Panacea Journal of Medical Sciences 2021;11(2):321–325

Content available at: https://www.ipinnovative.com/open-access-journals

Panacea Journal of Medical Sciences

Journal homepage: http://www.pjms.in/  

 

Original Research Article

Prospective study on prevalence of aeroallergens in allergic rhinitis in a teaching
hospital, Telangana

G Shyam1, G Rachana1,*, Mohammed Yawar1

1Dept. of ENT, Maheshwara Medical College, Patancheru, Hyderabad, Telangana, India
 

 

A R T I C L E I N F O

Article history:
Received 06-12-2020
Accepted 13-01-2021
Available online 25-08-2021

Keywords:
Allergic rhinitis
Aeroallergens
IgE antibody
Eosinophilia

A B S T R A C T

Background: Allergic rhinitis is an IgE antibody mediated, inflammatory disease.
The most commonly encountered risk factors for allergic rhinitis are presence of atopy, asthma, eczema,
and other allergic illnesses. Identification of aeroallergens helps in patient counseling to modify life style
and prevent exposure to triggering factors.
Aim of the study: To determine the prevalence of aeroallergens in allergic rhinitis.
Materials and Methods: This was a prospective study done in cases of allergic rhinitis over a duration of
one year from January 2019 to December 2019. Complete history taking was followed by ENT examination
including Rhinoscopy and endoscopy, peripheral smear examination for eosinophils, absolute eosinophil
count testing and Skin prick testing with known allergens and serum IgE level testing.
Results: A total of 145 cases of allergic rhinitis were studied. The patient age ranged from 11 years to 50
years. The male to female ratio was 0.5:1. Most common allergen causing allergic rhinitis was dust mite
which constituted about 44.1% cases. The next common allergen was Mold which accounted for 20.6%
cases.
Conclusion: We conclude that there are numerous aeroallergens that can cause allergic rhinitis and the most
common ones are dust mites, molds, house dust, animal dander, pollen and others. Correct identification
of the aeroallergen helps in the proper counseling of the patients so as to prevent exposure to those
aeroallergens thereby reducing the episodes and severity of allergic rhinitis.

This is an Open Access (OA) journal, and articles are distributed under the terms of the Creative Commons
Attribution-NonCommercial-ShareAlike 4.0 License, which allows others to remix, tweak, and build upon
the work non-commercially, as long as appropriate credit is given and the new creations are licensed under
the identical terms.

For reprints contact: reprint@ipinnovative.com

1. Introduction

Allergic rhinitis is an IgE antibody mediated, inflammatory
disease that is characterized by one or more of the
following symptoms: nasal congestion, rhinorrhea (anterior
and posterior), sneezing, and itching. 1,2

Allergic rhinitis may be classified by 3 temporal pattern
and context of exposure to a triggering allergen, 4

frequency and duration of symptoms, and/ or 1 severity.
Temporal patterns may be 3 seasonal (eg, pollens), 4

perennial (year-round exposures, eg, house dust mites),
or 3 episodic environmental (from allergen exposures not

* Corresponding author.
E-mail address: drrachana1234@gmail.com (G. Rachana).

normally encountered in the patient’s home or occupational
environment, eg, visiting a home with pets not present in an
individual’s home. 1,2

Allergic rhinitis severity can be classified as being
mild (when symptoms are present but are not interfering
with quality of life) or more severe (when symptoms are
severe enough to interfere with quality of life. 1,2 Factors
that may lead to a more severe problem include sleep
disturbance; impairment of daily, sport, or leisure activities;
and impairment of school or work performance. 5

The most common encountered risk factors for allergic
rhinitis are presence of atopy, asthma, eczema, and other
allergic illnesses. 6

https://doi.org/10.18231/j.pjms.2021.065
2249-8176/© 2021 Innovative Publication, All rights reserved. 321



322 Shyam, Rachana and Yawar / Panacea Journal of Medical Sciences 2021;11(2):321–325

Parental history of allergic illness is also a well-known
risk factor. The risk of allergic rhinitis (AR) rises in
children of parents with AR, asthma, hay fever and pollen
allergies. 7–9

Factors such as, vitamin D, obesity, exposure to cigarette
smoke, amplify overall serum IgE, elevate blood eosinophils
and other environmental exposures of urban settings can
also contribute to AR. 10,11

2. Aim of the study

To determine the prevalence of aeroallergens in allergic
rhinitis.

