Abstract: The fluidic system of the preferred embodiment includes a sheath pump to pump sheath fluid from a sheath container into an interrogation zone and a waste pump to pump waste fluid from the interrogation zone into a waste container. The sheath pump and/or the waste pump draw sample fluid from a sample container into the interrogation zone. The fluidic system also includes a controller to adjust the flow rate of the sample fluid from the sample container into the interrogation zone. The fluidic system is preferably incorporated into a flow cytometer with a flow cell that includes the interrogation zone.

Abstract: A pulsation attenuator for a fluidic system with a fluidic pump. The pulsation attenuator includes a fluidic channel, a first fluidic device adapted to attenuate pulsations with a shallow rolloff slope, and a second fluidic device adapted to attenuate pulsations with a shallow rolloff slope. The first fluidic device and the second fluidic device are connected to the fluidic channel such that they cooperatively attenuate pulsations with a steep rolloff slope. Preferably, the first fluidic device includes a first fluidic resistor and a first fluidic capacitor, and the second fluidic device includes a second fluidic resistor and a second fluidic capacitor. Preferably, the pulsation attenuator is arranged, similar a second-order low-pass filter, in the following order: (1) first fluidic resistor, (2) first fluidic capacitor, (3) second fluidic resistor, and (4) second fluidic capacitor.

Abstract: The flow cytometer user interface of the preferred embodiment comprises the steps of (1) running the sample and saving all collected data, (2) viewing the raw (or “unmodified”) data, (3) modifying the raw data (e.g., scaling and/or culling the raw data), (4) reviewing and saving the modified settings, and (5) exporting the saved data. Once the sample has been run and all collected data have been saved, the user can repeat the steps of modifying the raw data, saving the modified settings, and exporting the saved data as many times as necessary and/or desirable without the need to run an additional sample.

Abstract: The detection system of the first preferred embodiment includes a detector, having a wide dynamic range, that receives photonic inputs from the interrogation zone and produces an analog signal; and an analog-to-digital converter (ADC), having a high bit resolution, that is coupled to the detector and converts an analog signal to a digital signal. The digital signal includes an initial data set of the full dynamic range of the input signals from the flow cytometer sample. The method of extracting and analyzing data from a flow cytometer system of the first preferred embodiment preferably includes the steps of: collecting a full dynamic range of input signals from a flow cytometer sample; recognizing and annotating aggregate particle events; and storing an initial data set and an annotated data set of the full dynamic range of the input signals from the flow cytometer sample.

Abstract: The flow cytometry system of the present invention includes a flow channel including an interrogation zone. A light source and a light detector are connected to the interrogation zone, such that a sample flowing through the interrogation zone can be optically analyzed through methods known in the art of flow cytometry. A bubble detector is connected to the flow channel. A controller is connected to the bubble detector and is adapted to perform a predetermined output in response to the detection of a bubble in the flow channel. The predetermined output may include alerting a user as to the presence of a bubble, flagging potentially corrupted data, and ceasing data collection until the interrogation zone is clear of bubbles.

Abstract: A pulsation attenuator for a fluidic system with a fluidic pump. The pulsation attenuator includes a fluidic channel, a first fluidic device adapted to attenuate pulsations with a shallow rolloff slope, and a second fluidic device adapted to attenuate pulsations with a shallow rolloff slope. The first fluidic device and the second fluidic device are connected to the fluidic channel such that they cooperatively attenuate pulsations with a steep rolloff slope. Preferably, the first fluidic device includes a first fluidic resistor and a first fluidic capacitor, and the second fluidic device includes a second fluidic resistor and a second fluidic capacitor. Preferably, the pulsation attenuator is arranged, similar a second-order low-pass filter, in the following order: (1) first fluidic resistor, (2) first fluidic capacitor, (3) second fluidic resistor, and (4) second fluidic capacitor.

