Spontaneous breast hematoma as a complication of anticoagulation therapy requiring angiography and embolization.

Spontaneous breast hematoma is a rare complication of therapeutic anticoagulation therapy with few cases reported in the literature. We present a case of spontaneous breast hematoma resulting in hypotension and symptomatic anemia. Angiography demonstrated multiple sites of hemorrhage within the breast, which was treated with gelatin sponge embolization.

A microchip platform for structural oncology applications.

Recent advances in the development of functional materials offer new tools to dissect human health and disease mechanisms. The use of tunable surfaces is especially appealing as substrates can be tailored to fit applications involving specific cell types or tissues. Here we use tunable materials to facilitate the three-dimensional (3D) analysis of BRCA1 gene regulatory complexes derived from human cancer cells.

A Molecular Toolkit to Visualize Native Protein Assemblies in the Context of Human Disease.

We present a new molecular toolkit to investigate protein assemblies natively formed in the context of human disease. The system employs tunable microchips that can be decorated with switchable adaptor molecules to select for target proteins of interest and analyze them using molecular microscopy. Implementing our new streamlined microchip approach, we could directly visualize BRCA1 gene regulatory complexes from patient-derived cancer cells for the first time.

A Non-Symmetric Reconstruction Technique for Transcriptionally-Active Viral Assemblies.

The molecular mechanisms by which RNA viruses coordinate their transcriptional activities are not fully understood. For rotavirus, an important pediatric gastroenteric pathogen, transcription occurs within a double-layered particle that encloses the viral genome. To date, there remains very little structural information available for actively-transcribing rotavirus double-layered particles, which could provide new insights for antiviral development.

Visualizing viral assemblies in a nanoscale biosphere.

We present a novel microfluidic platform to examine biological assemblies at high-resolution. We have engineered a functionalized chamber that serves as a "nanoscale biosphere" to capture and maintain rotavirus double-layered particles (DLPs) in a liquid environment. The chamber can be inserted into the column of a transmission electron microscope while being completely isolated from the vacuum system.