3. Materials and Methods

This was a prospective study done in cases of allergic
rhinitis atttending the ENT OPD at Maheshwara Medical
College, Patancheru, Hyderabad, Telangana. The study
period was for one year from beginning of January 2019
to end of December 2020.

There were no ethical issues involved. Informed consent
was obtained from all the patients included in the study.

3.1. Inclusion criteria

1. Age range from 11 years to 50 years.
2. Both genders.
3. Rhinorrhea.
4. Sneezing.
5. Symptoms of nasal obstruction.

3.2. Exclusion criteria

1. Age less than 11 years and more than 50 years.
2. Pregnant women.
3. Patients with chronic respiratory tract infections.

3.3. Methodology

A thorough history was taken including age, gender,
occupation, history of atopy, etc. Symtoms such as sneezing,
rhinorrhoea, nasal itching and nasal congestion were asked
and noted thoroughly.

Personal history such as any food allergy or drug allergy
was noted. Complete local and general examination was
done.

ENT examination was done including anterior
rhinoscopy, and diagnostic nasal endoscopy.

Peripheral blood smear examination was done in all cases
and eosinophil count was noted.

Absolute eosinophil count was noted and up to
440 cells/mm3 was taken as normal. Total serum IgE
level was measured: It was measured by ELISA and
chemiluminescent assay. The upper limit of normal was
taken as 150 IU/ml.

Skin prick test (SPT): The patients were tested for few
aeroallergens.

The tests were performed according to standard methods
with allergens. Glycerinated buffered saline was used as a
negative control and histamine diphosphate or dichloride
was used as a positive control.

The skin prick reaction was read after 15-20 minutes and
considered positive if the reaction wheal diameter was at
least 3 mm larger than negative control.

Data was entered into excel sheets for statistical analysis.

4. Observations and Results

Total of 145 cases of allergic rhinitis were studied

Table 1: Age and gender distribution
Age
distribution

Females Males No. of cases

11 – 20 years 20 15 35 (24.1%)
21-30 years 26 19 45 (31% )
31 - 40 years 45 10 55 (37.9%)
41 – 50 years 40 60 100 (6.8%)
Total 95(65.5%) 50(34.4%) 145 (100%)

In the present study, age distribution ranged from 11
years to 50 years. Majority of the cases were reported among
31-40 years.Table 1

4.1. Gender distribution

There were 95 (65.5%) female patients and 50(34.4%) male
patients in the study and the male to female ratio was 0.5:1.

Table 2: Distribution based on symptoms
Symptoms No. of cases Percent

(%)
Only Rhinnorhea 30 20.6%
Nasal obstruction + Sneezing 22 15.1%
Nasal obstruction +
Rhinnorhea

35 24.1%

Ictching in nose + Rhinnorhea 20 13.7%
Nasal congestion 18 12.4%
Nasal obstruction + Rhinnorhea
+Pruritis of eyes

20 13.7%

Total 145 100%

In the present study most of the cases presented with
rhinorrhea and/or nasal obstruction. Rhinnorhea.

Out of 145 patients with allergic rhinitis, 55% had
history of episodic symptoms, 23% had complaints of
aggravation of symptoms due to change of season and 12%
had symptoms throughout the year.Table 2

4.2. Distribution based on past history

History of atopy was seen in 120(82.7%) and history of food
allergy was present in 25(17.2%) cases.



