The page number in the footer is not for bibliographic referencingwww.tandfonline.com/oemd 5

S Afr Fam Pract
ISSN 2078-6190    EISSN 2078-6204 

© 2019 The Author(s)

REVIEW

Rhinosinusitis

Sinusitis, more aptly referred to as rhinosinusitis, can be described 
as a symptomatic inflammatory condition of the paranasal 
sinuses and the nasal cavity.1 Generally, the condition is regarded 
as acute (ARS) if lasting up to 4 weeks, sub-acute when lasting 
between 4 and 12 weeks, and chronic (CRS) if symptoms present 
for more than 12 weeks.2

Common symptoms of ARS include purulent nasal drainage 
which is accompanied by nasal obstruction and/or facial pressure 
pain. Clear mucous drainage is mostly associated with viral 
upper respiratory conditions and must be distinguished from 
the purulent, cloudy drainage associated with sinusitis. If upper 
respiratory infection is excluded, viral ARS can be separated from 
bacterial ARS on the basis of duration and prognosis; viral ARS 
should be diagnosed if the condition does not worsen, but rather 
improve within 10 days from the onset of symptom presentation, 
while bacterial ARS is considered if symptoms are present 
for longer than 10 days since day of onset or worsens within  
10 days after initial improvement.2 Moreover, as opposed to most 
other bacterial infections of the human body, fever is neither a 
required clinical sign of bacterial ARS, nor an accurate marker that 
can be applied to distinguish between viral and bacterial ARS, 
although it may be present.3 Although other symptoms, e.g. 
malaise, reduced sense of smell, maxillary pain, and increased 
ear pressure are often associated with ARS, neither of these is 
required for diagnosis.4

CRS can be diagnosed with high sensitivity if any two or more 
of any of the symptoms that usually manifest in ARS, persist 
for longer than 12 weeks.5 However, symptomological overlap 
with other conditions, e.g. allergic and non-allergic rhinitis, 
vasomotor rhinitis, and nasal septal deformities, is common 
and hence consideration of potential differential diagnoses is 
important. As opposed to ARS, CRS is primarily an inflammatory 
condition and although acute flares in viral or bacterial infection 
may complicate the illness, it is not the etiological foundation 
of the condition.2 In contrast, recurrent ARS, defined as at least  
4 episodes of ARS within a 12-month period, is generally 

caused by viral or bacterial infection and therefore, should be 
approached differently.

The clinical relationship between allergy and rhinosinusitis 
is quite ambiguous.6 In fact, allergic rhinitis is generally not a 
contributing factor in ARS but may influence the etiology and 
prognosis of CRS. Further, it is the involvement of systemic, 
rather than local intranasal markers of inflammation that 
seem to provide insight into the mechanisms underlying both 
conditions. Indeed, nasally inhaled allergens are mostly unable to 
cross into the paranasal sinuses.7 However, once inhaled, allergens 
can also be processed by macrophages and eosinophils which 
in turn involve allergen-specific T-cell immune responses8 that 
will persist until the triggering allergen is neutralised. That said, 
patients who are chronically susceptible to rhinosinusitis present 
with persistently inflamed mucous membranes, irrespective of 
the actual presence of allergens in the nasal cavity.9,10

The treatment of rhinosinusitis with or without 
comorbid allergy

Intranasal saline irrigation

Intranasal saline irrigation (not saline sprays) is regarded as first-
line intervention for both ARS and CRS. In this regard, hypertonic, 
rather than isotonic solutions may be more beneficial to thin and 
clear mucus and prevent worsening of the condition. Not only do 
nasal irrigations assist the intranasal cilia from clearing mucus, 
but it also facilitates the removal of inflammatory mediators, 
e.g. histamine and prostaglandins.11 Further, saline irrigation is 
equally recommended for both viral and bacterial ARS as well as 
for the supportive treatment of CRS due to its low incidence of 
adverse effects.12

Antibacterial therapy

Antibacterial treatment for acute and chronic sinusitis includes 
amoxicillin-clavulanic acid combination, erythromycin, 
cefuroxime, doxycycline, co-trimoxazole, or moxifloxacin for a 
total of 10 to 14 days.13,14 Although efficacy of all the mentioned 
compounds have been demonstrated in the treatment of 
sinusitis, the increasing development of resistant organisms and 

