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Medical swab analysis using desorption electrospray ionization mass spectrometry (DESI-MS) – a non-invasive approach for mucosal diagnostics Pamela Pruski, David A. MacIntyre, Holly Victoria Lewis, Paolo Inglese, Goncalo dos Santos Correia, Trevor T. Hansel, Phillip R. Bennett, Elaine Holmes, and Zoltan Takats Anal. Chem., Just Accepted Manuscript • DOI: 10.1021/acs.analchem.6b03405 • Publication Date (Web): 27 Dec 2016 Downloaded from http://pubs.acs.org on December 29, 2016

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Medical swab analysis using desorption electrospray ionization mass spectrometry (DESI-MS) – a non-invasive approach for mucosal diagnostics

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Pamela Pruski†, David A. MacIntyre°, Holly V. Lewis°, Paolo Inglese†, Gonçalo DS Correia†, Trevor T. Hanselˠ, Phillip R. Bennett°, Elaine Holmes†, Zoltan Takats†*

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Campus, London, SW7 2AZ (UK)

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°

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Biology, Imperial College London, London W12 0NN, (UK)

Computational and Systems Medicine, Imperial College London, South Kensington Imperial College Parturition Research Group, Institute of Reproductive and Developmental

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ˠ

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Imperial College London, W2 INY, (UK)

Imperial Clinical Respiratory Research Unit (ICRRU), St Mary’s Hospital, Mint Wing,

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* Corresponding Author: Professor Zoltan Takats, Division of Computational and Systems

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Medicine, Department of Surgery and Cancer, Imperial College London, South Kensington

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Campus, Sir Alexander Fleming Building, London, SW7 2AZ. Telephone: 020 7594 2760.

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Email: [email protected]

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Abstract. Medical swabs are routinely used worldwide to sample human mucosa for

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microbiological screening with culture methods. These are usually time consuming and have

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a narrow focus on screening for particular microorganism species. As an alternative, direct

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mass spectrometric profiling of the mucosal metabolome provides a broader window into the

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mucosal ecosystem. We present for the first time a least effort/least-disruption technique for

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augmenting the information obtained from clinical swab analysis with mucosal metabolome

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profiling using DESI-MS analysis. Ionisation of mucosal biomass occurs directly from a

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standard rayon swab mounted on a rotating device and analysed by DESI MS using an

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optimised protocol considering swab-inlet geometry, tip-sample angles and distances,

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rotation speeds and reproducibility. Multivariate modelling of mass spectral fingerprints

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obtained in this way readily discriminate between different mucosal surfaces and display the

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ability to characterise biochemical alterations induced by pregnancy and bacterial vaginosis

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(BV). The method was also applied directly to bacterial biomass to confirm the ability to

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detect intact bacterial species from a swab. These results highlight the potential of direct

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swab analysis by DESI-MS for a wide range of clinical applications including rapid mucosal

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diagnostics for microbiology, immune responses and biochemistry.

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Human mucosae are primary sites of contact and exchange with an organism’s external

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environment. Mucosal surfaces not only act as a physical barrier for selective access

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pathogen entry, but also as a complex ecosystem where multiple microbial species interact

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among each other and with the host via the innate and acquired immune response

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Through extensive chemical interactions, including excretion of antimicrobial compounds or

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co-metabolism, host, symbiont and pathogen alike compete for niche dominance

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However, an imbalance of the mucosal ecosystem caused by bacterial colonization can lead

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to disease. For example, a stable environment of Lactobacillus spp. colonisation during

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pregnancy protects against pathobiont colonisation of the reproductive tract, which is

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strongly associated with increased risk of preterm birth and neonatal loss

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mucosal cytokines reflect allergic inflammation, viral infection and asthma 6. Mucosal

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analysis thus represents an important and expanding field with wide clinical applications and

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huge diagnostic potential 7.

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Medical cotton swabs are the standard mucosal sampling device and have been long used,

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for microbiological culture, drug testing and genetic screening. Conventionally, swabs of

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mucosal surfaces are used for culture-based characterisation of microbial colonization.

