iMatrixSpray: a free and open source sample preparation device for mass spectrometric imaging.

A device was built for matrix deposition in mass spectrometric imaging. This spray-type instrument requires no user interaction other than providing the spray solution and selecting the pre-defined or custom-built method. Robustness was achieved by utilizing a delta-robotics design in combination with a simple liquid system. All the information describing the systems is provided as open source and hardware and the design is therefore suitable for wide distribution and adaption by the scientific community.

Transgenic expression of intraneuronal Aß42 but not Aß40 leads to cellular Aß lesions, degeneration, and functional impairment without typical Alzheimer's disease pathology.

An early role of amyloid-ß peptide (Aß) aggregation in Alzheimer's disease pathogenesis is well established. However, the contribution of intracellular or extracellular forms of Aß to the neurodegenerative process is a subject of considerable debate. We here describe transgenic mice expressing Aß1-40 (APP47) and Aß1-42 (APP48) with a cleaved signal sequence to insert both peptides during synthesis into the endoplasmic reticulum. Although lower in transgene mRNA, APP48 mice reach a higher brain Aß concentration. The reduced solubility and increased aggregation of Aß1-42 may impair its degradation. APP48 mice develop intracellular Aß lesions in dendrites and lysosomes. The hippocampal neuron number is reduced already at young age. The brain weight decreases during aging in conjunction with severe white matter atrophy. The mice show a motor impairment. Only very few Aß1-40 lesions are found in APP47 mice. Neither APP47 nor APP48 nor the bigenic mice develop extracellular amyloid plaques. While intracellular membrane expression of Aß1-42 in APP48 mice does not lead to the AD-typical lesions, Aß aggregates develop within cells accompanied by considerable neurodegeneration.

High-sensitivity MALDI-MRM-MS imaging of moxifloxacin distribution in tuberculosis-infected rabbit lungs and granulomatous lesions.

MALDI-MSI is a powerful technology for localizing drug and metabolite distributions in biological tissues. To enhance our understanding of tuberculosis (TB) drug efficacy and how efficiently certain drugs reach their site of action, MALDI-MSI was applied to image the distribution of the second-line TB drug moxifloxacin at a range of time points after dosing. The ability to perform multiple monitoring of selected ion transitions in the same experiment enabled extremely sensitive imaging of moxifloxacin within tuberculosis-infected rabbit lung biopsies in less than 15 min per tissue section. Homogeneous application of a reference standard during the matrix spraying process enabled the ion-suppressing effects of the inhomogeneous lung tissue to be normalized. The drug was observed to accumulate in granulomatous lesions at levels higher than that in the surrounding lung tissue from 1.5 h postdose until the final time point. MALDI-MSI moxifloxacin distribution data were validated by quantitative LC/MS/MS analysis of lung and granuloma extracts from adjacent biopsies taken from the same animals. Drug distribution within the granulomas was observed to be inhomogeneous, and very low levels were observed in the caseum in comparison to the cellular granuloma regions. In this experiment the MALDI-MRM-MSI method was shown to be a rapid and sensitive method for analyzing the distribution of anti-TB compounds and will be applied to distribution studies of additional drugs in the future.

Dynamics of Abeta turnover and deposition in different beta-amyloid precursor protein transgenic mouse models following gamma-secretase inhibition.

