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INFLAMMATORY MARKERS IN SERA IN PATIENTS DIAGNOSED WITH MUCOSAL LICHEN PLANUS

Tina Sabet Motlagh, Carola Hanna Tutor: Majid Ebrahimi

Abstract: 247 words

Abstract and text: 3305 words 4 tables/figures

20 cited references

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ABSTRACT

OBJECTIVE: Lichen planus is a disease that can affect both skin and mucosa, in some cases both at the same time. Among patients with lichen planus, the oral version of lichen planus (OLP) can be observed in 50 – 70 %. OLP is the most common chronic

inflammatory disease of oral mucosa. Today it is known that OLP is an inflammatory condition but it is not known exactly what substances are prominent and active during this specific inflammatory process. The aim of this study was to examine inflammatory factors involved in OLP. METHODS: A total of 24 individuals were included in this prospective study. 15 of these were patients diagnosed with mucosal LP, whereas the other nine were healthy controls. Blood samples were taken from all participants and sent to Life Science Lab in Uppsala where they used Olinks inflammation panel to analyse inflammatory markers in the blood samples. RESULTS: There were differences in inflammatory factors in blood between the controls and patients with mucosal lichen planus. The inflammatory factors that contributed the most to this difference were IL-5, SCF, FGF-19 and FGF-21.

CONCLUSIONS: Due to the differences between LP-patients and controls we can conclude that there are tendencies to an inflammatory process going on systemically involving different levels of mainly IL-5, SCF, FGF-19 and FGF-21. The inflammatory factors that contributed the most to the differences between the two groups are not the typical ones that have been the resulting elevated inflammatory factors in other previous studies.

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INTRODUCTION

Lichen planus is a disease that can affect both skin and mucosa, in some cases both at the same time. Among patients with lichen planus, the oral version of lichen planus (OLP) can be observed in 50 – 70 % of the cases (Lourenço, Simonsen Nico, & Dumet

Fernandes, 2011). OLP is the most common chronic inflammatory disease of oral mucosa.

The prevalence of OLP is 1,9 % within the Swedish population (Axell & Rundquist, 1987) and 0,5 – 4 % of the World population. It is more commonly observed in middle aged females. (Lourenço, Simonsen Nico, & Dumet Fernandes, 2011).

OLP is often located on the tounge, buccal mucosa, gingiva and lips and is found symmetrically and bilaterally. It can be present in six different clinical forms; reticular, atrophic, papular, erosive, plaque and bullous (Müller, 2017). The clinical and

histopathological criteria of OLP and OLL was defined by WHO in 1978 (van der Meij &

van der Waal, 2003) and has later been modified by van der Meij et al. to a more stricter form.

The most common clinical form is reticular OLP which shows white, sharply-defined striations in a lacy-like network (Wickhams striae) and is most commonly seen on the buccal mucosa (Thorn, Holmstrup, & Rindum, 1988). The plaque-like form is similar to the reticular form but also contains homogenous, white plaque and is more commonly seen on the dorsum of the tounge in cigarette smokers. (Thorn, Holmstrup, & Rindum, 1988). These forms are normally asymptomatic, while burning sensation and discomfort are frequent symptoms in patients with erosive, bullous and atrophic forms. These forms clinically show red, atrophic mucosa, combined with white striations, often surrounded by papulae. Bullae is present in the bullous form, which is the result of a rapidly progressing erosive OLP. Spicy food, citrus fruit and toothbrushing are aggravating factors regarding the burning sensation and pain. (Ismail, Kumar, & Zain, 2007).

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Even though the various forms may vary in clinical appearances, the histological feature is the same. Histologically OLP shows a thickened basement membrane due to infiltration of eosinophilic cells, band-like infiltration of lymphoplasmatic cells (mainly T-cells) in the epithelio-mesenchymal junction and hyperkeratosis. There is also an inflammatory infiltrate in the superficial part of the connective tissue, cell nucleus enlargement, eosinophilic spheric bodies (known as civatte bodies) in the non-keratinized, stratified columnar epithelium and liquefaction degeneration of the basal cell layer in oral lichen planus. (Ismail, Kumar, & Zain, 2007).

