Abstract: The present invention provides an improved technique for cryogenically fixing biological samples in amorphous ice for analysis by cryo-electron microscopy (cryo-EM). Analyte particles are cooled to very low temperatures prior to depositing the particles onto a cooled substrate surface, such as a transmission electron microscope (TEM) grid. This approach “locks” in the particle structure prior to deposition. Either concurrently with or after deposition, the analyte particles are further contacted with a vapor stream of atoms or molecules at cryogenic or near cryogenic temperatures. As a result, a thin layer of an amorphous solid is formed around each particle without significant conformational changes in the particle structure, thereby forming an improved sample for EM analysis.

Abstract: The present invention provides methods for controllably forming a layer of amorphous ice and other amorphous solids on a substrate, and also provides cryo-electron microscopy (cryo-EM) sample preparation methods and systems that utilize in vacuo formation of amorphous ice and other solids. Formation of the amorphous solid layer can be independent of the deposition of sample molecules to be analyzed using electron microscopy, and allows for the generation of a uniformly thick layer. Optionally, mass spectrometry instruments are used to generate and purify molecules deposited on the generated amorphous solid layer. The techniques and systems described herein can deliver near ideal cryo-EM sample preparation to greatly increase resolution, sensitivity, scope, and throughput of cryo-EM protein imaging, and therefore greatly impact the field of structural biology.

Abstract: Systems for monitoring metabolites may include a sample collection system and a urinalysis system of or for a toilet. The sample collection system may be automated to collect sample urine from a toilet or toilet area, transport the sample to the urinalysis system, and/or the sample urine for analysis at a later time or after analysis by the urinalysis system. The urinalysis system may be automated by proactively providing test material on which a subject may provide a urine sample. Once the urine sample has been provided the urinalysis system may provide the test material to an analyzer for analysis. Results of the analysis of the test material and sample urine may be provided to a mobile device of the subject and/or a remote server. The urinalysis system may provide a urine sample to a mass spectrometry unit for analysis.

Abstract: The present invention provides methods for controllably forming a layer of amorphous ice and other amorphous solids on a substrate, and also provides cryo-electron microscopy (cryo-EM) sample preparation methods and systems that utilize in vacuo formation of amorphous ice and other solids. Formation of the amorphous solid layer can be independent of the deposition of sample molecules to be analyzed using electron microscopy, and allows for the generation of a uniformly thick layer. Optionally, mass spectrometry instruments are used to generate and purify molecules deposited on the generated amorphous solid layer. The techniques and systems described herein can deliver near ideal cryo-EM sample preparation to greatly increase resolution, sensitivity, scope, and throughput of cryo-EM protein imaging, and therefore greatly impact the field of structural biology.

Abstract: The present invention provides methods for controllably forming a layer of amorphous ice and other amorphous solids on a substrate, and also provides cryo-electron microscopy (cryo-EM) sample preparation methods and systems that utilize in vacuo formation of amorphous ice and other solids. Formation of the amorphous solid layer can be independent of the deposition of sample molecules to be analyzed using electron microscopy, and allows for the generation of a uniformly thick layer. Optionally, mass spectrometry instruments are used to generate and purify molecules deposited on the generated amorphous solid layer. The techniques and systems described herein can deliver near ideal cryo-EM sample preparation to greatly increase resolution, sensitivity, scope, and throughput of cryo-EM protein imaging, and therefore greatly impact the field of structural biology.

Abstract: The present invention provides methods for controllably forming a layer of amorphous ice and other amorphous solids on a substrate, and also provides cryoelectron microscopy (cryo-EM) sample preparation methods and systems that utilize in vacuo formation of amorphous ice and other solids. Formation of the amorphous solid layer can be independent of the deposition of sample molecules to be analyzed using electron microscopy, and allows for the generation of a uniformly thick layer. Optionally, mass spectrometry instruments are used to generate and purify molecules deposited on the generated amorphous solid layer. The techniques and systems described herein can deliver near ideal cryo-EM sample preparation to greatly increase resolution, sensitivity, scope, and throughput of cryo-EM protein imaging, and therefore greatly impact the field of structural biology.

Abstract: The present invention provides methods for controllably forming a layer of amorphous ice and other amorphous solids on a substrate, and also provides cryoelectron microscopy (cryo-EM) sample preparation methods and systems that utilize in vacuo formation of amorphous ice and other solids. Formation of the amorphous solid layer can be independent of the deposition of sample molecules to be analyzed using electron microscopy, and allows for the generation of a uniformly thick layer. Optionally, mass spectrometry instruments are used to generate and purify molecules deposited on the generated amorphous solid layer. The techniques and systems described herein can deliver near ideal cryo-EM sample preparation to greatly increase resolution, sensitivity, scope, and throughput of cryo-EM protein imaging, and therefore greatly impact the field of structural biology.

Abstract: A new approach is described herein for outfitting a mass spectrometer with an infrared laser that provides an improved method of ion dissociation. One embodiment, generally referred to as Activated Ion Electron Transfer Dissociation (AI-ETD) utilizes additional energy from photons during fragmentation to generate extensive fragmentation by interacting with peptides or proteins that are not fully fragmented or separated in the high pressure linear ion trap, thus allowing for increased information during MS/MS. Additionally, a new activation scheme generally referred to as AI-ETD+ is also described that combines AI-ETD in the high pressure cell of the linear ion trap with additional infrared multi-photon dissociation (IRMPD) activation in the low pressure cell. These methods provide improved fragmentation and sequence coverage without introducing additional time to the scan duty cycle.

Abstract: An active detector and methods for detecting molecules, including large molecules such as proteins and oligonucleotides, at or near room temperature based on the generation of electrons via field emission (FE) and/or secondary electron emission (SEE). The detector comprises a semiconductor membrane having an external surface that is contacted by one or more molecules, and an internal surface having a thin metallic layer or other type of electron emitting layer. The kinetic energy of molecules contacting the semiconductor membrane is transferred through the membrane and induces the emission of electrons from the emitting layer. An electron detector, which optionally includes means for electron amplification, is positioned to detect the emitted electrons.

Abstract: This invention provides methods, devices and device components for preparing ions from liquid samples containing chemical species and methods and devices for analyzing chemical species in liquid samples. The present invention provides an ion source for generating analyte ions having a selected charge state distribution, such as a reduced charged state distribution, that may be effectively interfaced with a variety of charged particle analyzers, including virtually any type of mass spectrometer.

Abstract: The present invention provides methods, devices and device components for detecting, sensing and analyzing molecules. Detectors of the present invention provide good detection sensitivity over a wide range of molecular masses ranging from a few Daltons up to 10s of megadaltons, which does not decrease as function of molecular mass. Sensors and analyzers of the present invention detect emission from an array of resonators to determine the molecular masses and/or electric charges of molecules which impact or contact an external surface of a membrane that is used to mount and excite the resonators in the array. Resonators in the array are excited via piezoelectric and/or magnetic excitation of the mounting membrane and, optionally, grid electrodes are used in certain configurations for electrically biasing for the resonator array, and for amplification or suppression of emission from the resonators so as to provide detection and mass/electric charge analysis with good sensitivity and resolution.