Abstract: The fluidic system 10 of the preferred embodiment includes a sheath pump 12 to pump sheath fluid 14 from a sheath container 16 through a sample port 34 into an interrogation zone 18 and a waste pump 20 to pump the sheath fluid 14 and a sample fluid 26 as waste fluid 22 from the interrogation zone 18 into a waste container 24, and a processor 30 to calculate a time window based on the flow rate of the sample fluid 26. Preferably the processor 30 also calculates a time window for the sample fluid to reach the interrogation zone 18 from the sample port 34 based on the flow rate of the sample fluid 26. The interrogation zone 18 functions to provide a location for the fluidic system 10 and an optical analysis system 32 of the flow cytometer to cooperatively facilitate the analysis of the sample fluid 26.

Abstract: The fluidic system with an unclogging feature of the preferred embodiment includes a flow channel, a sheath pump to pump sheath fluid from a sheath container into an interrogation zone, and a waste pump to pump waste fluid from the interrogation zone into a waste container. The sheath pump and/or the waste pump draw sample fluid from a sample container into the interrogation zone. The fluidic system also includes a controller to adjust the flow rate of the sample fluid from the sample container into the interrogation zone. The pump and controller cooperate to propagate a pulsation through the flow channel from the pump if the flow channel is clogged. The fluidic system is preferably incorporated into a flow cytometer with a flow cell that includes the interrogation zone.

Abstract: The present invention includes a system and a method of representing a medical event. The method includes the steps of collecting 3D information on an event, identifying a non-linear aspect of the event, determining a non-planar slice of the 3D information that represents the non-linear aspect, and outputting the non-planar slice as a representation of the event. The system includes an imaging device for collecting 3D information on an event. The system further includes a processor for identifying a non-linear aspect of the event, determining a non-planar slice of the 3D information that represents the non-linear aspect and outputting the non-planar slice as a representation of the event.

Abstract: The present invention includes a system and a method of displaying the trajectory of an instrument and the position of a body within a volume. The preferred method includes the steps of creating a representation of at least a portion of the volume, calculating a trajectory of the instrument relative to a position of the body, and displaying the trajectory of the instrument and the position of the body. The preferred system includes an instrument, an ultrasonic device, a processor coupled to the ultrasonic device, and a display adapted to display the trajectory of the instrument and the position of the body.

Abstract: The invention includes a system and a method for capturing multi source excitations from a single location on a flow channel. The system preferably includes a light subsystem that emits light onto a single location on a flow channel, a detector subsystem to detect light emitted from the single location on the flow channel, and a processor to separate the detected light. The method preferably includes emitting light onto a single location on a flow channel, detecting light emitted from the single location on the flow channel, and separating the detected light.

Abstract: A pulsation attenuator for a fluidic system with a fluidic pump. The pulsation attenuator includes a fluidic channel, a first fluidic device adapted to attenuate pulsations with a shallow rolloff slope, and a second fluidic device adapted to attenuate pulsations with a shallow rolloff slope. The first fluidic device and the second fluidic device are connected to the fluidic channel such that they cooperatively attenuate pulsations with a steep rolloff slope. Preferably, the first fluidic device includes a first fluidic resistor and a first fluidic capacitor, and the second fluidic device includes a second fluidic resistor and a second fluidic capacitor. Preferably, the pulsation attenuator is arranged, similar a second-order low-pass filter, in the following order: (1) first fluidic resistor, (2) first fluidic capacitor, (3) second fluidic resistor, and (4) second fluidic capacitor.

Abstract: The flow cytometry system of the present invention includes a flow channel including an interrogation zone. A light source and a light detector are connected to the interrogation zone, such that a sample flowing through the interrogation zone can be optically analyzed through methods known in the art of flow cytometry. A bubble detector is connected to the flow channel. A controller is connected to the bubble detector and is adapted to perform a predetermined output in response to the detection of a bubble in the flow channel. The predetermined output may include alerting a user as to the presence of a bubble, flagging potentially corrupted data, and ceasing data collection until the interrogation zone is clear of bubbles.

Abstract: The fluidic system of the preferred embodiment includes a sheath pump to pump sheath fluid from a sheath container into an interrogation zone, a sheath volume measurement device to measure the fluid in the sheath container, a waste pump to pump the sheath fluid and a sample fluid as waste fluid from the interrogation zone into a waste container, and a waste volume measurement device to measure the fluid in the waste container. The system also includes a controller connected to the sheath pump, the waste pump, and the volume measurement devices. The sheath pump and/or the waste pump draw sample fluid from a sample container into the interrogation zone, which functions to provide a location for the fluidic system and an optical system of the flow cytometer to cooperatively facilitate the analysis of the sample fluid.

