Mechanism of action of glucocorticoids in nasal polyposis

Fernandes, Atílio Maximino; Valera, Fabiana Cardoso Pereira; Anselmo-Lima, Wilma T.

doi:10.1590/S0034-72992008000200020

Abstracts

Glucocorticoids (GC) are the drugs of choice for the clinical treatment of nasal polyposis, according to the medical literature. Its mechanism of action in the regression of clinical symptoms and polyps, however, is not fully understood. The topical and/or systemic use of glucocorticoids lead to variable expression of cytokines, chemokines and lymphokines, as well as changes in cells. It is known that GC suppresses the expression of pro-inflammatory cytokines, chemokines and adhesion molecules such as ICAM-1 and E-selectin; GC also stimulate the transcription of anti-inflammatory cytokines such as TGF-b. GC suppress pro-fibrotic cytokines related to polyp growth, such as IL-11, the basic fibroblast growth factor (b-FGF), and the vascular endotelial growth factor (VEGF). The action of GC depends fundamentally on their interaction with receptors (GR); certain subjects have a degree of resistance to its effect, which appears to be related with the presence of a b isoform of GR. GC also act variably on the genes involved in immunoglobulin production, presentation, and antigen processing. AIM: We present a review of the literature on the mechanisms of GC action in nasal polyosis. CONCLUSION: Understanding the mechanism of action of GC in nasal polyposis will aid in the development of new, more efficient, drugs.

cytokines; glucocorticoids; pathophysiological mechanisms; nasal polyposis

Os glicocorticóides (GC) são drogas de escolha no tratamento clínico da polipose nasossinusal conforme recomendação da literatura. Entretanto, seus mecanismos de ação nas regressões dos sintomas clínicos e dos pólipos não são totalmente compreendidos. Sabe-se que a administração tópica e ou sistêmica dos glicocorticóides leva a variações na expressão de citocinas, quimiocinas e linfocinas, além das alterações celulares. Assim, os GC suprimem a expressão de citocinas pró-inflamatórias, de quimiocinas, de moléculas de adesão, além de estimular a transcrição de citocinas antiinflamatórias. Citocinas pró-fibróticas como a IL-11, fator básico de crescimento do fibroblasto (b-FGF) e fator de crescimento endotelial vascular (VEGF), relacionados com o crescimento do pólipo, também são suprimidos pela ação do GC. Tal ação depende fundamentalmente da interação com os seus receptores (GR), pois alguns indivíduos apresentam algum grau de resistência celular ao seu efeito, que parece estar relacionada com a presença da isoforma b do GR. Genes envolvidos nas fases de produção de imunoglobulinas, apresentação e processamento do antígeno também sofrem ação dos GC de forma variada. OBJETIVOS: Fazer uma revisão da literatura sobre os mecanismos de ação do GC na PNS. CONCLUSÃO: A compreensão desses mecanismos implicará no desenvolvimento de drogas mais eficazes na sua terapêutica.

citocinas; glicocorticóide; mecanismos fisiopatológicos; polipose rinossinusal

REVIEW ARTICLE

Mechanism of action of glucocorticoids in nasal polyposis

Atílio Maximino Fernandes^I; Fabiana Cardoso Pereira Valera^II; Wilma T. Anselmo-Lima^III

^IDoctor, USP/Ribeirão Preto, Otorhinolaryngologist

^IIDoctor, Professor

^IIILivre-docente habilitation, Professor

SUMMARY

Glucocorticoids (GC) are the drugs of choice for the clinical treatment of nasal polyposis, according to the medical literature. Its mechanism of action in the regression of clinical symptoms and polyps, however, is not fully understood. The topical and/or systemic use of glucocorticoids lead to variable expression of cytokines, chemokines and lymphokines, as well as changes in cells. It is known that GC suppresses the expression of pro-inflammatory cytokines, chemokines and adhesion molecules such as ICAM-1 and E-selectin; GC also stimulate the transcription of anti-inflammatory cytokines such as TGF-b. GC suppress pro-fibrotic cytokines related to polyp growth, such as IL-11, the basic fibroblast growth factor (b-FGF), and the vascular endotelial growth factor (VEGF). The action of GC depends fundamentally on their interaction with receptors (GR); certain subjects have a degree of resistance to its effect, which appears to be related with the presence of a b isoform of GR. GC also act variably on the genes involved in immunoglobulin production, presentation, and antigen processing.