Exact aetiology of OLP is not yet fully understood but autoimmunity has been suggested as a possible causative factor. (Ebrahimi, Nylander, Bäcklund, Wahlin, Coates, &

Nylander, 2010).

Clinical and histopathological observations must be combined in order to diagnose and confirm the lesion as an OLP-lesion. Differential diagnosis may vary depending on the clinical feature of OLP. Morsicatio buccarum, discoid lupus erythematosus and

candidiasis are all differential diagnosis to the reticular OLP, while aphthae and pemphigus vulgaris have similar clinical characteristics as the erosive form of OLP (Lourenço, Simonsen Nico, & Dumet Fernandes, 2011). Hence, the histological examination is very important when it comes to differentiate the diseases in order to provide the patient with correct diagnosis and therapy. One of the differential diagnosis, oral leukoplakia for example, has a higher malignant transformation tendency than OLP.

(Müller, 2017). Several studies confirm that the malignification rate of OLP and oral lichenoid lesions (OLL) is approximately 1 %, although this is controversial. (Gonzalez- Moles, Gil-Montoya, Ruiz.Avila, & Bravo, 2016).

Gonzales-Moles et al. showed in their study that 3,9 % of the patients with OLP and OLL developed oral squameous cell carcinoma within 9,72 months after the OLP/OLL

diagnosis.

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The treatment of OLP available today aims to reduce the symptoms. The choice of

treatment varies due to different clinical forms - one treatment cannot be recommended to all the clinical forms. The reticular form of OLP does usually not require any treatment because of the absence of symptoms. The erosive form on the other hand often requires treatment such as topical corticosteroids to reduce pain and burning sensation. Even though some OLP patients do not require any treatment it is important that the condition is kept under continuous control.

Optimization of oral hygiene is also a way of therapy, used as a method for preventing aggravation of the disease, especially in the presence of gingival lesions were plaque and tartar may induce local inflammation.

The cause of OLP is currently not known and therefore there is no causative treatment available today. Although the aetiology remains unknown, several factors that are thought to have an impact on the disease have been studied, such as; genetics, stress, drugs, diabetes, hypertension and autoimmune diseases. These factors have only been proposed to have an impact but there is no current evidence of their correlation with OLP.

(Roopashree, Gondhalekar, Shashikanth, George, & Thippeswamy, 2010).

OLP is defined as a T-cell mediated chronic inflammatory disease and the pathogenesis is believed to involve a destruction of the basal keratinocytes in the epithelium induced by T-cell mediation. CD8+ is the most activated T-cell in OLP and this is associated with increased production of Th1-cytokines (IL-1, IL-10, IL-12, IL-8 and TNF-α). This will increase the expression of ICAM-1 which is intercellular adhesion molecules on macrophages and Langerhans cells. (Lourenço, Simonsen Nico, & Dumet Fernandes, 2011). The keratinocytes are believed to present antigens on their surfaces, or expressing changed self-antigens, leading to the destruction of the keratinocytes. (Mattson &

Bäckman, 2016).

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One general accepted theory for the pathogenesis involves the dendritic Langerhans cells, which are located in the supra basal cellayer of the epithelium and are responsible for identifying and presenting antigens. The theory is that the Langerhans cell first identify the antigen, then migrates to local nodulus where it presents the antigen to naive (non activated) T-cells. The antigen must be presented to a naive T-cell with a specific receptor matching the antigen. When the antigen connects to the receptor, the naive T-cell becomes activated, resulting in proliferation of the T-cell. Following this process, some of the activated T-cells may leave the nodulus and enter the blood. These T-cells are now memory-T-cells and if the antigen that was previously presented by the Langerhans cell would be present again, an immunologic reaction would take place, leading to the lichenoid lesion. (Mattson & Bäckman, 2016).

As previously mentioned, one of the histological features of OLP is a band-like infiltration of T-cells in the epithelio-mesenchymal junction. The T-cell infiltrate is mainly composed of CD4+ and CD8+ cells. The CD8+ cells are cytotoxic T-cells with the ability to induce programmed cell death (apoptosis). CD4+ cells, mainly located beneath the epithelium, can be activated by Langerhans cells. The CD4+ cells have the ability to activate the cytotoxic CD8+ cells and indirectly initiate apoptosis of keratinocytes. The CD4+ cells also contribute to the chronic characteristics of the disease by releasing cytokines, leading to a maintained inflammation. (Mattson & Bäckman, 2016).