South African Family Practice 2019; 61(5):5-8
 
Open Access article distributed under the terms of the 
Creative Commons License [CC BY-NC-ND 4.0] 
http://creativecommons.org/licenses/by-nc-nd/4.0

Rhinosinusitis and allergy: a relationship of random meetings 
D Wolmarans, SF Steyn, L Brand

Centre of Excellence for Pharmaceutical Sciences, Department of Pharmacology, Faculty of Health Sciences, North-West University, 
Potchefstroom, South Africa
Corresponding author, email: dewet.wolmarans@nwu.ac.za



S Afr Fam Pract 2019;61(5):5-86

The page number in the footer is not for bibliographic referencingwww.tandfonline.com/oemd 6

antimicrobial stewardship awareness necessitate the optimal 
use of these drugs, only if and when necessary. A recent study 
reported that the majority of sinusitis prescriptions average a  
10-day treatment period.15 This is of note as previous work 
suggests short-course antibiotic treatment regimens (up to 
7 days) induce similar efficacy and outcome than long-term 
(≥ 2 days longer than short-course) regimens,16 while being 
without the increased risk for antibiotic-associated side effects.17 
Amoxicillin has a favourable side-effect profile and is therefore 
considered the first-line treatment option in chronic (and acute) 
sinusitis patients.14 Mono-therapy amoxicillin remains effective 
in low-risk patients, whereas the combination with clavulanic 
acid is recommended in patients where bacterial resistance is 
more likely (smokers, patients recently treated with antibacterials 
and/or where high rates of community resistance have been 
reported)3,18 as well as in children and elderly patients.14 As 
alluded to earlier, macrolides are often prescribed in penicillin-
allergic patients.14

Importantly, healthcare practitioners should evaluate each 
patient individually before prescribing antibiotics for sinusitis, as 
such intervention is unnecessary in the majority of patients.

Corticosteroid therapy

Corticosteroids benefit patients with both ARS and CRS, 
bearing in mind that such therapy be co-administered with oral 
antimicrobial therapy in the case of bacterial ARS.2 Intranasal 
corticosteroids have proven efficacy in the maintenance 
treatment of allergic rhinitis, acute post-viral sinusitis as well 
as chronic rhinosinusitis. Collectively, corticosteroids attenuate 
the expression and release of pro-inflammatory cytokines from 
airway epithelial cells and are effective in reducing the number 
of inflammatory and immunoreactive cells.19,20 Further, at the 
recommended doses they are safe to use, mostly being devoid 
of adrenal suppressive effect.21

Antihistamines

Although not indicated for use in bacterial ARS2 – in fact, they 
can complicate disease prognosis – all antihistamines are equally 
effective against the symptoms of allergic rhinitis and in some 
cases rhinosinusitis, but differ with regard to their chemical 
structures, clinical pharmacology and toxicology.22,23

Oral and topical second generation H1 antihistamines are 
commonly used as a first-line intervention for the symptoms of 
allergic rhinitis, including sneezing, nasal itching, rhinorrhoea24; 
however, they have modest effects on nasal congestion, 
which often predominates in persistent allergic rhinitis. 
Although differing in chemical structure, all of the newer, 
second-generation antihistamines demonstrate high affinity 
for H1 receptors and therefore present with equal efficacy, 
anti-inflammatory potential (not necessarily linked to their 
H1 blocking activity) and a reduced side-effect profile.

23,25 
However, that they differ on a chemical level is important to 
explain differences in their pharmacokinetic properties.25 Most 
of the currently available second generation H1 antihistamines 
are lab-synthesised derivatives from parent antihistaminergic 

compounds, which may have had undesirable central nervous 
system (CNS) and cardiotoxic adverse effects if administered as 
is. However, the single greatest advantage of using the second-
generation antihistamines as opposed to their first-generation 
predecessors, is the reduced risk for CNS-related adverse effects 
that characterised therapy with the first-generation compounds.