AIM: We present a review of the literature on the mechanisms of GC action in nasal polyosis.

CONCLUSION: Understanding the mechanism of action of GC in nasal polyposis will aid in the development of new, more efficient, drugs.

Keywords: cytokines, glucocorticoids, pathophysiological mechanisms, nasal polyposis.

INTRODUCTION

Glucocorticoids (GC) are steroid hormones derived from cholesterol metabolism. These hormones are effective immunosuppressant and anti-inflammatory agents, and are naturally produced in the adrenal glands upon stimulation by the hypothalamic-pituitary-adrenal axis (HPA). These steroid hormones are the main therapeutic component in various autoimmune diseases such as rheumatoid arthritis, ulcerative colitis, asthma and polyposis.¹

The fist successful use of hydrocortisone (the first GC metabolite that was synthesized) was in 1948; it was used for suppressing the clinical manifestations of rheumatoid arthritis. GC are used in nasosinal polyposis (NSP) in its topical or systemic forms, yielding excellent results by causing polypoid tissues to regress and by reducing inflammation. Clinical improvement occurs, with decreased respiratory obstruction and rhinorrhea, and improved olfaction. GC are first line drugs for the initial treatment of this condition, according to the International Consensus on NSP in 2002² and the European Consensus in 2004;³ its efficacy has been demonstrated in various therapeutic models.^4,5,6 Topical GC are preferable for long-term use due to minimal systemic absorption and fewer side-effects; their effect within the paranasal sinuses, however, is limited. GC have also been used routinely following polyp-removing surgical procedures for reducing the recurrence of polyps and increasing the interval between surgery in these patients, thus helping control NSP.⁶ GC may, however, not be effective in all cases; the success rate of this form of treatment is around 60.9 to 80%.^7,8It is known that unsuccessful topical GC treatment is related to extensive NSP cases and lack of adhesion to therapy. The main factor that establishes the efficacy of GC therapy is the intrinsic, cell mechanism-mediated, resistance to the drug.

The aim of this review was to discuss the possible cell action mechanisms of GC in NSP and their interactions with cytokines, chemokines and adhesion molecules.

REVIEW OF THE LITERATURE

Molecular Mechanisms in NSP

NSP is a chronic inflammatory disease; its pathophysiological mechanisms have not been fully understood, notwithstanding recognition of the histological changes that occur. These alterations are epithelial hyperplasia, increased goblet cell, basal membrane thickening, stromal edema, and increased fibroblast production, to which is added inflammatory cell recruitment including lymphocytes, plasmocytes and particularly eosinophils.⁶

At a molecular level, cytokines - essential regulating proteins for immune cell growth, differentiation and activation - influence NSP by two mechanisms: local tissue growth stimulation mediated by, for instance, b-FGF, IGF-1, TGF-a, and TGF- b, and cytokine-mediated long-term maintenance of an inflammatory state involving IL-1b, TNF-a, IL-4, IL-5, IL-6, IL-10, and IFN-g, among others.⁹ The complex interaction between these cytokines and structural and inflammatory cells leads to a chronic process that, after initiated, appears not to depend on the causal stimulus for its perpetuation.

It is known that fibroblasts and epithelial cells, once stimulated, are induced to produce TNFa and IL-1b. These cytokines stimulate nasal mucosa structural cells to produce various other cytokines (GM-CSF, IL-2, IL-3, IL-5, IL-6, IL-8, IL-12, IL-13, IL-16, TGF-a, TGF-b, TNF-a and IL-1 b), chemokines (RANTES, eotaxin, eotaxin-2) and adhesion molecules (ICAM-1 and VCAM-1). Cytokines activate inflammation, while chemokines and adhesion molecules are powerful circulating inflammatory cell - particularly eosinophils - recruiters. Once translocated to target tissues, these cells stimulate the production of other cytokines, which prolong and increase inflammation and produce cytotoxic molecules, such as the major basic protein (MBP), the eosinophilic cationic protein (ECP), leukotrienes and the platelet-activating factor (PAF). These molecules in turn intensify tissue damage, basal membrane thinning, stromal fibrosis, angiogenesis, and gland and stromal hyperplasia.^6,10 Eosinophils are particularly able to produce cytokines - such as IL-3, IL-5 and GM-CSF - that increase their survival and that recruit additional eosinophils into the polyps, thus intensifying tissue eosinophilia.¹¹

GC Action on Cell Composition and Activation

The anti-inflammatory action of GC results from a number of changes in inflammatory cells. Their use leads to an increase in the number of circulating neutrophils, decreased production of inflammatory lymphokines and monokines - such as IL-1 and TNF-a11 - and induction of eosinophils apoptosis.

