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. 2016 Feb 12;9:13–20. doi: 10.2147/RMHP.S98311

Hand hygiene knowledge and practice among university students: evidence from Private Universities of Bangladesh

Marufa Sultana 1,, Rashidul Alam Mahumud 1, Abdur Razzaque Sarker 1, Sarder Mahmud Hossain 2
PMCID: PMC4758791  PMID: 26929673

Abstract

Hand hygiene has achieved the reputation of being a convenient means of preventing communicable diseases. Although causal links between hand hygiene and rates of infectious disease have also been established earlier, studies focusing on hand hygiene among university-going students are not adequate in number. This study evaluated handwashing knowledge, practice, and other related factors among the selected university students in the city of Dhaka, Bangladesh. A cross-sectional study was conducted among 200 undergraduate students from four selected universities. A pretested, semistructured questionnaire, that included a checklist associated with handwashing practice, was applied to capture all relevant data. The mean (± SD) age of the participants was 20.4 (±1.8) years. The majority of the students washed their hands with water, but only 22.5% washed their hands effectively by maintaining the correct steps and frequency of handwashing with water, and soap or hand sanitizer. The mean (± SD) score of the participants’ hand hygiene practice was 50.81 (±4.79), while the total score with all perfect answers was considered as 66. Regression coefficient demonstrated that age has a negative influence on hand hygiene practice, as older students have lower scores compared to the younger ones (P<0.01). However, the unmarried students were a significant predictor for influencing the incensement of handwashing practice compared to the married ones (P<0.01). Findings of this study designate widespread insufficient hand hygiene practice in the university-going students and indicate a need for an extensive public health education program on this topic. Furthermore, availability of soap and sufficient water supply is needed within the university setting to facilitate handwashing. Therefore, supporting quantity and quality of available campus-based public health education programs along with providing health-washing equipment is suggested.

Keywords: hand hygiene, hand washing, practice, university students

Introduction

Hand hygiene is a milestone of infectious disease control, and promotion of improved hand hygiene has been recognized as an important public health measure.1,2 It has long been recognized to be a convenient, effective, and also cost-effective means of preventing communicable diseases.2 According to the definition of World Health Organization, hand hygiene is a general term referring to any action of hand cleansing, ie, it is the act of cleaning one’s hands with or without the use of water or another liquid, or with the use of soap, for the purpose of removing soil, dirt, and/or microorganisms.3 A causal link between hand hygiene and rates of infectious disease illness has also been established earlier.4,5 Globally, >3.5 million children younger than 5 years,6,7 mainly concentrated in developing countries8 including Bangladesh, die from diarrhea and acute lower respiratory tract infections. The transmission of communicable diseases is responsible for >164 million lost school days per school year among students up to twelfth grade worldwide.9 Approximately 2.4 million deaths can be prevented annually by good hygiene practice, reliable sanitation, and drinking water.10 A meta-analysis on 30 hand hygiene studies found that improvements in handwashing reduced the incidence of upper respiratory tract infections by 21% and gastrointestinal illnesses by 31%.11 Another evidence showed that handwashing with soap could reduce the risk of diarrheal diseases by 42%–47%, and handwashing promotion could save millions of lives.12

Despite the proven importance and benefits of washing hand, proper handwashing is not as pervasive as desired to prevent infections until now, especially in the developing countries that bear the greatest burden of infectious diseases. A survey undertaken in Bangladesh indicated that handwashing practice with soap before eating was much lower than after defecation, and a gap persists between perception and practice of proper handwashing practices with soap.10 Another observational study in rural Bangladesh showed that 14% of all persons washed both hands with soap after defecation, while <1% used soap and water for washing hand before eating.13 Several studies addressed hand hygiene among different population in Bangladesh; however, hand hygiene studies among college or university students are very limited.10,13,14 Although the morbidity and mortality associated with respiratory and gastrointestinal illnesses among university students are relatively low, these infections may contribute to absenteeism along with sickness presenteeism, which can ultimately affect academic performance and efficiency15 and can also be associated with outbreaks of viral gastroenteritis, upper respiratory tract infections, and group B streptococcal colonization in this setting,15 which ultimately affect potential human resource development. With the limited research about hand hygiene knowledge and practice among university students, this study evaluated handwashing knowledge, attitude, practice, and other related factors among the selected university students of Dhaka city in Bangladesh.

