The InSUS 607 single-use DO sensor is designed for integration into single-use bags. This single-use DO sensor uses optical technology to provide fast, accurate dissolved oxygen measurement.
Reliable Measurements
This single-use DO sensor uses optical spot (fluorescence quenching) technology to give a consistent, reliable measurement.
Stable Performance
This single-use DO sensor provides stable performance for long cell culturing runs, ensuring that your sensor will last through the full batch.
Reduced Start-Up Time
The short pre-conditioning phase of optical dissolved oxygen sensors like the InSUS 607 single-use DO sensor ensures quick start-up time.
Shelf life | 36 months dry storage |
Short description | Optical dissolved oxygen sensor |
Sensing Elements | Optical spot (Fluorescensce quenching) |
Integrated Temperature Probe | Pt1000 |
Measurement range | 0…250% air |
Calibration | 1-point air |
Shaft materials | High density polyethylene, USP 88 class VI |
O-ring material | EPDM, USP 88 class VI |
Process connection | Eldon James 1' port disc |
Gamma ray sterilizable | 25…45 kGy |
Operating temperature | 5…60°C (41…140°F) |
Storage temperature | 5…25°C (41…77°F) |
Mechanical pressure resistance | "2 barg / 40 °C (29 psig / 104 °F), 1 barg / 60 °C (15 psig / 140 °F)" |
Approvals | USP 88 class VI for all wetted polymer parts |
Measurement Parameter | Oxygen |
Measurement Technology | Optical fluorescence quenching |
Ensure Process Safety
All wetted polymer materials used on the InSUS 607 single-use DO sensor are made of USP 88 class VI certified materials to ensure the highest process safety.
Easy-to-Integrate
The InSUS 607 single-use DO sensor uses a standard 1" Eldon James port disc. This unified design allows for safe and easy installation on a broad range of applications, including cell culturing, harvesting, and fermentation.
Reliable Output Signals
The output signal on the single-use DO sensor set-up is identical to the output for METTLER TOLEDO resuable DO sensors. This allows for seamless integration into existing transmitters and biocontroller process environments.