Mastruzzo et al.¹² found that intranasal GC increase the density of CD8+ cells in polyps, thereby decreasing the CD4/CD8 ratio. This author also observed decreased numbers of IL-5+ and IL-4+ cells, in contrast with an increased number of TGF-b+ cells, which was correlated with CD8+ T-cells, and which is anti-inflammatory.¹²

GC Intracellular action and on Inflammatory Mediators

The action mechanism of these substances on cells results from their bonding to cytoplasmic high-affinity glucocorticoid receptors (GR). The steroid-receptor complex (GC-GR) is capable of nuclear translocation; in the nucleus, it bonds with chromosomal DNA. This bond sets in motion or inhibits gene transcription, respectively by transactivation and transrepression. Transactivation is mediated by hormone-activated glucocorticoid receptor (or GC-GR complex) bonding to the DNA sequence named glucocorticoid response element (GRE). Corticosteroids, for instance, may stimulate anti-inflammatory molecule (IL-10, IL-1Ra6, TGF-b and IkB) and uteroglobulin synthesis.

Benson⁹ used the microarray technique on glucocorticoid-treated polyps and showed that 200 of 22,000 genes underwent some change in expression after treatment, and that these alterations were involved in various immunoglobulin-producing steps, in antigen presentation and processing, in chemoattraction, and in granulocyte and lymphocyte activation. The most highly expressed genes were those producing uteroglobulin and 15-lipoxigenase, the latter being an enzyme that induces lipoxin production (signaling enzymes for inhibiting inflammation). Uteroglobulin inhibits leukocyte chemotaxis and phospholipase A2 and pro-inflammatory cytokines synthesis.⁹

It is thought that most of the side effects of oral GC take place by gene transactivation. The main anti-inflammatory effect of GC, however, is related to their transrepressor effect. Transrepression is specially mediated by direct protein-protein inhibition in the GC-GR complex and by transcription factors such as AP-1 and NF-kB (cross-inhibition). When bonding with these factors, the GC-GR complex blocks the transcription of cytokines, chemokines and enzymes such as IL-18, IL-16 and eotaxin, being thus directly related to their expresion.¹³

Transcription factors are cytoplasmatic molecules that upon activation are able to translocate to the nucleus and to induce transcription of pro-inflammatory cytokines, adhesion molecules and chemokines, among others. GC, therefore, also suppress the transcription of pro-inflammatory cytokines (IL-1, IL-2, IL-3, IL-4, IL-, IL-6, GM-CSF, TNF-a, and IFN-g), of chemokines (RANTES, eotaxin and MCP) and adhesion molecules (ICAM-1 and E-selectin).

Marx et al.¹⁴ found decreased GM-CSF and TNF-a levels in nasosinal polyps following in vitro glucocorticoid therapy. On the other hand, Hamilos et al.¹⁵ noted a marked decrease in GM-CSF, but not in TNF-a, in an in vivo study of fluticasone use during one month. Watanabe et al.¹¹ also found decreased GM-CSF levels in nasal polyp epithelial cells under GC therapy, which would explain reduced eosinophil apoptosis.

Woodworth et al.¹⁶ demonstrated that IL-5 and IL-13 levels were significantly decreased in nasal polyps following systemic GC therapy in NSP patients. An even more significant reduction was observed after treatment with chemokines, eotaxin and MCP-4 (monocyte chemoattractant protein) in the same group of patients.

Silvestri et al.¹⁷ showed that fluticasone significantly decreased b-FGF-induced fibroblast proliferation and TNF-a-induced ICAM-1 expression. This author also observed TNF-a inhibition of eotaxin release and fibroblast inhibition within polyps due to IL-4.