Shyam, Rachana and Yawar / Panacea Journal of Medical Sciences 2021;11(2):321–325 323

Table 3: Distribution based on type of allergen
Allergens No. of cases Percent (%)
House dust 20 13.7%
Dust Mite 64 44.1%
Animal dander 10 6.8%
Grass Pollen 11 7.5%
Trees pollen 4 2.7%
Insects 5 3.4%
Mold 30 20.6%
Fungal spores 10 0.6%
Total 145 100%

In the present study, most common allergen causing
allergic rhinitis was dust mite which constituted about
44.1% cases followed by Molds and house dust.Table 3

4.3. Distribution of cases based on seasonal variation

Dust mites and dusts were more common during winter
season, 74(51%) cases, pollens were more common during
summer season 35(24.1%) cases and fungi and insects were
common during rainy season 36 (24.8%) cases.

4.4. Distribution based on eosinophil count on
peripheral blood smear

In the present study, 32(22%) cases showed eosinophil
count <6% and 113(77.9%) cases showed >6% eosinophil
count.

4.5. Distribution based on absolute eosinophil count
(AEC)

There were 30(20.6%) cases that had AEC <440/cumm and
115(79.3%) cases that had AEC > 440/cumm.

4.6. Distribution based on Serum IgE levels

There were 30(20.6%) cases with serum IgE level of <150
IU/L and 115(79.3%) cases with >150 IU/L serum IgE level.

5. Discussion

This was a prospective study to determine the prevalence of
allergic rhinitis in hospital visiting patients in Telangana. A
total of 145 cases were studied.

5.1. Comparative studies related to age distribution

In the present study, most of the cases (37.9%) of allergic
rhinitis were observed among 31-40 years followed by 31%
in the 21-30 years age group. Kammili J et al 12 in their
study observed that the most common age-group affected
was 21-30 years, i.e., 66.66% while only 15% of the patients
belonged to the age-group of 31–40 years. Aggarwal D et
al 13 observed majority of their patients were in the age

group of 31-40 years (31%) with male to female ratio of
1.5: 1. Wang W et al 14 reported the median age as 19.0
years. Bellamkonda M et al 15 in a similar study observed
the youngest patient to be 16 years and the oldest as 45
years. The mean age of their study group was 27 years. Our
observations compare well with the above studies.

5.2. Comparative studies related to gender distribution

In the present study, females were predominant ie. 65.5%
(95/145) when compared to males ie, 34.4 % (50/145).
Bellamkonda M et al 15 in their study observed that female
patients were slightly more than the male patients with a
male to female ratio of 0.935:1 ie they had 31 females and
29 males in their study. Kammili J et al 12 observed allergic
rhinitis more in males than in females, with 66.66% in males
and 33.33% in females. Wang W et al 14 in their study had
2269 males (55.5%) and 1816 (44.5%) females.

5.3. Comparative studies related to Prevalence of
sensitisation to aeroallergens

In the present study, most common allergen causing allergic
rhinitis was dust mite which constituted about 44.1%. The
next common allergen was Mold which occupied 20.6%,
followed by house dust 13.7%, animal dander (6.8%),
grass pollen 7.5% trees pollen 2.7%, insects 3.4% and
fungal spores 0.6%. In Wang W et al 14 study, among the
4085 patients with allergic rhinits, the prevalence rates of
sensitization to aeroallergens were as follows: 84.4% for
house dust mites, 23.4% for pet allergens (combination of
dog hair and cat dander), 21.1% for cockroaches, 9.1% for
mould allergens, 7.7% for mixed tree pollens and 6.0% for
mixed weed pollen. In Kammili J et al 12 study, dust mites
(20.82%) and dusts (12.49%) were more common during
winter season, pollens (17.49%) were more common during
summer season, and fungi (4.9%) and insects (5.83%)
during rainy season. Most common allergen in their study
was dust mite (32.48%) followed by pollens (27.48%),
dusts (18.32%), fungi (10.82%), and insect (9.16%). In the
study by Aggarwal D et al 13 the most common allergen/
irritant causing aggravation of symptoms was dust, which
was responsible for 97% of cases, followed by smoke (22%)
and the least was pollen (5%). In the study by Nagare P
et al 16 dust was the most common risk factor for allergic
rhinitis accounting for 82% followed by weather changes in
46% cases.