In terms of their administration to patients with non-bacterial 
rhinosinusitis, it is interesting to note that all H1 antihistamines 
have anti-inflammatory effects, mediated via their inhibition 
of histamine-activated NF-κB synthesis, a transcription factor 
involved in the synthesis of pro-inflammatory cytokines and 
adhesion molecules.26 This results in reduced nasal congestion 
and hyperreactivity when administered according to a regular 
daily dosing schedule, an effect not clinically evident if given 
on an as-needed basis.26 Against this background, the relatively 
novel H1 antihistamine, rupatadine, displays an additional ability 
to block platelet activating factor receptors, thereby decreasing 
platelet aggregation which contributes to its anti-inflammatory 
effect.27,28 Continuous treatment with the H1 antihistamines 
over a longer period of time proves to be more beneficial and 
effective than on-demand treatment.29 

The leukotriene receptor antagonists

Montelukast is an orally active compound, initially developed for 
the prophylactic treatment of asthma and the only antileukotriene 
approved for the treatment of allergic rhinitis. The drug binds 
with high affinity and selectivity to the leukotriene-1 receptor, 
thereby inhibiting the physiologic actions of leukotrienes in the 
upper respiratory system.30 The drug also reduces the number of 
circulating eosinophils, suggesting that it acts on a systemic level 
to reduce the physiological sequelae of allergic inflammation.30 
Moderate evidence for the efficacy of antileukotrienes in 
the treatment of CRS with nasal polyposis exists, especially 
in combination with topical and/or oral corticosteroids.31 
Unfortunately, post-marketing reports of neuropsychiatric 
adverse effects, including depression, aggression, insomnia, 
irritability, and nightmares,32 have prevented the drug from 
being registered as an over-the-counter therapy for allergic 
rhinitis and rhinosinusitis.33

Immunotherapy

Immunotherapy is only indicated in patients with moderate 
to severe refractory allergic rhinitis and CRS. Furthermore, 
subcutaneous omalizumab is currently the only monoclonal IgE 
antibody registered in South Africa in this category. By binding 
to high levels of circulating, allergy-associated IgE-antibodies, 
omalizumab removes IgE antibodies from the circulation, thereby 
reducing its potent ability to cause mast cell degranulisation and 
subsequent allergic reactions.34

Decongestants

Whether administered locally or systemically, decongestants 
induce nasal vasoconstriction via alpha (α)-adrenoceptor 
stimulation, thereby reducing hyperaemia and mucosal 
swelling, leading to increased airflow and overall improvement 
of nasal breathing. Due to the reduction in nasal blood flow, 



S Afr Fam Pract 2019;61(5):5-88

The page number in the footer is not for bibliographic referencingwww.tandfonline.com/oemd 8

plasma exudation and nasal discharge is also decreased, 
altogether contributing to the decongestant properties.35 Oral 
decongestants include direct- (i.e. phenylephrine) and indirect 
acting (i.e. pseudoephedrine) sympathomimetics. However, 
due to their general non-selectivity and systemic absorption, 
their α-adrenoceptor stimulating effects are not limited only 
to the nasal cavity. In fact, side effects generally associated 
with systemic decongestants, include, but are not limited, to 
hypertension, insomnia and appetite suppression.

Topical decongestants could be a more attractive treatment 
strategy in treating nasal congestion. In this regard, topical 
decongestants include the α-adrenoceptor agonist imidazoles, 
xylometazoline and oxymetazoline. Despite differences in 
receptor affinity (xylometazoline being a full agonist to the 
α2B-adrenoceptor, and oxymetazoline a more potent and 
full agonist at the α2B-adrenoceptor with additional weak  
α1A-adrenoceptor partial agonist properties),

36 both drugs induce 
fast-acting decongestant effects with similar duration of action.37 
Nevertheless, the overall higher affinity for the α2-adrenoceptor 
subtype of topical decongestants, relative to α1, facilitates an 
improved side-effect profile compared to systemic and non-
selective decongestants. In fact, α2-adrenoceptor agonists 
might have a greater constricting effect on nasal veins, as 
opposed to the equipotent constricting effects of non-selective 
adrenoreceptor decongestants.35 This could partly be due to 
the dominating α2-adrenoceptor-mediated vasoconstricting 
effects, relative to the α1-adrenoreceptor effect, within the 
nasal cavity.38 In fact, the α2-adrenoceptor agonist, clonidine, 
was originally developed as a decongestant,39 but due to its 
systemic effects, most notably hypotension and bradycardia, its 
decongestant potential was deemed inferior. Importantly, topical 
decongestants are not free from side effects, and although being 
a debated topic,40-42 prolonged use of topical decongestants are 
commonly associated with rhinitis medicamentosa – rebound 
congestion.41,43

Summary

In this article, we summarised the major clinical aspects of acute 
and chronic rhinosinusitis. We further highlighted the fact that 
contrary to general perception, allergic rhinitis and rhinosinusitis 
are in fact two fundamentally distinct conditions, that may 
overlap to some extent and co-present in some patients under 
certain circumstances. That said, the pharmacological treatment 
of these conditions overlaps significantly. As such, we also 
elaborated on the different available drug classes and explained 
from a mechanistic perspective how they may be used to 
improve overall disease prognosis.