Human beta-amyloid precursor protein (APP) transgenic mice are commonly used to test potential therapeutics for Alzheimer's disease. We have characterized the dynamics of beta-amyloid (Abeta) generation and deposition following gamma-secretase inhibition with compound LY-411575 [N(2)-[(2S)-2-(3,5-difluorophenyl)-2-hydroxyethanoyl]-N(1)-[(7S)-5-methyl-6-oxo-6,7-dihydro-5H-dibenzo[b,d]azepin-7-yl]-L-alaninamide]. Kinetic studies in preplaque mice distinguished a detergent-soluble Abeta pool in brain with rapid turnover (half-lives for Abeta40 and Abeta42 were 0.7 and 1.7 h) and a much more stable, less soluble pool. Abeta in cerebrospinal fluid (CSF) reflected the changes in the soluble brain Abeta pool, whereas plasma Abeta turned over more rapidly. In brain, APP C-terminal fragments (CTF) accumulated differentially. The half-lives for gamma-secretase degradation were estimated as 0.4 and 0.1 h for C99 and C83, respectively. Three different APP transgenic lines responded very similarly to gamma-secretase inhibition regardless of the familial Alzheimer's disease mutations in APP. Amyloid deposition started with Abeta42, whereas Abeta38 and Abeta40 continued to turn over. Chronic gamma-secretase inhibition lowered amyloid plaque formation to a different degree in different brain regions of the same mice. The extent was inversely related to the initial amyloid load in the region analyzed. No evidence for plaque removal below baseline was obtained. gamma-Secretase inhibition led to a redistribution of intracellular Abeta and an elevation of CTFs in neuronal fibers. In CSF, Abeta showed a similar turnover as in preplaque animals demonstrating its suitability as marker of newly generated, soluble Abeta in plaque-bearing brain. This study supports the use of APP transgenic mice as translational models to characterize Abeta-lowering therapeutics.

Biophotonics applied to proteomics.

Since the completion of the human genome sequencing, our understanding of gene and protein function and their involvement in physiopathological states has increased dramatically, partly due to technological developments in photonics. Photonics is a very active area where new developments occur on a weekly basis, while established tools are adapted to fulfill the needs of other disciplines like genomics and proteomics. Biophotonics emerged at the interface of photonics and biology as a very straightforward and efficient approach to observe and manipulate living systems. In this chapter, we review the current applications of photonics and imaging to proteomics from 2D gels analysis to molecular imaging.

Imaging of a beta-peptide distribution in whole-body mice sections by MALDI mass spectrometry.

Mass spectrometric imaging was applied to assess compound distributions on whole-body sections of mice after i.v. dosing of a beta-peptide and an alpha-peptide control. Animals were sacrificed at different time points (5 min, 1 h, 24 h) post-dose, providing simultaneous spatial as well as kinetic information. As a result of this study, no detection of the alpha-peptide control was observed at 1 h post-dose, while retention of the beta-peptide was observed for longer than 24 h post-dose.

MALDI MS imaging of amyloid.

Label-free molecular imaging by mass spectrometry allows simultaneous mapping of multiple analytes in biological tissue sections. In this chapter, the application of this new technology to the detection Abeta peptides in mouse brain sections is discussed.

MALDI mass spectrometric imaging of biological tissue sections.

In biomedical research, the discovery of new biomarkers and new drugs demands analytical techniques with high sensitivity together with increased throughput. The possibility to localize or to follow changes in organisms at the molecular level by imaging component distributions of specific tissues, is of prime importance to unravel biochemical pathways and develop new treatments and drugs. Established molecular imaging techniques such as MRI and PET are already widely used, however their need for molecular probes to report the presence of the analytes of interest precludes the simultaneous exploration of different biomolecules. Matrix-assisted laser desorption/ionization mass spectrometric imaging (MALDI MSI) takes full advantage of the high sensitivity of mass spectrometry instrumentation but also of the ability of the latter to simultaneously detect a wide range of compounds, almost regardless from their nature and mass. To perform MALDI MSI, sections of biological tissues are introduced in an MALDI MS instrument, where the UV pulsed laser of the MALDI source is used to raster over a selected area while acquiring mass spectra of the ablated ions at every image point. From this array of spectra, hundreds of analyte-specific images can be generated based on the selected masses. MALDI MSI can be used to track biomarkers such as peptides or proteins but also to map drug/tissue interactions. In this paper, an overview of the possibilities of MSI will be given. As an example, MSI on brain tissue sections for the study of Alzheimer's disease (AD) will be shown. Mapping of amyloid peptides as a new approach for drug lead optimization will be presented. Target identification thanks to MSI will be introduced and the last part will be dedicated to the molecular scanner approach, which gives access to high-mass range by combining tissue blotting and digestion in a one-step process.