Molet et al.¹⁸ showed that IL-11, a pro-fibrotic cytokine that stimulates fibroblast proliferation and smooth muscle hyperplasia, is increased in nasal polyps. This elevation relative to the healthy mucosa occurs both in epithelial cells and in submucosal inflammatory cells, and is directly connected with type I collagen fiber accumulation. Collagen types I and III typically accumulate in NSP, which is in line with the findings above. The same author also showed that following treatment of polyps with GC (fluticasone) during four weeks, IL-11 expression was markedly decreased. Uchida et al.¹⁹ demonstrated in vitro that, following treatment of polyps with fluticasone, there was suppression of mRNA expression of the basic fibroblast growth factor (bFGF) and the vascular endothelial growth factor. Yaritas et al.²⁰ reported similar findings, noting decreased expression of bFGF in nasal polyps following the topical use of mometasone during four weeks in individuals with polyps.

Delbrouck et al.²¹ showed in vitro that budesonide can inhibit expression of the leukocyte migration inhibitory factor (MIF), a lymphokine that counter-regulates GC, decreasing their expression in polyp epithelial and gland cells, depending on the concentration of GC.

There are two main cell resistance mechanisms against GC:

- the ratio between GRa/GRb receptor isoforms

- transcription factors

There are two main GS isoform: GRa and GRb. It is known that GRa is able to bind to GC after activating the GRE, after which it is considered as the active form. GRb has the same GRE-binding capability, but does not bind to GC; GRb, then, is considered an endogenous inhibitor of GC. Pujols et al.¹³ and Hamilos et al.¹⁵ reported increased GRb expression in NSP patients, compared with controls. Valera¹⁰ and Li et al.²² observed lower GRa levels in NSP, compared to the normal mucosa. Both Pujols et al.¹³ and Valera¹⁰ stated that the most important factor in resistance to GC was the GRa/GRb isoform ratio, more important then the absolute values of each isoform.

Increased expression of transcription factors is also important in the resistance to GC; when activated, these factors are able to directly inhibit bonding between GR and GC.²³

Valera¹⁰ and Takeno et al.²⁴ observed an increased expression of the p65 (active) and p50 (constitutional) NFkB fraction in nasal polyps, compared to the control mucosa. Valera¹⁰ showed that p65 levels decreased significantly following the use of topical budesonide for 2 months. This author also found a higher expression of p65 in NSP cases that responded less to topical budesonide, compared to those cases that responded more favorably to medical therapy.

Baraniuk et al²⁵ found that the AP-1 transcription factor c-fos (active) fraction was elevated in nasosinal polyps, and that c-fos expression in polyps was decreased following oral therapy with GC. Valera,¹⁰ however, showed that c-fos levels were not increased compared to the control nasal mucosa.

Further knowledge about the action of GC in NSP and the development of cell resistance mechanisms against these drugs increase the possibility that more specific and effective drugs may be developed for the treatment of NSP.

CONCLUSION

Systemic or topical corticosteroids are important drugs in the treatment of NSP, both singly in therapy and as adjuvant therapy in extensive cases that are also treated surgically. Their efficacy is still limited to 60-80% of cases.

Understanding the action mechanisms of GC in NSP may foster the development of more effective drugs for treating this condition.