There is a great number of different substances that are involved in any inflammatory process. Today it is known that OLP is an inflammatory condition but it is not known exactly what inflammatory mediators are prominent and active during this specific inflammatory process. Therefore the aim of this study was to examine inflammatory factors involved in OLP. A screening of 96 inflammatory factors in the blood of patients with OLP and of healthy individuals without the disease was done, to later examine what roles these specific factors play in inflammation and how they affect the body in general.

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MATERIALS AND METHODS Study design

A total of 24 individuals were included in this prospective study. 15 of these were patients diagnosed with mucosal LP, whereas the other nine were healthy controls. In the LP- group three were men and 12 were women and the mean age were 70,2 years old (table 1).

In the control group two were men and seven were women and the mean age were 64,3 years old (table 2).

Specific procedures

Blood samples from all the 24 individuals were taken at Blodcentralen, University Hospital of Umeå. The selection of patients was made consecutively and the patients in the LP-group were asked to participate in the study after being diagnosed with LP

according to the WHO inclusion criteria, while the healthy controls were collected through advertisement. Before participation it was ensured that each participant in the control group did not have any form of LP or any other inflammatory disease. All the 24 participants were given information, both verbally and in written form, about the

procedure, possible pain/discomfort in conjunction with the blood sampling, and the main purpose of the study. The participation was voluntary and they could at any time, without any explanation or penalty choose to end their participation. All the participants gave their written informed consent to participate in the study. They also received a financial

compensation. The participants and their blood samples were only known to the caregivers responsible for the study. Their names were exchanged to numbers and the samples were labelled with a random number in order to provide complete anonymity in the study. A report of the study and an application for ethical review to the regional ethics committee was sent and approved before starting the study. Dnr: 2013-252-32M.

The blood samples were centrifuged to separate the serum from the blood cells. The serum samples were then kept in a freezer (-80°C) and transported to Life Science Lab in

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Uppsala where they used Olinks inflammation panel (called Proseek) on the samples (1µl serum each) with PEA-technology. Olink is a company that has developed a Proseek panel, an inflammation panel which provides an immunoassay “enabling analysis of 92 inflammation-related protein biomarkers across 96 samples simultaneously” (Olink Proteomics, 2017), thanks to their patented Proximity Extension Assay (PEA) technology.

(Olink Proteomics, 2017).

The assay involved these main steps:

1. 1 µl of serum were taken from each sample

2. A pair of oligonucleotide-labelled antibodies, also called “proseek probes” were allowed to bind in pairs to the target protein in the sample in a homogeneous assay.

3. A new PCR target was then formed because of the proximity-dependent DNA

polymerisation event that occurred when the two proseek probes were in close proximity.

4. Standard real-time PCR were then used to enable detection and amplification of the resulting sequence. (Olink Proteomics, 2017).

The unique DNA sequences of each of the 92 oligonucleotide antibody-pairs allow hybridization only to each other. In other words, only correctly matched sequences hybridize. The proximity extension (by DNA polymerase) will then create 92 unique DNA reporter sequences which will be amplified by real-time PCR. 92 protein biomarkers are then measured simultaneously in each sample.

What makes this technique unique and successful is that “[c]ross-reactive events will not be detected with Olinks panels since only matched DNA reporter pairs are amplified with real-time PCR […]. This allows for scalable multiplexing without loss of specificity and sensitivity.” (Olink Proteomics, 2017). It takes 24 hours to get the results (hands-on time is less than 3 hours). (Olink Proteomics, 2017).

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Statistics

The data Life Science Uppsala sent back was then analysed in the statistical program Simca 14.1 which transforms the multivariate data into visual information and the data could easily be interpret. The statistical modelling tool used was OPLS-DA.

