The invention generally relates to systems including nanoelectrospray ionization emitters in a movable array format in which the emitters can be loaded, singly or simultaneously, through their narrow ends using a novel dip and go method based on capillary action, taking up sample from an array. The sample solutions in each emitter can be electrophoretically cleaned, singly or simultaneously, by creating an inductive electric field that moves interfering ions away from the narrow end of the capillary. Subsequent to cleaning, the emitters are supplied with an inductive electric field that causes electrospray into a mass spectrometer allowing mass analysis of the contents of the emitter.

A method of multiplexing the operation of a sample preparation and analysis system is disclosed. The system includes a sample preparation system capable of preparing a first sample in accordance with a first assay that is selected from a database containing a plurality of unique assays and preparing a second sample in accordance with a second, different assay. The method includes separately transporting the first and second prepared samples to an analysis station having first and second separation channels and an analyzer comprising a mass spectrometer. The method further includes simultaneously analyzing the first prepared sample with the analyzer in accordance with the first selected assay and separating the second prepared sample with the second separation channel in accordance with the second selected assay.

Slide analysis a gripper with three sensors for controlling a slide grip sequence and at least one rotatable carousel with a slide receiving channel. The systems also include a robot with a robot arm that holds a slide gripper residing inside the housing in communication with the rotatable carousel. The systems also include a load lock chamber and a door sealably coupled to the second end portion and an acquisition vacuum chamber with an X-Y stage and a slide holder with a vacuum seal.

Methods for preparing a biological sample for testing by Maldi where such methods are selected based on sample parameters. Maldi scores are obtained for a range of sample parameters (e.g. McFarland, dispense volume and number of dispenses). From the data, sample preparation parameters can be selected for a biological sample being prepared for Maldi testing. One sample preparation strategy uses multiple dispenses of sample with an intervening drying step, which yields more accurate Maldi scores, particularly for samples at the low range of McFarland values (e.g. below about 2).

A sample preparation and analysis system. The system includes a sample preparation system and a sample analysis system. The sample preparation system prepares samples in accordance with an assay that is selected from a database containing a plurality of unique assays. The sample analysis system includes an analyzer that is dynamically reconfigurable based on the selected assay so as to analyze the prepared sample in accordance with that selected assay. A data communication link communicates data from the sample preparation system to the sample analysis system to reconfigure the analyzer in accordance with the selected assay.

A cleanliness monitor for monitoring a cleanliness of a vacuum chamber. The cleanliness monitor may include a mass spectrometer, a molecule aggregation and release unit and an analyzer. The molecule aggregation and release unit is configured to (a) aggregate, during an aggregation period, organic molecules that are present in the vacuum chamber and (b) induce, during a release period, a release of a subset of the organic molecules towards the mass spectrometer. The mass spectrometer is configured to monitor an environment within the vacuum chamber and to generate detection signals indicative of a content of the environment; wherein a first subset of the detection signals is indicative of a presence of the subset of the organic molecules. The analyzer is configured to determine the cleanliness of the vacuum chamber based on the detection signals.

Methods for preparing a biological sample for testing by Maldi where such methods are selected based on sample parameters. Maldi scores are obtained for a range of sample parameters (e.g. McFarland, dispense volume and number of dispenses). From the data, sample preparation parameters can be selected for a biological sample being prepared for Maldi testing. One sample preparation strategy uses multiple dispenses of sample with an intervening drying step, which yields more accurate Maldi scores, particularly for samples at the low range of McFarland values (e.g. below about 2).

Disclosed are various embodiments for automated drug assays. A command is sent to the mass spectrometer to analyze a blood sample to generate a mass spectrum. The mass spectrum is then received from the mass spectrometer. The mass spectrum is analyzed to determine an identity of a pharmaceutical compound present in the blood sample. Finally, a report for the blood sample is generated, the report containing the identity of the pharmaceutical compound present in the blood sample.

Slide analysis a gripper with three sensors for controlling a slide grip sequence and at least one rotatable carousel with a slide receiving channel. The systems also include a robot with a robot arm that holds a slide gripper residing inside the housing in communication with the rotatable carousel. The systems also include a load lock chamber and a door sealably coupled to the second end portion and an acquisition vacuum chamber with an X-Y stage and a slide holder with a vacuum seal.

A mass spectrometer system for analysis of clinical samples includes a source of clinical samples. A controller receives the clinical samples from the source of clinical samples. A sample preparation system receives clinical sample from the controller and processes the samples to produce an extract suitable for analysis by MALDI-TOF mass spectrometry and deposits the extract on a sample plate together with a MALDI matrix. A sample plate loading mechanism transports sample plates from the sample preparation system into an evacuated ion source of a MALDI-TOF mass spectrometer. A MALDI-TOF mass spectrometer ionizes and analyzes samples on the sample plate and generates a mass spectrum of components in the clinical samples. A computer system receives data from the MALDI-TOF mass spectrometer and processes and interprets the data to generate a mass spectrum.