REFERENCES

¹
Schimmer BP, Parker KL. Hormônio adrenocorticotrópico; esteróides adrenocorticais e seus análogos sintéticos; inibidores da síntese e das ações dos hormônios adrenocorticais. In: Goodman & Gilman. As bases farmacológicas da Terapêutica. 10ª ed. Rio de Janeiro: Mc Graw Hill, 2003.Cap.60, p.1241-60.
²
Mladina R, Clement P, Lopadin A, Mann W, Passali D. International Consensus on Nasal Polyposis 2002-2004. Eur Arch Otorhinolaryngol 2005;262(6):519-21.
³
Fokkens W, Lund V, Bachert C, Clement P, Hellings P, Holmstrom M et al. EAACI position paper on rhinosinusitis and nasal polyps executive summary. Allergy 2005;60(5):583-601.
⁴
Hissaria P, Smith W, Wormald PJ, Taylor J, Vadas M, Gillis D, Kette F. Short course of systemic corticosteroids in sinonasal polyposis: a double-blind, randomized, placebo-controlled trial with evaluation of outcome measures. J Allergy Clin Immunol 2006;118(1):128-33.
⁵
Benitez P, Alobid I, Haro J, Berenguer J, Bernal-Sprekelsen M, Pujols L, Picado C, Mullol J. A short course of oral prednisone followed by intranasal budesonide is an effective treatment of severe nasal polyps. Laryngoscope 2006;116:770-5.
⁶
Bachert C, Watelet, JB, Gevaert P, Cauwenberge, PV. Pharmacological management of nasal polyposis. Drugs 2005;65(11):1537-52.
⁷
Sieskiewicz A, Olszewska E, Rogowski M, Grycz E. Preoperative corticosteroid oral therapy and intraoperative bleeding during functional endoscopic sinus surgery in patients with severe nasal polyposis: a preliminary investigation. Ann Otol Rhinol Laryngol 2006;115(7):490-4.
⁸
Sheth A, Reddymasu S, Jackson R. Worsening of asthma with systemic corticosteoids. J Gen Intern Med 2006;21:C11-3.
⁹
Benson M. Pathophysiological effects of glucocorticoids on nasal polyps: an update. Curr Opin Allergy Clin Immunol 2005;5:31-5.
¹⁰
Valera FCP. Expressão dos genes de receptors de glicocorticóides GRa e b e dos fatores de transcrição AP-1 e NFkB em pacientes com polipose nasossinusal: avaliação de mecanismos de resistência ao corticosteróide. Tese (Doutorado em Medicina) - Faculdade de Medicina de Ribeirão Preto - USP, Ribeirão Preto, 2006.
¹¹
Watanabe K, Kanaizumi E, Shirasaki H, Himi T. Effects of glucocorticoids on infiltrating cells and epithelial cells of nasal polyps. Ann Otol Rhinol Laryngol 2004;113:465-73.
¹²
Mastruzzo C, Greco LR, Nakano K. Impact of intranasal budesonide on immune inflammatory responses and epithelial remodeling in chronic upper airway inflammation. J Allergy Clin Immunol 2003;112: 37-44.
¹³
Pujols L, Mullol J, Torrego A, Picado C. Glucocorticoid receptors in human airways. Allergy 2004;59:1042-52.
¹⁴
Marx D, Tassabvehji M, Heer S, Huttenbrink KB, Szelenyi I. Modulation of TNF and GM-CSF release from dispersed human nasal polyp cells and human whole blood by inhibitors of different PDE isoenzymes and glucocortidoids. Pulm Pharmacol Ther 2002;15(1):7-15.
¹⁵
Hamilos DL, Leung DY, Muro S, Kahn AM, Hamilos SS, Thawley SE, Hamid QA J. GRb expression in nasal polyp inflammatory cells and its relationship to the anti-inflammatory effects of intranasal fluticasone. J Allergy Clin Immunol 2001;108(1):59-68.
¹⁶
Woodworth BA, Kusumam J, Kaplan AP, Schlosser RJ. Alterations in eotaxin, monocyte chemoattractant protein-4, interleukin-5 and interleukin-13 after systemic steroid treatment for nasal polyps. Otolaryngol Head Neck Surg 2004;131(5):585-9.
¹⁷
Silvestri M, Sabatini F, Scarso L, Cordone A, Dasic G, Rossi GA. Fluticasone propionate downregulates nasal fibroblast functions involved in airway inflammation and remodeling. Int Arch Allergy Immunol 2002;128(1):51-8.
¹⁸
Molet SM, Hamid QA, Hamilos DL. IL-11 and IL-17 expression nasal polyps: relationship to collagen deposition and suppression by intranasal fluticasone propionate. Laryngoscope 2003;113:1803-12.
¹⁹
Uchida J, Kanai K, Asano K, Watanabe S, Hisamitsu T, Suzaki H. Influence of fluticasone propionate on the production of vascular endothelial growth factor and basic fibroblast growth factor from nasal fibroblasts in vitro. In Vivo 2004;18(6):767-70.
²⁰
Yariktas M, Doner F, Sutcu R, Demirci M, Dogru H, Yasan H. The effect of topical corticosteroid on basic fibroblast growth factor in nasal polyps tissue. Am J Rhinol 2005;19(3):248-50.
²¹
Delbrouck C, Gabius HJ, Vandenhoven G, Kiss G, Hassid S. Budesonide-dependent modulation of expression of macrophage migration inhibitory factor in a polyposis model: evidence for differential regulation in surface and glandular epithelia. Ann Otol Rhinol Laryngol 2004;113(7):544-51.
²²
Li P, Li Y, Zhang X, Zhang G, Ye J, Sun Y, Hu B. Detection of glucocorticoid receptor-alpha mRNA expression using FQ-RT-PCR in nasal polyp. Lin Chuang Er Bi Yan Hou Ke Za Zhi 2005;19:769-71.
²³
Valera FCP, Anselmo-Lima WT. Evaluation of efficacy of topical corticosteroid for the clinical treatment of nasal polyposis: searching for clinical events that may predict response to treatment. Rhinology 2007, in press.
²⁴
Takeno S, Hirakawa K, Ueda T, Furukido K, Ossada R, Yajin K. Nuclear factor-kappa B activation in the nasal polyp epithelium: relationship to local cytokine gene expression. Laryngoscope 2002;112:53-8.
²⁵
Baraniuk JN, Wong G, Ali M, Sabol M, Troost T. Glucocorticoids decrease c-fos expression in human nasal polyps in vivo. Thorax 1998;53:577-82.

