Thermo Scientific TruScan

Title: Handheld Raman Spectrometer

Product Overview

Thermo Scientific TruScan

Inspector
Thermo Scientific TruScan

True one handed operation design
Ergonomic Design
One handed operation of wristband, setting sample bottle insertion bag
Dual design of touch screen operation and thumb wheel operation, suitable for various testing situations

Inspector's Development History
In 1997, DeltaNu was established to develop portable Raman spectroscopy instruments.
In 2003, DeltaNu launched * generation Inspectors, which won the R&D 100 Innovation Award in the United States.
In 2006, DeltaNu launched the most compact and sturdy handheld Raman spectrometer Reporter.

In 2013, DeltaNu merged with SciAps to launch the new generation of InspectorTM handheld Raman spectrometers with detection capabilities.

Compliant with European Pharmacopoeia EP chapter 2.2.48 for instrument performance validation, rigorously tested according to ASTM E1840-96 standard, and meets FDA 1040.10 laser performance and safety standards

Compliant with FDA 21CFR Part 11 Electronic Signature&Tracking User Permission Classification Management Operation Record Keeping System PDF Printing Report

Fully enclosed design, each instrument undergoes strict waterproof and dustproof testing, meets IP67 rating standards, can be cleaned and disinfected, and can also be packaged in sterile clean bags for use.

Laser power adjustable in ten levels
Colored samples such as riboflavin (2) and bright red often absorb laser light and generate heat, causing sample decomposition, combustion, and burning through packaging bags
situation The darker the color, the more obvious the light absorption effect, and generally the instrument power is too high to test.

The design power of InspectorTM is linearly adjustable in ten levels from 0 to 300mW. By using low power to test colored samples, ideal detection results can be obtained. At the same time, the maximum power of 300mW meets the testing needs of most difficult to excite samples.

1030nm laser technology (optional)
Among common active pharmaceutical ingredients, about 20% of compounds with special structures, such as MCC (microcrystalline cellulose), produce fluorescence interference when exposed to 785nm laser irradiation. The fluorescence covers the Raman signal, making it impossible to obtain accurate information about the drug.

The 1030nm laser technology used in InspectorTM-500, coupled with a highly sensitive near-infrared light detector, eliminates the problem of fluorescent samples for users, greatly enhancing their detection capabilities and detection range.
Common raw materials with high fluorescence include cellulose (MCC, cross-linked carboxymethyl cellulose, etc.), biological proteins, gelatin, capsules, etc.

Free Light Path Design
The internal optical path of InspectorTM is only completed through professionally designed lenses, known as free optical path design.
The free optical path design of InspectorTM focuses the laser spot irradiated on the sample to the level of 25 microns, greatly improving the safety of users.
The micrometer level laser spot of InspectorTM makes the signal irradiated on the sample packaging (PE bag) extremely small, greatly reducing the interference of packaging materials on the detection results.
The free light path design of InspectorTM enables the instrument's luminous flux (the proportion of scattered light received by the detector) to reach a height of *, NA=0.55， This greatly improves the signal-to-noise ratio and sensitivity.
The free optical path design of InspectorTM has successfully achieved seamless integration with Olympus microscopes, making it convenient for users to perform micro area positioning analysis on samples such as tablets and powders.

Chemical stoichiometry methods
The model development method of InspectorTM adopts The Unscramber X (DeltaNu) 10.2 software developed in collaboration between SciAps and the industry's chemometric software, CAMO Norway. The Unscramber X 10.2, with over 25000 users, greatly improves the selectivity and tolerance of the chemometric algorithm, thereby minimizing the probability of erroneous judgments.

Technical parameters

Laser 1030 ± 0.5nm, 2cm-1, Class III B
Detector TE Refrigeration III-IV Semiconductor Array
Spectral resolution 8-10 cm-1
Spectral range 100-2500cm-1
Laser performance stability<0.1cm-1, in compliance with FDA 1040.10 laser performance and safety specifications
Luminous flux NA=0.55
Specification size (mm) 190 × 175 × 43; Weight (Kg) 1.7
Environmental temperature usage environment (℃) -20~40; Storage environment (℃) -30~60
The battery operates continuously for more than 4 hours.
规范 EP chapter 2.2.48 ； FDA 21CFR Part 11； FDA 1040.10； MIL-SPEC-810G； IP67； CE；Advanced 3Q&SOP