes from those derived from normal tissue because of the low yield recovery and the time required for the process. A further advantage is the ability to isolate a specific subpopulation of exosomes relying on the expression of a specific surface marker as well as improved exosome recovery rate.

Mechanistic study of the reduction of MoO 2 to Mo 2 C under methane pulse conditions

Molybdenum carbide (Mo2C), an interstitial transition metal carbide, has been used in a myriad of industrial applications due to its refractory nature, extreme hardness and strength, and high electrical and thermal conductivity. It also possesses catalytic activity for many chemical processes such as hydrodeoxygenation, reforming, water–gas shift, and the Fischer–Tropsch reaction. Among the current synthesis methods available to produce β-Mo2C, temperature-programmed reduction yields materials with the highest specific surface areas. The objective of the present work is to perform a detailed investigation of the carburization process and to determine the key intermediate phases that are formed during reduction. To achieve this objective, we performed the carburization process under pulse conditions wherein a small amount of CH4 in each pulse was reacted with a packed bed of MoO2. Our XRD and TEM results demonstrate that the solid-phase transformation from MoO2 to β-Mo2C follows a “plum-pudding” mechanism where Mo metal crystallites are constantly formed as the key intermediate phase throughout the matrix.