References
1. Meltzer EO, et al. Rhinosinusitis: establishing definitions for clinical research and 

patient care. J Allergy Clin Immunol. 2004;114(6):155-212.

2. Rosenfeld RM, et al. Clinical practice guideline (update): adult sinusitis. 
Otolaryngol–Head Neck Surg. 2015; 152(2_suppl):S1-S39.

3. Rosenfeld RM. Acute sinusitis in adults. N Eng J Med. 2016;375(10):962-70.

4. Fokkens W, et al. EAACI position paper on rhinosinusitis and nasal polyps 
executive summary. Allergy. 2005;60(5):583-601.

5. Bhattacharyya N. Clinical and symptom criteria for the accurate diagnosis of 
chronic rhinosinusitis. Laryngoscope. 2006;116(S110):1-22.

6. Marcus S, et al. Chronic Rhinosinusitis: Does Allergy Play a Role? Medical 
Sciences. 2019;7(2):30.

7. Adkins TN, et al. Does inhaled pollen enter the sinus cavities? Ann Allergy 
Asthma  Immunol. 1998;81(2):181-4.

8. Kennedy JL, Borish L. Chronic sinusitis pathophysiology: the role of allergy. Am J 
Rhinol Allergy. 2013;27(5):367-71.

9. Jahnsen FL, et al. Eosinophil infiltration is related to increased expression of 
vascular cell adhesion molecule-1 in nasal polyps. Am J Respir Cell Mol Biol. 
1995;12(6):624-32.

10. Inman MD, et al. Allergen-induced increase in airway responsiveness, airway 
eosinophilia, and bone-marrow eosinophil progenitors in mice. Am J Respir Cell 
Mol Biol. 1999;21(4):473-9.

11. Brown CL, Graham SM. Nasal irrigations: good or bad? Curr Opin 
Otolaryngol Head Neck Surg. 2004;12(1):9-13.

12. Inanli S, et al. The effects of topical agents of fluticasone propionate, 
oxymetazoline, and 3% and 0.9% sodium chloride solutions on mucociliary 
clearance in the therapy of acute bacterial rhinosinusitis in vivo. Laryngoscope. 
2002;112(2):320-5.

13. Merck laboratories, Nose and paranasal sinus disorders, in The Merck manual, M. 
Beers, ed. Merck Research Laboratories: USA; 2006. p. 831-3.

14. Chow AW, et al. IDSA clinical practice guideline for acute bacterial rhinosinusitis 
in children and adults. Clin Infect Dis. 2012;54(8):e72-e112.

15. King LM, et al. Antibiotic therapy duration in US adults with sinusitis. JAMA 
Internal Med. 2018;178(7):992-4.

16. Falagas ME, et al. Effectiveness and safety of short vs. long duration of antibiotic 
therapy for acute bacterial sinusitis: a meta‐analysis of randomized trials. Br J 
Clin Pharmacol. 2009;67(2):161-71.

17. Falagas ME, et al. Comparison of antibiotics with placebo for treatment of acute 
sinusitis: a meta-analysis of randomised controlled trials. Lancet Infect Dis. 
2008;8(9):543-52.

18. Rosenfeld RM, et al. Clinical practice guideline (update): adult sinusitis. 
Otolaryngol Head Neck Surg. 2015.152(2 Suppl):S1-S39.

19. Wang JH, et al. Expression of RANTES by human bronchial epithelial cells in 
vitro and in vivo and the effect of corticosteroids. Am J Respir Cell Mol Biol. 
1996;14(1):27-35.

20. Trigg CJ, et al. Placebo-controlled immunopathologic study of four months of 
inhaled corticosteroids in asthma. Am J Respir Crit Care Med. 1994;150(1):17-22.

21. Nguyen K-L, et al. The effect of a steroid “burst” and long-term, inhaled 
fluticasone propionate on adrenal reserve. Ann Allergy Asthma Immunol. 
2003;91(1):38-43.