5.4. Comparative studies related to symptoms

In the present study, majority of the cases presented with
nasal obstruction and rhinnorhea ie, 24.1% cases. Next
common symptom was only rhinorhea and was seen in
20.6% cases whereas, in the study by Bellamkonda M et
al 15 the most common nasal symptom was nasal discharge
(80%) followed by sneezing (78.34%) and nasal obstruction



324 Shyam, Rachana and Yawar / Panacea Journal of Medical Sciences 2021;11(2):321–325

(70%). Seven patients (11.67%) had altered sense of
smell and headache. The most common ophthalmological
symptom associated with allergic rhinitis was congestion
in eyes in about 40% of patients followed by itching.
Photophobia and foreign body sensation were seen in 1.67%
patients, respectively in their study. Our findings correlate
well with the above authors.

5.5. Comparative studies related to history of
comorbidities

In the present study history of atopy was seen in 82.7%
cases, and 17.2% had history of food allergy.

Bellamkonda M et al 15 observed in a similar study that a
total of 19(31.67%) patients had a positive family history of
allergy. Two had history of food allergy; one patient to milk
and other to peanuts. One patient had drug hypersensitivity
to aspirin.

Nagare P et al 16 observed dust allergy among 50 patients,
5 had family history of allergic rhinitis and 10% had atopy.

5.6. Comparative studies related to peripheral blood
smear eosinophilia

In the present study, 77.9% cases showed eosinophil count >
6% whereas, in the study by Nagare P et al 16 they observed
that eosinophil count in 66% patients was < 5% and in 34%
patients it was >= 5%. Aggarwal D et al 13 observed 49%
of patients had raised eosinophils in their peripheral blood
smear.

5.7. Comparative studies related to AEC

In the present study 79.3% cases showed AEC > 440
cells/cumm. In the study by Bellamkonda M et al 15 the
majority of patients (26.6%) had AEC ranging between 301
and 400 cells/cumm followed by 25% patients in range
of 400-500 cells/cumm. Aggarwal D et al 13 observed an
absolute eosinophil count (AEC) of >440 cells/mm3 in 50%
of patients.

5.8. Comparative studies related to Skin prick test

In the present study, the Skin prick test was strongly positive
for dust mite in 44.1% cases. The next common allergen was
Molds which accounted for 20.6% cases, followed by house
dust in 13.7% cases, animal dander in 6.8% cases, grass
pollen in 7.5% cases, trees pollen in 2.7% cases, insects in
3.4% cases and fungal spores in 0.6% cases. Aggarwal D
et al 13 in their study observed the prevalence of skin prick
test was strongly positive for pollens (46.19%), followed by
dust (16.4%), dust mites (15.7%), fungus (9.7%), insects
(9.24%) and to epithelia (2.77%). Among 68 aeroallergens,
most common offending allergen was D-farinae (30%) in
their study.

6. Conclusion

We conclude that there are numerous aeroallergens that can
cause allergic rhinitis and the most common ones are dust
mites, molds, house dust, animal dander, pollen and others.
Correct identification of the aeroallergen helps in the proper
counseling of the patients so as to prevent exposure to those
aeroallergens thereby reducing the episodes and severity of
allergic rhinitis.

7. Conflict of Interest

The authors declare that there are no conflicts of interest in
this paper.

8. Source of Funding

None.

References
1. Benincasa C, Lloyd RS. Evaluation of fluticasone propionate aqueous

nasal spray taken alone and in combination with cetirizine in the
prophylactic treatment of seasonal allergic rhinitis. Drug Investig.
1994;8(4):225–33.

2. Lorenzo GD, Pacor ML, Pellitteri ME, Morici G, Gregoli AD,
Bianco C, et al. Randomized placebo-controlled trial comparing
fluticasone aqueous nasal spray in mono-therapy, fluticasone plus
cetirizine, fluticasone plus montelukast and cetirizine plus montelukast
for seasonal allergic rhinitis. Clin Exp Allergy. 2004;34(2):259–67.

