Combined Molecular and Mechanistic Methods for Detection of Pressure Ulcers

Purpose and aims A pressure ulcer (PU) is a localized injury to the skin and/or underlying tissue and develop from prolonged pressure on the skin. Such injuries are common in the healthcare setting, especially among vulnerable elderly. PUs greatly decrease the quality of life of individuals and are costly for the healthcare system. As many as 14% of the inpatients suffered from PUs in the Swedish country's municipalities and regions during 2022. The origin and timing of events leading to PUs are not fully understood, and current methods to assess the risk for an individual to develop a PU, are unreliable. Therefore, there is an urgent need to develop more objective, sensitive and specific methods for identifying early signs of tissue damage before they come visible and thus avoid development of PUs.

The investigators have previously identified a preliminary set of molecular biomarkers (cytokines and proteins), sampled non-invasively in the sebum, that reflects the inflammatory process under-pinning PU etiology and, possibly, individual susceptibility to pressure exposure. Therefore, it is hypothesize that non-invasive measurements of specific biomolecules on the skin surface, together with model-based analysis, can be used for individualized PU prediction. Accordingly, the purpose of this project is to confirm and expand on these preliminary findings in different PU risk scenarios to model the underlying inflammatory processes that reflect the individual vulnerability of the skin caused by pressure exposure and use modeling to extract a new layer of mechanistic insights of the underlying inflammatory process in different patient populations.

The specific aims of the project are:

1. To establish and validate optimal combinations of molecular biomarkers to identify individual susceptibility to pressure exposure during routine management regimes related to medical devises non-invasive ventilation (NIV) therapy.
2. To unravel key mechanisms in inflammatory processes related to early tissue damage by developing a mathematical model for the timing of events in the response to pressure, based on collected biomolecules, earlier data, and interaction databases
3. To identify risk factors of PU vulnerability on an individual level in routine clinical settings by combining biomolecules, model-based simulations, and clinical parameters