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Commercial platforms using Matrix Assisted Laser Desorption Ionisation Time of Flight

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(MALDITOF) MS based analysis of bacterial proteins (e.g. Bruker MALDI Biotyper and

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bioMerieux VITEK MS) facilitate strain-level identification of bacteria from isolated, purified

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cultures

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addition of matrix to assist lysis and ionisation. Culture-independent approaches are also

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increasingly used for characterisation of microbial composition in clinical samples. These

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methods largely rely upon next-generation sequencing of hypervariable regions of the 16S

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rRNA subunit of bacteria using region-specific primers and high-throughput DNA sequencing

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10,11

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host interactions. Integration of LC MS-derived metabonomic data with microbiomic data has

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recently been used to evaluate host-microbiota interactions in mucosal samples in collected

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from women with bacterial vaginosis, a common vaginal condition characterised by reduction

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in commensal Lactobacillus species, elevated pH and a malodorous discharge12,13.

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Moreover, BV is accompanied by increased diversity of anaerobic bacteria in the vaginal

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microbiome including Atopobium, Gardnerella, Prevotella, Megasphaera, Dialister and

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several other bacteria. These studies showed that these BV-associated bacteria (BVAB)

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increase vaginal pH by producing short chained fatty acids (SCFA, e.g. butyrate, succinate

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and propionate) and polyamines (e.g. putrescine and cadaverine) and are also capable of

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utilizing lactic acid as an energy source. Despite the quality of the information provided by

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4,5

1,2

.

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. Similarly, nasal

). However, these methods are limited to cultivatable bacterial and require the

. However none of the aforementioned approaches have the ability to assess bacterial-

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LC-MS and 16S rRNA, it has limited application for clinical point of care (POC)-diagnostics

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due to extensive and time-consuming sample preparation and extraction protocols.

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For routine clinical application, faster and simpler methodologies are desirable to enable real

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time metabolic profiling that could assist in the generation of objective, effective and

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immediate biochemical data to inform clinicians and direct personalized treatment strategies.

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As an alternative to LC-MS analysis, ambient ionization MS techniques permit rapid and cost

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effective metabolic profiling of unmodified and complex biological materials, including

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bacteria, without the need for sample preparation

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applications

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all on the same principle, which is to generate gas phase ions directly from the samples,

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without the need of chromatographic separation or sample preparation resulting in a

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straightforward handling and rapid analysis of intact biofluid. Paper spray (PS) MS has been

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already introduced as one of a main potential ambient ionization technique for POC testing,

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which allows the quantification of analytes in dried samples spots of blood, plasma, urine

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and oral fluid. Moreover, PS MS has been shown to readily discriminate between sixteen

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different cultures bacteria species

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wooden tip electrospray, coated blade spray and touch spray were which introduce the

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concept of simultaneous sample collection and ionization directly from the surface of the

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sampling device

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glycerophospholipids of cultured strep throat causing bacterial species using a metallic

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modified medical swab device

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application of touch spray MS as a semi-quantitative MS method for direct oral fluid drug

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testing

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samples for POC diagnostic using touch spray MS has yet to be demonstrated. In a different

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study, Bregy et al. used secondary electrospray ionisation (SESI) MS on saliva to identify 18

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potential markers from a single periodontitis patient with confirmed infection where the

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obtained metabolic profile was compared with 120 in vitro detected compounds from four

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cultures periodontal pathogens

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volatile and semi-volatile compounds e.g. fatty acids it is therefore more suitable for direct

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, enabling a wide range of POC

. To date, more than 80 ambient ionization techniques are known, that work

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. Other examples of direct sampling analysis include

. For microbiological analysis, touch spray MS was used to profile 17

. Furthermore, the same group has extended the potential

. However, to date, the detection of bacterial associated metabolites in real clinical

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. But since SESI-MS covers preferably the detection of

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headspace analysis including exhaled breath samples.

