Resolution, Accuracy, and Sensitivity All in One Instrument
Feature 1: Ultra-high mass-resolution, ultra-high mass-accuracy
Built on JEOL's proprietary SpiralTOF ion optics, derived from the MULTUM II ion optics system developed at Osaka University, the NewSpiralTOF™ achieves an effective flight path of 17 meters in a compact instrument design. This advanced ion optical configuration combines high ion transmission with performance levels that are exceptional for MALDI-TOFMS: mass resolution of 75,000 and mass-accuracy of 1 ppm using internal calibration.
Feature 2: High quality data for everyone
A longer flight path does more than improve performance under ideal conditions. It also enhances day-to-day practicality by reducing the influence of specimen-surface irregularities, such as matrix crystal morphology on a target plate or surface variation in mass imaging specimens. This makes it easier for users to obtain high-quality, reproducible data under real-world operating conditions.
Feature 3: High sensitivity despite long flight path
Even with a long flight path, NewSpiralTOF™ maintains excellent sensitivity. Ion packets of the same mass are refocused at each cycle of the spiral trajectory, allowing the system to achieve high mass-resolution and high mass-accuracy without compromising high sensitivity.
Feature 4: Analysis of small molecules realized with very low chemical noise
Because the SpiralTOF ion optical system, which consists of electric sectors, also acts as an energy filter, fragment ions generated by PSD are prevented from passing through the analyzer. This is the key to its remarkably low chemical noise in the low-mass region and its superior performance for small-molecule analysis.
NewSpiralTOF™ High-Speed MS Imaging × High Mass-Resolution
In MALDI mass spectrometry imaging (MALDI-MSI), molecules are visualized directly within a specimen by coating the specimen surface with matrix, scanning it with a laser, and acquiring a mass spectrum at each position. This makes it possible to see where specific molecules are located and how much of them is present across a tissue section or other specimen surface.
High Mass-Resolution for Accurate MS Imaging
Thanks to its 17 m flight path, the NewSpiralTOF™ delivers high mass-resolution even when analyzing biological tissue sections with nonuniform surface conditions. In measurements of approximately half of a mouse brain over a region of about 5 × 7 mm, the system achieved a mass resolution of approximately 40,000 in the average mass spectrum. This high resolving power enabled the separation of isobaric lipid species such as phosphatidylcholine (PC), phosphatidylethanolamine (PE), and galactosylceramide (GalCer), making it possible to obtain the correct spatial distribution for each molecule.
PE: Phosphatidyl ethanolamine, PC: Phosphatidyl Choline, GalCer: Galactosylceramide
This data was acquired in a joint research project with the Mass Spectrometry Group, Project Research Center for Fundamental Sciences, Graduate School of Science, Osaka University. The tissue section specimen was provided by Awazu Laboratory, Division of Sustainable Energy and Environmental Engineering, Graduate School of Engineering, Osaka University.
AI-Enhanced Image Quality for MS Imaging
JEOL has a long history of innovation in image processing, driven by its leadership in electron microscopy. Building on this expertise, JEOL adapted its AI-based image enhancement technology LIVE-AI (Live Image Visual Enhancer-AI), originally developed for SEM, to MS imaging data processing and implemented it as the FINE-AI Filter. The result is a substantial improvement in the clarity and interpretability of mass images.
Automatic Extraction of Important Features
With the high mass-resolution of the NewSpiralTOF™, more than 100 lipid species were detected in mouse brain sections. However, interpreting the distribution of each lipid individually is not practical. Meaningful insight requires statistical tools that can identify groups of components that vary together and summarize complex datasets efficiently.
To address this, vertex component analysis (VCA), a method that models all spectra in a mass imaging dataset as mixtures of a small number of "vertex components" is implemented. Compared with methods such as principal component analysis, VCA provides results that are easier to interpret in a shorter time. Because VCA is sensitive to noise, applying it after denoising with the FINE-AI Filter makes the analysis far more effective. In the example shown, this approach revealed three key vertex components characterizing lipids in mouse brain tissue.
Features and usages of TOF-TOF option and linear TOF option
The TOF-TOF option extends the analytical power of the NewSpiralTOF™ by using SpiralTOF ion optics in the first MS stage, enabling high precursor-ion selectivity and accurate selection of the monoisotopic precursor ions. Combined with high energy collision-induced dissociation (HE-CID), the system generates product-ion spectra rich in structural information. JEOL's proprietary offset parabolic reflectron further strengthens TOF-TOF performance by allowing simultaneous acquisition of product-ion information from m/z 5 up to the precursor ion. This provides comprehensive fragment information and supports highly reliable structural analysis.
A representative example is the analysis of reserpine and its photodegradation product. Because reserpine is photolabile, its solution degrades under ordinary room light. The degradation product differs by 2 Da, suggesting the loss of two hydrogen atoms. Thanks to the high precursor selectivity of the TOF-TOF option, the NewSpiralTOF™ successfully acquired separate product-ion spectra for both reserpine and its degradation product directly from a mixture, enabling structural characterization of each species.
With the Linear TOF option, ions travel directly from the ion source to the detector. If post-source decay occurs during flight, the resulting fragment ions and neutral species continue at the same velocity as the precursor and are detected as the same signal. This makes Linear mode particularly effective for the high-sensitivity analysis of high-mass compounds that are prone to PSD. Used together, Spiral mode and Linear mode broaden the range of analytes that can be measured.
The application examples are the confirmation of the molecular weight distribution of polymers above 100 kDa and the measurement of the molecular weight of immunoglobulin G (IgG), a glycoprotein of approximately 150 kDa.
The 3D structure of IgG (PDB ID: 1IGY) based on L.J. Harris, et al., J Mol Biology, 275: 861-872 (1998), by using Mol* Viewer, D. Sehnal, et al., Nucleic Acids Research 49: W431-W437 (2021), available on RCSB PDB (RCSB.org), H.M. Berman, et al., Nucleic Acids Research 28: 235-242 (2000)
Stable Performance with a Contamination-Resistant Ion Source
In MALDI ion sources, much of the desorbed matrix leaves the target as neutral particles, and some of this material adheres to the ion extraction electrode. In conventional MALDI-TOFMS systems, contamination can accumulate unevenly on the aperture lens, leading to uneven charging and deflection of ion trajectories. This degrades both sensitivity and mass resolution, making frequent cleaning necessary.
To overcome this issue, the NewSpiralTOF™ uses a fine, high open-area (> 82%) ion extraction grid. Because less contamination accumulates overall, and because the ion-optical properties of the grid reduce the impact of any charge that does build up, ion trajectories remain stable even over long-term use. The result is maintenance-free operation with sustained high sensitivity and high mass-resolution.