Reproducible Matrix Deposition for MALDI MSI Based on Open-Source Software and Hardware.

The new open-source software and hardware matrix deposition device named iMatrixSpray was optimized and specified for homogeneity, reproducibility, and sensitivity in MS imaging experiments. The results confirm the design claims, with the device delivering uniform coatings with a constant quality from experiment to experiment. The robustness in combination with the open design allows developing and sharing of matrix deposition and sample preparation protocols between labs. This tool therefore enables researchers to enter the field of MALDI MSI without previous experience in matrix coating.

Evaluation of sparfloxacin distribution by mass spectrometry imaging in a phototoxicity model.

Mass spectrometry imaging (MSI) was applied to samples from mouse skin and from a human in vitro 3D skin model in order to assess its suitability in the context of photosafety evaluation. MSI proved to be a suitable method for the detection of the model compound sparfloxacin in biological tissues following systemic administration (oral gavage, 100 mg/kg) and subsequent exposure to simulated sunlight. In the human in vitro 3D skin model, a concentration-dependent increase as well as an irradiation-dependent decrease of sparfloxacin was observed. The MSI data on samples from mouse skin showed high signals of sparfloxacin 8 h after dosing. In contrast, animals irradiated with simulated sunlight showed significantly lower signals for sparfloxacin starting already at 1 h postirradiation, with no measurable intensity at the later time points (3 h and 6 h), suggesting a time- and irradiation-dependent degradation of sparfloxacin. The acquisition resolution of 100 µm proved to be adequate for the visualization of the distribution of sparfloxacin in the gross ear tissue samples, but distinct skin compartments were unable to be resolved. The label-free detection of intact sparfloxacin was only the first step in an attempt to gain a deeper understanding of the phototoxic processes. Further work is needed to identify the degradation products of sparfloxacin implicated in the observed inflammatory processes in order to better understand the origin and the mechanism of the phototoxic reaction.

Applications of MALDI-MSI to pharmaceutical research.

MALDI-MSI has been demonstrated to be a suitable technique in pharmaceutical research for providing information of the distribution of low molecular weight compounds such as drugs and their metabolites within whole-body tissue sections. Important ADME information can be determined by MALDI-MSI analysis of the distribution of drugs and metabolites in whole-body tissue sections taken from animals killed at a range of time points postdose. In this example we applied MALDI-MSI to the localization of a compound and its primary metabolite in whole-body mouse sections.

Spatial and spectral correlations in MALDI mass spectrometry images by clustering and multivariate analysis.

Matrix-assisted laser desorption/ionization mass spectrometry imaging is a technique for direct analysis of tissue sections without the use of molecular tags or contrast agents. The combination of spatial and mass resolution results in large and complex data sets that require powerful and efficient analysis and interpretation tools. Conventional images, derived from a specific analyte mass, do not identify the spatially localized correlations between analytes that are latent in the data. A new approach to find and visualize these correlations is presented. Clustering methods are used to classify pixels by spectral similarity, facilitating definition of distinct spatial regions. Principal component and discriminant analyses are combined to comprehensively identify changes in the mass spectra between regions. Images are generated by projecting the spectra of each pixel on the discriminant spectra; contrast is then a function of multiple correlated peaks.

Molecular imaging of amyloid beta peptides in mouse brain sections using mass spectrometry.

A method is presented for direct spatial analysis of amyloid beta peptides in biological tissue sections. The technique takes advantage of the very high sensitivity of matrix-assisted laser desorption/ionization mass spectrometry and is implemented on a commercial instrument with modifications to only a few components and the software. With this setup, hundreds of molecular images can be generated simultaneously and within just a few minutes. The current features are an instrumental resolution of 50 microm and a sensitivity down to the attomol range. This new technology is applied to the study of amyloid beta peptide distribution in brain sections from mice, showing features reminiscent of Alzheimer's disease.