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Fields & Applications Mass Spectrometry, Metabolomics & Lipidomics, Liquid Chromatography, Proteomics

Wound Healing in Diabetes

Chronic ulcerative wounds are a distressing and common complication of diabetes. To help determine the processes that prevent normal wound repair in diabetic patients, the McLean Research Group based at Vanderbilt University, Tennessee, used ion mobility-mass spectrometry (IM-MS) to analyze wound fluid (a complex brew of byproducts of the wound repair process) from sponges implanted into the wounds of diabetic and control rats. Here, Kelly M. Hines, lead author of the group’s recent paper (1) answers questions about the research.

What drove your interest in biomedical signatures?

The ion mobility-mass spectrometry (IM-MS) approach keeps the wound fluid intact. This allows a broad scale and untargeted investigation of the interactions between multiple types of molecules involved in the wound healing process. The approach spans the transition from untargeted to targeted analysis: differentially expressed molecules are revealed in the untargeted data set, while the guidance of statistical analysis and further experiments are performed in a targeted fashion to elucidate and validate their identities.

How did the results compare with your expectations?

It was interesting to observe biomolecular species in wound fluid that are similarly differentially expressed in the serum and blood of diabetics. Lysophoshatidyl choline (20:4), cholic acid and the protein S100A8 were associated with diabetes in previous studies, while S100A8 has been implicated in the wound healing process and diabetes. 

Why was UPLC-IM-MS chosen as the analytical tool?

For the initial untargeted analysis, electrospray ionization (ESI) was used, and ultra-performance liquid chromatography (UPLC) was introduced for the subsequent targeted analysis. The separation of multiple classes of biomolecular species in the IM dimension is greatly beneficial for the analysis of complex samples because it allows us to integrate various omics analyses in the same experiment with very little sample preparation. For example, it allows lipidomics, metabolomics, and proteomics to be performed simultaneously. Omics analyses by MS only typically requires extensive sample preparation to deplete the undesired species from the biological samples, reducing the native complexity of the sample. Using IM-MS, sample preparation procedures were reduced to dilution and desalting (for ESI). 

UPLC analysis was performed in a targeted manner to elucidate the source of the molecular species m/z 355 and 373, which were suspected to be in-source fragments of a common precursor. These species were shown to elute in the same chromatographic peak, and switching the instrument polarity from positive to negative ionization mode revealed the common precursor to be cholic acid.

What statistical analysis did you use?

The MarkerLynx XS software package from Waters. A combined scan method aligned the mass spectra, which were then normalized by the constant sum method. Partial least squares-discriminant analysis (PLS-DA) was used to visualize group differences and orthogonal PLS-DA was used to generate S-plots, from which the features contributing the most to the group differences were revealed.

Were there major challenges with the stats?

The most challenging aspect was data processing, but not necessarily due to the size of the ESI-IM-MS data set. Ideally, statistical analysis would be performed on data aligned by ion mobility drift times and m/z. However, most conventional software packages rely on peak alignment by chromatographic (liquid or gas) retention times and m/z, and are not yet suited to perform peak alignment by drift times. This is disappointing, as the ion mobility data could not be fully incorporated into the statistical analysis of the wound fluids. As IM-MS becomes more popular, the biostatistics software will likely be developed, which is also an active research pursuit of our group. We anticipate being able to extract even more information from these datasets in the future.

Image of Three-dimensional ion mobility-mass spectrum of diabetic rat wound fluid collected two days after sponge implantation

(a) Three-dimensional ion mobility-mass spectrum of diabetic rat wound fluid collected two days after sponge implantation. The dashed white box in (a) contains a 10 kDa protein, which was differentially expressed between diabetic (b) and control (c) wound fluids. Collision induced dissociation of signals corresponding to this species yielded a partial protein sequence from which the protein S100-A8 was identified. S100-A8 has been implicated in the onset of inflammation in both diabetes and wound healing. Figure courtesy of Kelly M. Hines and John A. McLean, Vanderbilt University.

How can the findings be applied?

The untargeted approach enables this platform to be used as a discovery tool; tracking treatment studies are one possible avenue to explore. In this particular study, the molecular species differentially expressed between the diabetic and nondiabetic groups, as well as between the diabetic groups at different time points could be useful in this regard. 

And biomedical signatures generally?

The IM-MS based approach to identifying biomolecular signatures of disease could be applied to any number of discovery-driven and targeted endeavors due to the unbiased nature of the analysis. In addition to wound fluid, our group has looked at human breast cancer tissue extracts, cerebrospinal fluids, cell lysates, serum, and microbial extracts. RW

The Experiment

Sample Collection and Preparation

Implanted sponges were removed and centrifuged to collect wound fluids. For IM-MS analysis, wound fluids were diluted, desalted, dried and reconstituted in 1:1 methanol: water for electrospray ionization.

System 

UHPLC: NanoAcquity UPLC (Waters), Acquity HSS C18 column (1.8 µm, 1.0 x 100 mm).  The UPLC analysis was performed online with a Synapt G2 

IM-MS (Waters), which utilizes electrodynamic traveling waves and nitrogen gas for ion mobility separations. Mass analysis was performed with orthogonal time-of-flight (oTOF) MS operating in single reflectron mode. The four-dimensional data set comprised of retention time, drift time, m/z and intensity.

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  1. K. M. Hines et al., “Biomolecular Signatures of Diabetic Wound Healing by Structural Mass Spectrometry,” Anal. Chem., 85, 3651 (2013)  (dx.doi.org/10.1021/ac303594m )
About the Author
Rich Whitworth

Rich Whitworth completed his studies in medical biochemistry at the University of Leicester, UK, in 1998. To cut a long story short, he escaped to Tokyo to spend five years working for the largest English language publisher in Japan. "Carving out a career in the megalopolis that is Tokyo changed my outlook forever. When seeing life through such a kaleidoscopic lens, it's hard not to get truly caught up in the moment." On returning to the UK, after a few false starts with grey, corporate publishers, Rich was snapped up by Texere Publishing, where he spearheaded the editorial development of The Analytical Scientist. "I feel honored to be part of the close-knit team that forged The Analytical Scientist – we've created a very fresh and forward-thinking publication." Rich is now also Content Director of Texere Publishing, the company behind The Analytical Scientist.

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