RESULTS

The analyses of the inflammatory related proteins expression that Olink performed with their PEA-technology showed that there were differences between the two groups examined. Green dots (except L4 and L32) are placed to the left of the midline and blue dots (except C67) are placed to the right of the midline in the diagram (figure 1). The inflammatory factors that contributed the most to this difference were IL-5, SCF, FGF-19 and FGF-21 (figure 2).

DISCUSSION

This study found tendencies of differences regarding inflammation related biomarkers in patients with mucosal lichen planus compared to the controls. This means that there are different expressions of inflammatory factors between the two groups examined which is also the result of previous studies on this subject.

The outcome of this study shows that the following inflammatory factors contributed the most to the differences between controls and patients with mucosal lichen planus: IL-5, SCF, FGF-19 and FGF-21. Among the inflammatory factors that contributed the most to the differences with highest statistical reliability were IL-5, SCF and FGF-19. FGF-21 had a great contribution to the differences but with lower statistical reliability. To further investigate if these inflammatory factors are up-regulated or down-regulated we suggest that further analyse methods such as ELISA or PCR should be done to verify the amount of one specific protein in the samples.

IL-5 has been linked to oral lichen planus in previous studies, whereas SCF and FGF-19 have been linked to other inflammatory conditions rather than OLP specifically. IL-5 is an

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interleukin, a protein produced mainly by type 2 T-helper cells but also by eosinophils, mast cells and gamma delta T-cells. (Lu, Zhang, Sun, Du, & Gang, 2015). Interleukins are a group of cytokines which play a significant role in the immune system and inflammatory processes. The main role of IL-5 is to regulate the differentiation and maturation of

eosinophils in bone marrow and their migration, function and survival in different tissue sites. (Lu, Zhang, Sun, Du, & Gang, 2015). IL-5 has also been shown to have a role in stimulating the terminal differentiation stage of B-cells, turning them into antibody secreting plasma cells. (Lu, Zhang, Sun, Du, & Gang, 2015). The observation of IL-5 in patients with oral lichen planus varies between studies. According to one study made by Gotoh et al., an increased level of IL-5 was found in the oral mucosa in patients with OLP compared to the controls. (Gotoh, Hamada, Shiobara, & et. al, 2008). A decreased level of IL-5 in the oral mucosa in patients with OLP was observed in another study made by Kalogerakou et al. (Kalogerakou, Albanidou-Farmaki, Markopoulos, & Antoniades, 2008), while a third study show no statistical difference in the levels of IL-5 between controls and patients with OLP (Pekiner, Demirel, Borahan, & Ozbayrak). A possible explanation to this variation in results may be other factors related to the patients involved in the studies, such as different compositions in the subjects and the different IL-5 sources.

(Lu, Zhang, Sun, Du, & Gang, 2015).

SCF (stem cell factor) or KIT-ligand, is a cytokine that can be produced by fibroblasts, endothelial cells, mast cells and eosinophils during an inflammatory process. (Hassan &

Zander, 1996). Although SCF has not yet been directly linked to OLP in previous studies, there are studies showing correlation between SCF and inflammatory processes (Shen, Wang, & Huang, 2017). Further, in a study by Hassan et al, an increased level of SCF and its receptor was shown in patients with acute myeloid leukaemia compared to healthy controls. (Hassan & Zander, 1996).

FGF-19 and FGF-21 are fibroblast growth factors and these are two of the total 22 sub

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Kliewer, & Mangelsdorf, 2012). The discovery of FGF-19, FGF-21 and their functions have been relatively recent, thus there are few studies discussing specifically these fibroblast growth factors. Regarding FGF-19, current studies are focused on its role in patients with hepatitis due to alcohol consumption, or on its function in the regulation of bile acid homeostasis. (Potthoff, Kliewer, & Mangelsdorf, 2012). Studies have shown increased levels of FGF-19 in patients with hepatitis and extrahepatic cholestasis, indicating that it has a proven correlation with inflammation. (Zweers, o.a., 2017).