Abstract: A first preferred embodiment includes a flow cytometer with a fluidic system to draw a sample fluid into an interrogation zone, a light source to emit light toward the sample fluid in the interrogation zone, an optic system to collect and detect at least one of a scattered light and a fluorescent light from the interrogation zone, and a processor. The flow cytometer, if properly boxed and labeled, complies with the parcel post requirements of the United States Postal Service. A second preferred embodiment includes the method of supplying a flow cytometer by shipping the flow cytometer via the United States Postal Service. A third preferred embodiment includes the method of servicing a flow cytometer by receiving the flow cytometer from a user via the United States Postal Service and servicing the flow cytometer.

Abstract: The fluidic system of the preferred embodiment includes a sheath pump to pump sheath fluid from a sheath container into an interrogation zone and a waste pump to pump waste fluid from the interrogation zone into a waste container. The sheath pump and/or the waste pump draw sample fluid from a sample container into the interrogation zone. The fluidic system also includes a controller to adjust the flow rate of the sample fluid from the sample container into the interrogation zone. The fluidic system is preferably incorporated into a flow cytometer with a flow cell that includes the interrogation zone.

Abstract: The first integrated circuit/transducer device 36 of the handheld probe includes CMOS circuits 110 and cMUT elements 112. The cMUT elements 112 function to generate an ultrasonic beam, detect an ultrasonic echo, and output electrical signals, while the CMOS circuits 110 function to perform analog or digital operations on the electrical signals generated through operation of the cMUT elements 112. The manufacturing method for the first integrated circuit/transducer device 36 of the preferred embodiment includes the steps of depositing the lower electrode S102; depositing a sacrificial layer S104; depositing a dielectric layer S106; removing the sacrificial layer S108, followed by the steps of depositing the upper electrode S110 and depositing a protective layer on the upper electrode S112.

Abstract: The first integrated circuit/transducer device 36 of the handheld probe includes CMOS circuits 110 and cMUT elements 112. The cMUT elements 112 function to generate an ultrasonic beam, detect an ultrasonic echo, and output electrical signals, while the CMOS circuits 110 function to perform analog or digital operations on the electrical signals generated through operation of the cMUT elements 112. The manufacturing method for the first integrated circuit/transducer device 36 of the preferred embodiment includes the steps of depositing the lower electrode S102; depositing a sacrificial layer S104; depositing a dielectric layer S106; depositing the upper electrode S108; depositing a protective layer on the upper electrode S110; and removing the sacrificial layer S112. In the preferred embodiment, the manufacturing method also includes the step of depositing a sealant layer to seal a cavity between the lower electrode and the upper electrode S114.

Abstract: A pulsation attenuator for a fluidic system with a fluidic pump. The pulsation attenuator includes a fluidic channel, a first fluidic device adapted to attenuate pulsations with a shallow rolloff slope, and a second fluidic device adapted to attenuate pulsations with a shallow rolloff slope. The first fluidic device and the second fluidic device are connected to the fluidic channel such that they cooperatively attenuate pulsations with a steep rolloff slope. Preferably, the first fluidic device includes a first fluidic resistor and a first fluidic capacitor, and the second fluidic device includes a second fluidic resistor and a second fluidic capacitor. Preferably, the pulsation attenuator is arranged, similar a second-order low-pass filter, in the following order: (1) first fluidic resistor, (2) first fluidic capacitor, (3) second fluidic resistor, and (4) second fluidic capacitor.

Abstract: An optical system for guiding light from an interrogation zone to a detector system. The optical system includes an optical device, a first waveguide, and a second waveguide. The optical device is preferably adapted to collect and partition light into a first channel and a second channel of substantially similar light from a substantially singular orientation of the interrogation zone. The first waveguide is preferably adapted to guide the first channel from the optical device to a detector system without substantial interruption. Likewise, the second waveguide is preferably adapted to guide the second channel from the optical device to a detector system without substantial interruption. Preferably, the light of the first channel can be filtered without affecting the light of the second channel, and the light of the second channel can be filtered without affecting the light of the first channel.