Publication Dates

Publication in this collection
16 June 2008
Date of issue
Apr 2008

History

Accepted
24 Mar 2007
Received
04 Aug 2006

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] ¹
Schimmer BP, Parker KL. Hormônio adrenocorticotrópico; esteróides adrenocorticais e seus análogos sintéticos; inibidores da síntese e das ações dos hormônios adrenocorticais. In: Goodman & Gilman. As bases farmacológicas da Terapêutica. 10ª ed. Rio de Janeiro: Mc Graw Hill, 2003.Cap.60, p.1241-60.

[2] ²
Mladina R, Clement P, Lopadin A, Mann W, Passali D. International Consensus on Nasal Polyposis 2002-2004. Eur Arch Otorhinolaryngol 2005;262(6):519-21.

[3] ³
Fokkens W, Lund V, Bachert C, Clement P, Hellings P, Holmstrom M et al. EAACI position paper on rhinosinusitis and nasal polyps executive summary. Allergy 2005;60(5):583-601.

[4] ⁴
Hissaria P, Smith W, Wormald PJ, Taylor J, Vadas M, Gillis D, Kette F. Short course of systemic corticosteroids in sinonasal polyposis: a double-blind, randomized, placebo-controlled trial with evaluation of outcome measures. J Allergy Clin Immunol 2006;118(1):128-33.

[5] ⁵
Benitez P, Alobid I, Haro J, Berenguer J, Bernal-Sprekelsen M, Pujols L, Picado C, Mullol J. A short course of oral prednisone followed by intranasal budesonide is an effective treatment of severe nasal polyps. Laryngoscope 2006;116:770-5.

[6] ⁶
Bachert C, Watelet, JB, Gevaert P, Cauwenberge, PV. Pharmacological management of nasal polyposis. Drugs 2005;65(11):1537-52.

[7] ⁷
Sieskiewicz A, Olszewska E, Rogowski M, Grycz E. Preoperative corticosteroid oral therapy and intraoperative bleeding during functional endoscopic sinus surgery in patients with severe nasal polyposis: a preliminary investigation. Ann Otol Rhinol Laryngol 2006;115(7):490-4.

[8] ⁸
Sheth A, Reddymasu S, Jackson R. Worsening of asthma with systemic corticosteoids. J Gen Intern Med 2006;21:C11-3.

[9] ⁹
Benson M. Pathophysiological effects of glucocorticoids on nasal polyps: an update. Curr Opin Allergy Clin Immunol 2005;5:31-5.

[10] ¹⁰
Valera FCP. Expressão dos genes de receptors de glicocorticóides GRa e b e dos fatores de transcrição AP-1 e NFkB em pacientes com polipose nasossinusal: avaliação de mecanismos de resistência ao corticosteróide. Tese (Doutorado em Medicina) - Faculdade de Medicina de Ribeirão Preto - USP, Ribeirão Preto, 2006.