Methods

Study design and setting

A cross-sectional study was conducted among the under-graduate private university-going students in Banani of Dhaka city during August 2013–September 2013. Banani is an affluent residential area with a number of restaurants, universities, and shopping centers, as well as schools and members’ clubs, in Dhaka, the capital of Bangladesh. Out of nine private universities located in Banani, Dhaka, four nearby universities are purposively selected for this survey. The universities were selected based on the criteria that must have undergraduate course level. The inclusion criterion for participants was being a registered undergraduate ongoing student of any year of bachelor level; and the participation was completely voluntary. Study participants provided written consent prior to participating; and participants’ anonymity and confidentiality were maintained throughout the study. This study was conducted through Northern University where only written consent from participants was required and no IRB was applicable for this study.

Sample size estimation

An earlier study showed that 72.9% of the overall college students washed their hands.16

The following formula has been used for calculating sample size:

n=z2p(100p)d2 (1)

where n is the required sample size, d the marginal error level (we considered the proportion of handwashing practice of students at 6.5% proportion of marginal error level), and z the standard normal deviate (considered 1.96 for 95% confidence interval [CI]). The formula provided that the significant sample size was 180. Considering a 10% nonresponse rate to the survey, the total required sample size was 198. Finally, a total of 200 participants who were willing to give written consent and participate in the study, were interviewed.

Instruments and procedure

A pretested, semistructured, interviewer-administrated questionnaire was applied to capture all relevant data related to sociodemographic characteristics, attitude toward hand hygiene, knowledge, as well as practice of hand hygiene. A checklist related to handwashing practice was incorporated into the questionnaire with three different responses.6 We put an assumed number “3” for every appropriate answer, “2” for the less appropriate, and finally “1” for no/wrong practice according to responses during analysis and then summed up to make the handwashing practice “score”.

Data analysis

Descriptive statistics was used to summarize the data. The characteristics of the study participants were expressed in terms of mean, standard deviation (SD), percentage, and frequencies with 95% CI. Multiple linear regression analysis was done to examine the effect of handwashing practice score on sex, age, marital status, educational status, parents’ educational status, household size, and present living conditions among the study participants. The regression model is as follows for each variable:

y=β0+β1x1+β2x2+β3x3+β4x4+β5x5+β6x6+β7x7+ (2)

where y is a dependent variable (total handwashing practice score), x1 the respondents’ age group (0= ≤19 years, 1=19–20 years, and 3=23 years or older), x2 the sex of respondents (0= male and 1= female), x3 the marital status of respondents (0= married and 1= unmarried), x4 the respondents’ education level (0= first year, 1= second year, 2= third year, and 3= fourth year), x5 the education level of respondents’ mother (1= up to primary, 2= secondary, 3= higher secondary, and 0= higher), x6 the household size (0= less than four members, 1= four to five members, and 2= more than five members), x7 the living condition (0= with family member, 1= with relatives, 2= hostel or with friends, and 3= others), β0 the unknown intercept, βi the unknown regression coefficient (i=1, 2, 3, 4, 5, 6, and 7) for each independent variable that refers to the effect of xi on total handwashing practice score, and ∈ the error term. Unadjusted and adjusted regression coefficient and their corresponding 95% CI and R2 values were computed. For all tests conducted in this study, statistically significant level was accepted at P<0.05. All statistical analyses were performed using Stata 13.0.

Results

Background information of participants

A total of 200 students participated in the study (Table 1). Among the total, 68.5% of the respondents were male and 27.5% were married. The mean age (±SD) was 20.4 (±1.8) years, and the age range was between 17 and 26 years. Approximately 51% of the participants were in the second year, followed by 19% in the third year. The study revealed that most of the respondents lived with their own family (57.7%), whereas others lived in the hostel (26%) and with relatives (14%). With regard to parents’ education, most of the parents had higher secondary level education and above (Table 1).

Table 1.