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Another widely more established ionization technique for direct analysis of clinical sample is

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desorption electrospray ionization (DESI) MS

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technique to MALDI MS or secondary ionization mass spectrometry (SIMS), also suitable for

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the rapid analysis of samples under ambient conditions and on arbitrary sample surfaces

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In DESI, a pneumatically-assisted electrospray of charged aqueous droplets is directed onto

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a sample, where it then forms a liquid film that gently dissolves molecules from the sample

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. DESI is a comparably soft ionization

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and desorbs secondary charged micro droplets. A subsequent ESI-like process occurs,

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leading to the formation of gaseous ions of analytes, which are directed via the usual

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atmospheric pressure to the vacuum ion optics interface. DESI has also proved applicable

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for the ionization of a variety of compounds including lipids, peptides, proteins or drug

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molecules

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analysis but also for discriminating purified bacterial samples at species and subspecies

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level from a glass slide or directly from the agar plate using DESI or nano-DESI MS following

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statistical PCA analysis

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proposed but not yet been demonstrated 29.

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In this study, we describe an analytical protocol for direct analysis of standard medical

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swabs, by DESI-MS (Figure 1). No modified swabs or alterations to the default clinical

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sample collection protocols for microbial analysis are required. We illustrate the potential of

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the method with analysis of human mucosa samples, including vaginal mucosa samples

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acquired in a clinical setting. We aimed to extend the DESI-MS application to direct analysis

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of standard medical swabs for rapid assessment of mucosal chemistry perturbations and the

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development of a novel, non-invasive POC-diagnostic technique.

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Experimental Section

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Reagents and materials. All chemicals used were analytical reagent grade. HPLC grade

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methanol and water for DESI-MS analysis were purchased from Sigma Aldrich (St Louis,

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MO). Human plasma was purchased from Sigma Aldrich (St Louis, MO).Transwab® Amies

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medical rayon swabs provided by MWE medical wire (Wiltshire, UK) were used for mucosal

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sampling.

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Sample collection. Written, informed consent was provided from all patients prior to sample

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collection. 20 volunteer subjects contributed nasal fluid according to NHS REC ethical

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protocol RESPI-SAM (15/LO/0444). Oral mucosa samples were taken from the inner cheek

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cavity of the mouth from 15 volunteers. For the vaginal mucosa study samples were

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obtained from 23 non-pregnant healthy volunteers (13/LO/0126) and from 43 pregnant

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healthy women according the ethical protocol VMet2-Vaginal Microbiome and Metabonome

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in Pregnancy (14/LO/0328) at Queen Charlotte’s and Chelsea Hospital, Imperial College

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Healthcare NHS Trust (London, UK). Exclusion criteria included HIV positive women and

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women who had had sexual intercourse or vaginal bleeding in the preceding 48 h prior to

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sampling. Vaginal secretions were collected by a trained clinician by placing the cotton swab

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in the vaginal cavity for 5 s; transferred to a sterile tube without buffer or storage medium

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solution and stored at -80 °C in the freezer. Matched vaginal swabs were also sent for

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clinical microbial assessment and diagnosis of BV was performed via the Hay/Ison criteria

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. DESI MS provides high specifity, selectivity and sensitivity for direct tissue

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. Direct analysis of gastrointestinal mucosa by DESI has been

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and assessment of gram staining30. Gestational age at sampling varied from 12 to 40 weeks

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of gestation for pregnant women.

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To examine inter-swab variability, quality control swabs were prepared by first precipitating

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human plasma using a 4 to 1 ratio of ice-cold acetonitrile and incubating for 1h at -80°C. The

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precipitate was recovered following removal of the supernatant after centrifugation (1000 x g

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for 10 seconds). The precipitate was dried for approximately 2h at room temperature until

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reaching a gel-like consistency. The pellet was then distributed uniformly on the swab

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surface rotating the swab on aluminium foil so that each swab contained approximately 50

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mg of plasma precipitate (see Supplementary Information, Figure S1).