3. Anolik R. Clinical benefits of combination treatment with
mometasone furoate nasal spray and loratadine vs monotherapy with
mometasone furoate in the treatment of seasonal allergic rhinitis. Ann
Allergy Asthma Immunol. 2008;100(3):264–71.

4. Barnes ML, Ward JH, Fardon TC, Lipworth BJ. Effects of
levocetirizine as addon therapy to fluticasone in seasonal allergic
rhinitis. Clin Exp Allergy. 2006;36(5):676–84.

5. Martin BG, Andrews CP, Bavel JV. Comparison of fluticasone
propionate aqueous nasal spray and oral montelukast for the treatment
of seasonal allergic rhinitis symptoms. Ann Allergy Asthma Immunol.
2006;96(6):851–7.

6. Sultész M, Gabor K, Hirschberg A, Galffy G. Prevalence and risk
factors for allergic rhinitis in primary schoolchildren in Budapest. Int
J Pediatr Otorhinolaryngol. 2010;74(5):503–9.

7. Wang QP, Wu KM, Li ZQ, Xue F, Chen W, Ji H, et al.
Association between maternal allergic rhinitis and asthma on the
prevalence of atopic disease in offspring. Int Arch Allergy Immunol.
2012;157(4):379–86.

8. Westman M, Kull I, Lind T, Melen E, Stjarne P, Toskala E, et al. The
link between parental allergy and offspring allergic and nonallergic
rhinitis. Allergy. 2013;68(12):1571–8.

9. Dold S, Wjst M, Mutius EV, Reitmeir P, Stiepel P. Genetic risk for
asthma, allergic rhinitis, and atopic dermatitis. Arch Dis Childhood.
1992;67(8):18–22.

10. Wright AL, Holberg CJ, Halonene M, Martinez FD, Morgan W,
Taussig LM, et al. Epidemiology of physician-diagnosed allergic
rhinitis in childhood. Pediatrics. 1994;94(6):895–901.

11. Musaad S, Patterson T, Ericksen M, Lindsey M, Dietrich K, Succop P,
et al. Comparison of anthropometric measures of obesity in childhood
allergic asthma: central obesity is most relevant. J Allergy Clin
Immunol. 2009;123(6):1321–7.

12. Kammili J, Praveenkumar. Analysis of Distribution of Allergens and
its Seasonal Variation in Allergic Rhinitis. J Med Sci. 2019;5(3):59–
62. doi:10.5005/jp-journals-10045-00129.

13. Aggarwal D, Abhhilash S, Kapur S, Gupta D. Study of causal
aeroallergens in allergic rhinitis. Int J Otorhinolaryngol Head Neck

http://dx.doi.org/10.5005/jp-journals-10045-00129


Shyam, Rachana and Yawar / Panacea Journal of Medical Sciences 2021;11(2):321–325 325

Surg. 2019;5(4):916–21.
14. Wang W, Huang X, Chen Z, Zheng R, Chen Y, Zhang G, et al.

Prevalence and trends of sensitisation to aeroallergens in patients with
allergic rhinitis in Guangzhou, China: a 10-year retrospective study.
BMJ Open. 2016;6(5):11085. doi:10.1136/bmjopen-2016-011085.

15. Bellamkonda M, Vinodkumar G. Clinicopathological study of allergic
rhinitis. Asian J Pharm Clin Res. 2017;10(1):186–91.

16. Nagare P, Chavan S, Jain P, Burgute S. Study of clinicopathological
profile in patients of Allergic Rhinitis. Indian J Basic Appl Med Res.
2019;8(2):374–80.

Author biography

G Shyam, Associate Professor

G Rachana, Senior Resident

Mohammed Yawar, Senior Resident

Cite this article: Shyam G, Rachana G, Yawar M. Prospective study on
prevalence of aeroallergens in allergic rhinitis in a teaching hospital,
Telangana. Panacea J Med Sci 2021;11(2):321-325.

http://dx.doi.org/10.1136/bmjopen-2016-011085