Background information of participants

Variables n (%) 95% CI
Age (yrs) (mean ± SD) 20.4±1.8 (20.1, 20.6)
Age group
<19 years 30 (15.0) (10.7, 20.7)
19–20 years 94 (47.0) (40.1, 54.0)
21–22 years 51 (25.5) (19.9, 32.1)
≥23 years 25 (12.5) (8.6, 17.9)
Sex
Male 137 (68.5) (61.7, 74.6)
Female 63 (31.5) (25.4, 38.3)
Marital status
Married 55 (27.5) (21.7, 34.2)
Unmarried 145 (72.5) (65.8, 78.3)
Religion
Muslim 131 (65.5) (58.6, 71.8)
Non-Muslim 69 (34.5) (28.2, 41.4)
Educational status
First year 29 (14.5) (10.2, 20.1)
Second year 102 (51.0) (44.0, 57.9)
Third year 38 (19.0) (14.1, 25.1)
Fourth year 31 (15.5) (11.1, 21.3)
Mother’s education
Up to primary 32 (16.0) (11.5, 21.8)
Secondary 44 (22.0) (16.8, 28.3)
Higher secondary 81 (40.5) (33.9, 47.5)
Higher 43 (21.5) (16.3, 27.8)
Father’s education
Up to primary 21 (10.5) (6.9, 15.6)
Secondary 20 (10.0) (6.5, 15.0)
Higher secondary 78 (39.0) (32.4, 46.0)
Higher 81 (40.5) (33.9, 47.5)
Household size, n
<4 32 (16.0) (11.5, 21.8)
4–5 152 (76.0) (69.5, 81.5)
>5 16 (8.0) (4.9, 12.7)
Living condition
With family 115 (57.5) (50.5, 64.2)
With relatives 28 (14.0) (9.8, 19.6)
Hostel or with friends 52 (26.0) (20.3, 32.6)
Others 5 (2.5) (1.0, 5.9)
Monthly household income (BDT) (mean ± SD) 38,345±14,446.4 (36,330.6,40,359.4)

Abbreviations: BDT, Bangladeshi Taka (currency); CI, confidence interval; yrs, years; SD, standard deviation.

General attitude and knowledge toward hand hygiene

Majority of the students (43.5%) washed their hands only three to five times daily, followed by 28.5% six to ten times. Only 22.5% among the total respondents washed their hands with soap for eleven times or more daily. The main reason to skip handwashing was reported as “keep forgetting”, which was 52% and 37.5% at home and at university, respectively. Approximately 67% of the respondents said that they had separate soap for washing hand at home and 56% replied that they used instant hand sterilizer for maintaining hand hygiene. Among the total respondents, 83% of the students thought that washing hand was important to prevent disease, while 17% of the students did not think so (Table 2).

Table 2.