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DESI-MS swab analysis. The in-house built DESI source mounted on the mass

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spectrometer consists of an electronic spray emitter and an automatic rotatable swab holder

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that are separately secured onto a 3D manual moving stage. The sample holder consists of

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a rotor for controlled rotation of the medical swab followed by a plastic tube to stabilize the

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swab and prevent sideway tripping during rotation. All experiments were performed on a

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LTQ-Orbitrap Discovery mass spectrometer (Thermo Scientific, Bremen, Germany) and

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Xevo G2-S Q Tof (Waters, Manchester, UK) mass spectrometer. The DESI source operating

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parameters and instrumental settings are listed in Table 1. All samples were randomised

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prior to analysis, to avoid bias in the statistical analysis due to analytical batch effects. For

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DESI-MS analysis the medical swabs were fixed into the swab holder and positioned

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orthogonally in front of the MS inlet capillary with a swab-capillary distance of less than 2

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mm. The DESI sprayer was directed to the centre of the medical swab with a tip-sample

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distance between 1.5-2 mm and an altitude difference between the tip and the inlet capillary

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of 2 mm. The entire surface of the medical swabs was analysed by DESI through clockwise

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rotation of the swab toward the MS capillary. For desorption of the sample material a mixed

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methanol:water solution (95:5, v:v) spray solvent was used for DESI measurement. The

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mucosal membrane was absorbed from the swab tip by gently desorbing the molecules with

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charged droplets of organic solvent and subsequently transferred to the mass spectrometer

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for analysis. Full scan mass spectra (m/z 50-1000, R = 30.000 (FWHM)) were recorded in

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the negative and positive ion mode.

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For microbial culture samples, a loop scraping of biomass was diluted into 50 µL of methanol

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before a swab was rapidly dipped into the solution and DESI-MS analysis was performed on

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the swab surface.

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Mass spectral data pre-processing. Raw mass spectral data were converted from .raw

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files into .mzML format via the ProteoWizard msConverterGUI (Vanderbilt University,

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Nashville, TN, USA)

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package

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0.01 ∆m/z and an averaged mass spectrum obtained by averaging all the scans in a

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measurement (in average 30 scans), thus obtaining a matrix of mass spectral profiles. For

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peak detection, Savitzky-Golay smoothing

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window increasing linearly with the m/z value was applied before detection of local maximum

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by analysis of second and first derivatives. The peaks detected in each samples were

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matched sequentially (window of 0.01 m/z). Peaks only detected in less than 10 samples

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(50% of samples in the smallest of the mucosal types, nasal mucosa) were discarded,

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resulting in a final peak list of 926 peaks in negative mode and 2418 peaks in positive mode.

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Two other versions of this peak matrix were generated by applying TIC and probabilistic

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quotient normalization (see Supplementary Information, Figure S2).

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Multivariate statistical analysis. Data was analysed in the same manner in parallel using

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the non-normalized, TIC and PQN

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and effect of normalization on model quality and discriminatory variables. Principal

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component analysis (PCA) was used for unsupervised analysis of the data set and

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visualisation of general clustering trends. For the group discrimination analyses (nasal vs

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oral vs vaginal mucosa and pregnant vs non-pregnant), a random forest classifier

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used (number of trees; n = 400). Feature importance was calculated by checking the out-of-

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bag error after permuting the data. Model fitting and feature importance evaluation were

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performed using the ‘randomForest’ R package

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random forest models was validated through leave one out cross validation (CV). This

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procedure involved leaving out one sample from the sample set and calculation of a new

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model using the remaining data set. Statistical measures including sensitivity (TPR),

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specificity (TNR), positive predictive value and negative predictive value. No outliers were

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removed for any of the analyses described. The distribution of the identified features was

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visualised by violin plots, which feature a kernel density estimation of the underlying

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distribution. P-values for each peak were calculated by using the Kruskal Wallis rank sum

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test and were assigned to be statistical significant with p