Understanding the pathogenesis of steatocystoma multiplex
Grantee: Edel O'Toole, Professor, Queen Mary University of London
Amount: DKK 2,846,085
Grant category: Research Grants in open competition
Year: 2021
Geography: United Kingdom
This project, led by Edel O’Toole, aims to give new insights into the rare genetic skin disease, steatocystoma multiplex (SM) that may contribute to the development of a new treatment for affected individuals.
SM is a debilitating and embarrassing disorder, which presents as multiple smooth, yellow skin lumps or cysts distributed on the arms, trunk, neck, and underarm area. The lesions usually appear in the teenage years and for the severely affected patients with 100s to 1000s of cysts, these are a major burden causing disability and pain with frequent inflammation often mimicking infection.
The most common genetic defect is found in the gene coding for Keratin 17, a protein expressed in nails, hair follicles, skin on the palms and soles, and in sebaceous glands. The cysts in SM are believed to arise from the lining of these glands. The team will use single cell RNA sequencing and look at gene expression in individual cells lining the cyst and from the surrounding tissue, to understand the genetic differences. In parallel, the O’Toole group will engineer cells from the sebaceous gland with and without the defect in the Keratin 17 gene. These cells will be used to form 3D skin models and cysts that mimic SM. Finally, drugs that target pathways of interest identified from the RNA sequencing will be used to ‘treat’ the 3D model, thereby adding to the many insights around SM expected from this project.
New diagnostic tool for scleroderma based on the detection of non-coding RNA biomarkers from skin interstitial fluid
Grantee: Claire Higgins, Senior Lecturer, Imperial College London
Amount: DKK 3,436,300
Grant category: Research Grants in open competition
Year: 2021
Geography: United Kingdom
Claire Higgins’ project aims to develop an early-stage diagnostic tool for scleroderma, a disease caused by an overproduction of collagen in both the skin and connective tissues, leading to a scarring of the skin and internal organs.
Among the early symptoms of scleroderma are poor blood circulation in fingers and toes, and an increased sensitivity to cold, which in many aspects is comparable to the much more common Raynaud’s phenomenon, and hence, scleroderma is often undiagnosed.
Utilizing the fact that certain molecules change expression level during disease (‘biomarker’ molecules), Claire Higgins aims to identify scleroderma-specific biomarkers in the liquid between individual skin cells, i.e., in the skin interstitial fluid. The identified biomarkers will be used to develop a non-invasive and painless test for general practitioners (GPs), enabling fast diagnosis – within minutes – and thereby differentiation between patients suffering from scleroderma and Raynaud’s phenomenon. Thus, patients will be able to get the most relevant intervention as early as possible. The actual diagnostic test will be developed along with the biomarker identification.
Developing 1600 nm OCT angiography to quantify severe inflammatory epidermal hyperplasia in atopic dermatitis
Grantee: Stephen Matcher, Professor, University of Sheffield
Amount: DKK 4,197,519
Grant category: Research Grants in open competition
Year: 2021
Geography: United Kingdom
The aim of this project is to enable quantification of the effects of treating atopic dermatitis (AD) with new therapies. New therapies have similar effectiveness to steroids but are much more expensive. Thus, there is a need for demonstrated benefits and better long-term safety to persuade healthcare providers to fund them.
Optical coherence tomography (OCT) is an ideal tool to quantify the benefits of new drugs for treating AD, whilst checking that they do not cause skin thinning, which is a risk with long-term use of steroids. OCT is a non-invasive imaging technique that uses laser light to provide ultrasound-like images with higher resolution – and OCT avoids the need to perform painful biopsies.
One problem with the current OCT systems is that if the skin inflammation becomes too high, it becomes difficult to quantify because OCT can only image to depths of around 1 mm. This limited depth penetration can potentially be improved by using a longer wavelength of laser light. With the project, Stephen Matcher will quantify the improvement in OCT image quality when using 1600 nm light rather than the current 1300 nm light.
If successful, the project holds a strong potential for use in both clinical trials and clinical practice with a highly needed more patient-friendly tool for measuring drug efficacy in skin diseases such as atopic dermatitis.