[11] ¹¹
Watanabe K, Kanaizumi E, Shirasaki H, Himi T. Effects of glucocorticoids on infiltrating cells and epithelial cells of nasal polyps. Ann Otol Rhinol Laryngol 2004;113:465-73.

[12] ¹²
Mastruzzo C, Greco LR, Nakano K. Impact of intranasal budesonide on immune inflammatory responses and epithelial remodeling in chronic upper airway inflammation. J Allergy Clin Immunol 2003;112: 37-44.

[13] ¹³
Pujols L, Mullol J, Torrego A, Picado C. Glucocorticoid receptors in human airways. Allergy 2004;59:1042-52.

[14] ¹⁴
Marx D, Tassabvehji M, Heer S, Huttenbrink KB, Szelenyi I. Modulation of TNF and GM-CSF release from dispersed human nasal polyp cells and human whole blood by inhibitors of different PDE isoenzymes and glucocortidoids. Pulm Pharmacol Ther 2002;15(1):7-15.

[15] ¹⁵
Hamilos DL, Leung DY, Muro S, Kahn AM, Hamilos SS, Thawley SE, Hamid QA J. GRb expression in nasal polyp inflammatory cells and its relationship to the anti-inflammatory effects of intranasal fluticasone. J Allergy Clin Immunol 2001;108(1):59-68.

[16] ¹⁶
Woodworth BA, Kusumam J, Kaplan AP, Schlosser RJ. Alterations in eotaxin, monocyte chemoattractant protein-4, interleukin-5 and interleukin-13 after systemic steroid treatment for nasal polyps. Otolaryngol Head Neck Surg 2004;131(5):585-9.

[17] ¹⁷
Silvestri M, Sabatini F, Scarso L, Cordone A, Dasic G, Rossi GA. Fluticasone propionate downregulates nasal fibroblast functions involved in airway inflammation and remodeling. Int Arch Allergy Immunol 2002;128(1):51-8.

[18] ¹⁸
Molet SM, Hamid QA, Hamilos DL. IL-11 and IL-17 expression nasal polyps: relationship to collagen deposition and suppression by intranasal fluticasone propionate. Laryngoscope 2003;113:1803-12.

[19] ¹⁹
Uchida J, Kanai K, Asano K, Watanabe S, Hisamitsu T, Suzaki H. Influence of fluticasone propionate on the production of vascular endothelial growth factor and basic fibroblast growth factor from nasal fibroblasts in vitro. In Vivo 2004;18(6):767-70.

[20] ²⁰
Yariktas M, Doner F, Sutcu R, Demirci M, Dogru H, Yasan H. The effect of topical corticosteroid on basic fibroblast growth factor in nasal polyps tissue. Am J Rhinol 2005;19(3):248-50.

[21] ²¹
Delbrouck C, Gabius HJ, Vandenhoven G, Kiss G, Hassid S. Budesonide-dependent modulation of expression of macrophage migration inhibitory factor in a polyposis model: evidence for differential regulation in surface and glandular epithelia. Ann Otol Rhinol Laryngol 2004;113(7):544-51.

[22] ²²
Li P, Li Y, Zhang X, Zhang G, Ye J, Sun Y, Hu B. Detection of glucocorticoid receptor-alpha mRNA expression using FQ-RT-PCR in nasal polyp. Lin Chuang Er Bi Yan Hou Ke Za Zhi 2005;19:769-71.

[23] ²³
Valera FCP, Anselmo-Lima WT. Evaluation of efficacy of topical corticosteroid for the clinical treatment of nasal polyposis: searching for clinical events that may predict response to treatment. Rhinology 2007, in press.

[24] ²⁴
Takeno S, Hirakawa K, Ueda T, Furukido K, Ossada R, Yajin K. Nuclear factor-kappa B activation in the nasal polyp epithelium: relationship to local cytokine gene expression. Laryngoscope 2002;112:53-8.

[25] ²⁵
Baraniuk JN, Wong G, Ali M, Sabol M, Troost T. Glucocorticoids decrease c-fos expression in human nasal polyps in vivo. Thorax 1998;53:577-82.

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Mechanism of action of glucocorticoids in nasal polyposis

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