On-chip laser-induced DNA dehybridization.

Detection of pathogens and relevant genetic markers using their nucleic acid signatures is extremely common due to the inherent specificity genomic sequences provide. One approach for assaying a sample simultaneously for many different targets is the DNA microarray, which consists of several million short nucleic acid sequences (probes) bound to an inexpensive transparent substrate. Typically, complex samples hybridize to the microarray and the pattern of fluorescing probes on the microarray's surface identifies the detected targets. In the case of evolving or newly emergent organisms, a hybridization pattern can occur that differs from any previously known sources. When this happens it can be useful to recover the hybridized DNA from the binding locations of interest for sequencing. Here we present the novel utilization of a focused Infrared (IR) laser to heat user-selected spots on the DNA microarray surface, causing only localized dehybridization and recovery of the desired DNA into an elution buffer where it is available for subsequent amplification or sequencing. The introduction of a focused dehybridization method for spots of interest suppresses the amount of background DNA to be analyzed from downstream processes, and should reduce subsequent sequence assembly errors. This technique could also be applied to high-density protein microarrays where the desire to locally heat spots for release of bound molecules is desired.

The neutron imaging diagnostic at NIF (invited).

A neutron imaging diagnostic has recently been commissioned at the National Ignition Facility (NIF). This new system is an important diagnostic tool for inertial fusion studies at the NIF for measuring the size and shape of the burning DT plasma during the ignition stage of Inertial Confinement Fusion (ICF) implosions. The imaging technique utilizes a pinhole neutron aperture, placed between the neutron source and a neutron detector. The detection system measures the two dimensional distribution of neutrons passing through the pinhole. This diagnostic has been designed to collect two images at two times. The long flight path for this diagnostic, 28 m, results in a chromatic separation of the neutrons, allowing the independently timed images to measure the source distribution for two neutron energies. Typically the first image measures the distribution of the 14 MeV neutrons and the second image of the 6-12 MeV neutrons. The combination of these two images has provided data on the size and shape of the burning plasma within the compressed capsule, as well as a measure of the quantity and spatial distribution of the cold fuel surrounding this core.