22. Shamizadeh S, Brockow K, Ring J. Rupatadine: efficacy and safety of a 
non-sedating antihistamine with PAF-antagonist effects. Allergo J Int. 
2014;23(3):87-95.

23. Leurs R, Church M, Taglialatela M. H1‐antihistamines: inverse agonism, anti‐
inflammatory actions and cardiac effects. Clin Exp Allergy. 2002;32(4):489-98.

24. Okubo K, et al. Long-term safety and efficacy of rupatadine in Japanese patients 
with perennial allergic rhinitis: a 52-week open-label clinical trial. J Drug Assess. 
2019;8(1):104-14.

25. Tillement J.-P. Pharmacological profile of the new antihistamines. Clin Exp 
Allergy Reviews. 2005;5(1):7-11.

26. Church DS, Church MK. Pharmacology of Antihistamines. World Allergy Organ J. 
2011;4:S22-S27.

27. Wasilewska K, et al. Ethylcellulose in Organic Solution or Aqueous Dispersion 
Form in Designing Taste-Masked Microparticles by the Spray Drying Technique 
with a Model Bitter Drug: Rupatadine Fumarate. Polymers. 2019;11(3):522.

28. Thorn C, et al. Rupatadine - Pharmacology, clinical profile and safety of a new 
antihistamine with PAF-antagonizing quality. Allergologie. 2010;33(10):429-40.

29. Ciprandi G, et al. Continuous versus on demand treatment with cetirizine for 
allergic rhinitis. Ann Allergy Asthma Immunol. 1997;79(6):507-11.

30. Van Adelsberg J, et al. Randomized controlled trial evaluating the clinical benefit 
of montelukast for treating spring seasonal allergic rhinitis. Ann Allergy Asthma 
Immunol. 2003;90(2):214-22.

31. Smith TL, Sautter NB. Is montelukast indicated for treatment of chronic 
rhinosinusitis with polyposis? Laryngoscope; 2014;124(8):1735-6.

32. Haarman MG, van Hunsel F, de Vries TW. Adverse drug reactions of montelukast 
in children and adults. Pharmacol Res Perspect. 2017;5(5):e00341.

33. Gerald JK, Wechsler ME, Martinez FD. Asthma medications should be available 
for over-the-counter use: pro. Ann Am Thorac Soc. 2014;11(6):969-74.



34. Vashisht P, Casale T. Omalizumab for treatment of allergic rhinitis. Expert Opin Biol 
Ther. 2013;13(6):933-45.

35. Corboz M, et al. Mechanism of decongestant activity of α2-adrenoceptor agonists. 
Pulm Pharmacol Ther. 2008;21(3):449-54.

36. Haenisch B, et al. Alpha‐adrenoceptor agonistic activity of oxymetazoline and 
xylometazoline. Fundam Clin Pharmacol. 2010;24(6):729-39.

37. Eskiizmir G, et al. A comparative analysis of the decongestive effect of 
oxymetazoline and xylometazoline in healthy subjects. Eur J Clin Pharmacol. 
2011;67(1):19-23.

38. Corboz MR, et al. Pharmacological characterization of postjunctional 
α-adrenoceptors in human nasal mucosa. Am J Rhinol. 2005;19(5):495-502.

39. Stähle H. A historical perspective: development of clonidine. Best  Pract Res Clin 
Anaesthesiol. 2000;14(2):237-46.

40. Mortuaire G, et al. Rebound congestion and rhinitis medicamentosa: nasal 
decongestants in clinical practice. Critical review of the literature by a medical 
panel. Eur Ann Otorhinolaryngol Head Neck Dis. 2013;130(3):137-44.

41. Passàli D, et al. Nasal decongestants in the treatment of chronic nasal obstruction: 
efficacy and safety of use. Expert Opin Drug Saf. 2006;5(6):783-90.

42. Graf P, Enerdal J, Hallén H. Ten days’ use of oxymetazoline nasal spray with 
or without benzalkonium chloride in patients with vasomotor rhinitis. Arch 
Otolaryngol Head Neck Surg. 1999;125(10):1128-32.

43. Snidvongs K, Thanaviratananich S. Update on intranasal medications in 
rhinosinusitis. Curr Allergy Asthma Rep. 2017;17(7):47.