FGF-21 has been shown to have an effect on liver metabolism by improving hepatic insulin sensitivity and thereby increasing the glycogen content in the liver. (Potthoff, Kliewer, & Mangelsdorf, 2012). In a study made by Xu et al., obese mice injected with FGF-21 showed decreased levels of glucose in blood and improved glucose tolerance and insulin sensitivity. (Xu, o.a., 2009). Available studies that include FGF-21 are mainly focused on its effect on glucose and lipid metabolism, and little about its role in inflammation. In our study FGF-21 turned out to contribute a lot to the differences but with lower statistical reliability. This may indicate that FGF-21 is not associated with inflammatory conditions such as Lichen planus but to verify this statement further investigation need to be done on this specific inflammatory factor.

Overall, the main inflammatory factors that have a tendency to a different expression pattern between the two groups in this study are not the typical inflammatory factors that have been found in studies based on tissue. Studies have shown that the major cytokines that are involved in the pathogenesis of OLP so far are; IL-1, 2, 4, 5, 6, 8, 10, 12, 17 and 18. (Lu, Zhang, Sun, Du, & Gang, 2015). Although these interleukins have been shown to have an involvement in OLP, there is a variation in their expression in tissue and serum.

According to Lu et. al, IL-6 is the only interleukin that has shown increased levels in both tissue and serum. (Lu, Zhang, Sun, Du, & Gang, 2015). Our study did not show any statistical differences regarding the expression of IL-6 between LP-patients and controls.

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IL-5, 10, 12 and 17 have also shown increased levels in tissue, but their expression in serum have been either inconsistent or unclear. (Lu, Zhang, Sun, Du, & Gang, 2015). The levels of IL-2 and IL-18 in tissue show no differences between controls and patients with OLP, however the expression of IL-18 is elevated in serum in patients with oral lichen planus, whereas the expression of IL-2 in serum is inconsistent. (Lu, Zhang, Sun, Du, &

Gang, 2015). Expression of IL-8 in patients with oral lichen planus has been undetected in tissue but increased in serum. (Lu, Zhang, Sun, Du, & Gang, 2015).

Based on previous studies involving patients with OLP, one can conclude that an inflammatory factor can both be up-regulated in serum and tissue, as well as it can be down-regulated in serum while it is up-regulated in tissue and vice versa. In our study we can not come to this conclusion based on the fact that tissue samples were never taken from the participants.

Due to the differences between LP-patients and controls we can conclude that there is a tendency to an inflammatory process going on systemically involving different levels of mainly IL-5, SCF, FGF-19 and FGF-21. These inflammatory factors are not the typical ones that have been the resulting factors in other previous studies.

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ACKNOWLEDGMENTS

We would like to express our great appreciation to our main supervisor Majid Ebrahimi for guiding us through this project, and for letting us take part of the research material to further learn and investigate on this subject. We would also like to thank all the experts involved for their assistance with the statistics used in this report.

 

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REFERENCES

Axell, T., & Rundquist, L. (1987). Oral lichen planus - a demographic study. Community Dent Oral Epidemiol (15), pp. 52-56.

Ebrahimi, M., Nylander, E., Bäcklund, B., Wahlin, Y., Coates, P., & Nylander, K. (2010, July). The use of a novel ELISA method for detection of antibodies against p63 in sera from patients diagnosed with oral and/or genital and skin lichen planus. J Oral Pathol Med. , 39 (6), pp. 486-490.

Gonzalez-Moles, M., Gil-Montoya, J., Ruiz.Avila, I., & Bravo, M. (2016, 06 30). Is oral cancer incidence among patients with oral lichen planus/oral lichenoid lesions

underestimated? J Oral Pathol Med. , pp. 1-6.

Gotoh, A., Hamada, Y., Shiobara, N., & et. al. (2008). Skew in T cell receptor usage with polyclonal expansion in lesions of oral lichen planus without hepatitis C virus infection.

Clin Exp Immunol (154), pp. 192–201.

Hassan , H., & Zander, A. (1996). Stem cell factor as a survival and growth factor in human normal and malignant hematopoiesis. Acta Haematol. (95), pp. 257-262.

Ismail, S. B., Kumar, S. K., & Zain, R. B. (2007). Oral lichen planus and lichenoid reactions: etiopathogenesis, diagnosis, management and malignant transformation. J Oral Sci. , 49 (2), pp. 89-106.

