A cancer cell detection device includes a computer with a database and a display and a microscope coupled to the computer. The microscope has a base upon which a biopsy sample can be placed. The device further includes a camera coupled to the microscope and computer. The camera is configured to capture images of the biopsy sample. The device also has a filter configured to attach to the microscope and a connection feature for connecting the computer to the camera and the filter. The computer further includes a processor that processes the images captured by the camera and classifies the images according to known variables stored in the database.

In one aspect, a computer readable memory medium comprising program instructions for graphically developing a connectivity driver is provided. The computer readable memory medium is a non-transitory medium. The program instructions are executable by a processor to generate a purchase order for a laboratory item, transmit the purchase order to a remote computer in order to communicate the purchase order to a vendor, receive an advance shipping notice generated in response to the purchase order, receive item information stored in an RFID tag of a tagged item received at the delivery location, and check the item information against the advance shipping notice in order to verify that the tagged item is the same as the ordered laboratory item. The purchase order specifies a delivery location.

As a standard solution for evaluating a scattered light measuring optical system mounted on an automated analyzer, a standard solution containing an insoluble carrier at a concentration, at which transmittance is in a range of 10% to 50%, is used, and a light quantity of a light source is adjusted such that a scattered light detector outputs a predetermined value.

As a standard solution for evaluating a scattered light measuring optical system mounted on an automated analyzer, a standard solution containing an insoluble carrier at a concentration, at which transmittance is in a range of 10% to 50%, is used, and a light quantity of a light source is adjusted such that a scattered light detector outputs a predetermined value.

Disclosed is an automated liquid-phase immunoassay apparatus used with a cuvette having a plurality of chambers containing a reagent necessary for detection of an analyte in a biological specimen. The apparatus includes a movable cuvette module equipped with the cuvette, an optical reading module for optical assaying of a material resulting from a reaction between the specimen and the reagent, and a dispenser module which is positioned on the cuvette module and which dispenses the specimen and the reagent to the plurality of chambers of the cuvette and washes the specimen and the reagent therefrom.

Embodiments of a platelet testing system include an analyzer console device and a blood testing cartridge configured to releasably install into the console device. The cartridge device is configured with one or more measuring chambers and one or more mixing chambers that are fluidically connected within the cartridge device that enable the mixing of saline and a blood sample to a desired dilution. Additionally, the cartridge device is further configured with a cartridge slider that provides a reagent bead to the saline and blood mixture at a desired time. As such, one or more platelet activation assays can be conducted by measuring, through cartridge electrodes of the cartridge device, the detectable changes in platelet activity within the blood and saline mixture.

System and method for managing one or more experimental requests. For example, the method includes receiving multiple experimental requests, determining a schedule for executing the multiple experimental requests based upon attributes associated with each experimental request, and assigning the multiple experimental requests to remote laboratories for execution based upon the schedule and features of the remote laboratories.

System and method for processing one or more experimental workflows. For example, the method includes receiving an indication of an experimental workflow selected by a user, generating workflow configuration requirements for the experimental workflow, presenting a user interface to enable input of parameters to configure the experimental workflow in accordance with the workflow configuration requirements, performing a validation of the parameters, configuring the experimental workflow based upon the validated parameters, and transforming the configured experimental workflow into machine executable codes for execution by devices at remote laboratories.

The automatic analysis system comprises an analysis device which introduces sample containers which have been placed at a predetermined placement location into an analysis unit to perform analysis on the samples, and a management device which has a function of transmitting identification information for a sample to said analysis device when an analysis request has been made for that sample. The analysis device comprises a sample information management unit which retains sample identification information transmitted from the management device as analysis-requested sample information and retains identification information for samples which have been analyzed by the analysis unit as analysis-completed sample information.

A reaction processor is provided with a reaction processing vessel in which a channel is formed, a liquid feeding system, a temperature control system for providing a high temperature region and a low temperature region to the channel, and a fluorescence detector for detecting the sample passing through a fluorescence detection region of the channel, and a CPU for controlling the liquid feeding system based on a signal that is detected. A target stop position X.sup.[L].sub.0(n+1) of the sample in the low temperature region in an (n+1)th cycle is corrected from a target stop position X.sup.[L].sub.0(n) of the sample in the low temperature region in the nth cycle based on the result of stopping control on the sample in the nth cycle.