Kalogerakou, F., Albanidou-Farmaki, E., Markopoulos, A., & Antoniades, D. (2008).

Detection of T cells secreting type 1 and type 2 cytokines in the peripheral blood of patients with oral lichen planus. . Hippokratia (12), pp. 230-235.

Lourenço, S. V., Simonsen Nico, M. M., & Dumet Fernandes, J. (2011). Oral lichen planus. An Bras Dermatol , pp. 633-643.

Lu, R., Zhang, J., Sun, W., Du, G., & Gang, Z. (2015). Inflammation-related cytokines in oral lichen planus: an overview. Journal of Oral Pathology & Medicine (44), pp. 1-14.

Müller, S. (2017). Oral lichenoid lesions: distinguishing the benign from the deadly. Mod Pathol. (30), pp. 54-67.

Mattson, U., & Bäckman, K. (2016). Oral medicin i teori och praktik. Gothia fortbildning.

Olink Proteomics. (2017). Olink Proteomics. Retrieved from Olink Proteomics:

http://www.olink.com/data-you-can-trust/technology/

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Pekiner, F., Demirel, G., Borahan, M., & Ozbayrak, S. (n.d.). Cytokine profiles in serum of patients with oral lichen planus. Cytokine , 60, pp. 701-706.

Potthoff, M. J., Kliewer, S. A., & Mangelsdorf, D. J. (2012, February 15). Endocrine fibroblast growth factors 15/19 and 21: from feast to famine. Genes Dev. , 26 (4), pp. 312- 324.

Roopashree, M. R., Gondhalekar, V. R., Shashikanth, M. C., George, J., & Thippeswamy, S. H. (2010, 06 23). Pathogenesis of oral lichen planus - a review. J Oral Pathol Med.

(39), pp. 729-734.

Shen, S., Wang, R., & Huang, S. (2017, March 8). Expression of the stem cell factor in fibroblasts, endothelial cells, and macrophages in periapical tissues in human chronic periapical diseases. Genet mol res. , 16 (1).

Thorn, J., Holmstrup, P., & Rindum, J. (1988). Course of various clinical forms of oral lichen planus. A prospective follow-up study of 611 patients. J Oral Pathol (17), pp. 213- 218.

van der Meij, E. H., & van der Waal, I. (2003, 02 12). Lack of clinicopathologic correlation in the diagnosis of oral lichen planus based on the presently available diagnostic criteria and suggestions for modifications. J Oral Pathol Med. (32), pp. 507- 512.

Xu, J., Lloyd, D., Hale, C., Stanislaus, S., Chen, M., Sivits, G., et al. (2009). Fibroblast growth factor 21 reverses hepatic steatosis, increases energy expenditure, and improves insulin sensitivity in diet-induced obese mice. Diabetes (58), pp. 250–259.

Zweers, S., de Vries, E., Lenicek, M., Tolenaars, D., de Waart, D., Koelfat, K., et al.

(2017, January). Prolonged fibroblast growth factor 19 response in patients with primary sclerosing cholangitis after an oral chenodeoxycholic acid challenge. Hepatol int. , 11 (1), pp. 132-140.

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Table 1. LP patients included in the study

Number of men Number of women Mean age (years old)

Min-max (years old)

3 (20%) 12 (80%) 70,2 57-84

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Table 2. Control patients included in the study

Number of men Number of women Mean age (years old)

Min-max (years old)

2 (22%) 7 (78%) 64,3 45-73

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Figure 1. Green dots, L = Lichen planus patients. Blue dots, C = controls. Most of the green dots are on the left side of the midline and most of the blue dots are on the right side of the midline. This speaks for the possible statistical differences regarding inflammatory factors between the two groups.

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Figure 2. Each green dot represents an inflammatory factor. Inflammatory factors to the far left and to the far right of the diagram contribute the most to the differences between LP-patients and controls. To the far right are the inflammatory factors that contribute the most with statistical certainty whereas the factors to the far left have a great contribution to the difference but with lower statistical reliability. Inflammatory factors placed close to 0 at the x-axis and y-axis (in the middle of the diagram) represents no difference between the two groups.

References

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