Attitudes to hand hygiene

Attitudes to hand hygiene n (%) 95% CI
How many times a day do you wash your hands?
Never 1 (00.5) (0.1, 3.5)
1–2 times 10 (05.0) (2.7, 9.1)
3–5 times 87 (43.5) (36.7, 50.5)
6–10 times 57 (28.5) (22.6, 35.2)
11 or more 45 (22.5) (17.2, 28.9)
Reasons for skipping handwashing at home
No need 62 (31.0) (24.9, 37.8)
No available time 13 (06.5) (3.8, 10.9)
Keep forgetting 104 (52.0) (45, 58.9)
Far from water and soap 21 (10.5) (6.9, 15.6)
Poor water supply 3 (01.5) (0.5, 4.6)
Others 1 (00.5) (0.1, 3.5)
Reasons for skipping handwashing at university
No need 60 (30.0) (24, 36.8)
No available time 13 (06.5) (3.8, 10.9)
Keep forgetting 75 (37.5) (31, 44.5)
Soap not available 46 (23.0) (17.6, 29.4)
Poor water supply 7 (03.5) (1.7, 7.2)
Inadequate facility 3 (01.5) (0.5, 4.6)
Separate soap available for handwashing at home
Yes 135 (67.8) (61, 74)
No 64 (32.2) (26, 39)
How often does your household buy soap?
Weekly 129 (64.5) (57.6, 70.9)
1–2 weeks 9 (04.5) (2.3, 8.5)
3–4 weeks 19 (09.5) (6.1, 14.5)
More than a month 10 (05.0) (2.7, 9.1)
Do not know 33 (16.5) (11.9, 22.4)
Do you use instant hand sterilizer when you are outside from home?
Yes 112 (56.0) (49, 62.8)
No 47 (23.5) (18.1, 29.9)
Do not know 41 (20.5) (15.4, 26.7)
How often you cut your nails?
Weekly 167 (83.5) (77.6, 88.1)
1–2 weeks 15 (07.5) (4.6, 12.1)
3–4 weeks 12 (06.0) (3.4, 10.3)
More than a month 6 (03.0) (1.3, 6.6)
Toilet facility
Kacha 5 (02.5) (1, 5.9)
Sanitary 162 (81.0) (74.9, 85.9)
Modern commode 27 (13.5) (9.4, 19)
Others 6 (03.0) (1.3, 6.6)
Toilet facility
Hygienic 189 (94.5) (90.3, 96.9)
Unhygienic 11 (05.5) (3.1, 9.7)
Handwashing is important to prevent diseases
Yes 166 (83.0) (77.1, 87.6)
No 34 (17.0) (12.4, 22.9)
Handwashing is a part of personal hygiene
Yes 157 (78.5) (72.2, 83.7)
No 43 (21.5) (16.3, 27.8)

Abbreviation: CI, confidence interval.

With regard to knowledge about handwashing, most of the students (69%) believed that cold water should be used for washing hand, while only 28.5% students replied appropriately that “medium hot water” should be used for washing hand. Approximately 80% of the respondents answered “watch and bracelets” need to be removed during washing hand and 38.5% of the students replied that rings need to be removed during handwashing (Table 3). Of the total students, 39.5% agreed that at least 15 seconds is required for washing hand properly, whereas 26% respondents disagreed with this question (table not shown). Approximately 30% of the respondents did not know about the time needed for washing hands.

Table 3.

Knowledge about handwashing

Knowledge about handwashing n (%) 95% CI
What type of water should be used for handwashing?
Cold water 138 (69.0) (62.2, 75.1)
Medium hot water 57 (28.5) (22.6, 35.2)
Hot water 5 (2.5) (1, 5.9)
How many times are needed for proper handwashing?
Yes 123 (61.5) (54.5, 68)
No 77 (38.5) (32, 45.5)
With what you should wash your hand?
Only water 48 (24.0) (18.5, 30.5)
Water with soap 134 (67.0) (60.1, 73.2)
Water with ash 16 (8.0) (4.9, 12.7)
Water with mud 2 (1.0) (0.2, 4)
Others
Watch and bracelet should be removed during handwashing?
Yes 162 (81.0) (74.9, 85.9)
No 38 (19.0) (14.1, 25.1)
Rings should be removed during handwashing?
Yes 137 (68.5) (61.7, 74.6)
No 53 (26.5) (20.8, 33.1)
Do not know 10 (5.0) (2.7, 9.1)
Wrist should be washed during handwashing?
Yes 145 (72.5) (65.8, 78.3)
No 18 (9.0) (5.7, 13.9)
Do not know 37 (18.5) (13.7, 24.5)
Hands need to be dried after washing
Yes 160 (80.0) (73.8, 85.0)
No 29 (14.5) (10.2, 20.1)
Do not know 11 (5.5) (3.1, 9.7)

Abbreviation: CI, confidence interval.

Hand hygiene practice and its association considering different factors

Table 4 shows the participants’ response of a “handwashing practice checklist” in percentages for every response. The bold numbers indicate the appropriate answer for each type of practice. The mean (±SD) score of the participant’s hand hygiene practice was 50.81 (±4.79) (Table 5). Association of handwashing practice with sociodemographic characteristics using “t-test” showed statistically significant difference in scores (P<0.05) among marital status where the practice score was higher among the unmarried (51.37) and married (49.34). The result also showed a small variation in the practice score among male (50.64) and female (51.17) students, but statistically, it was not a significant difference (P>0.05) (Table 5). Handwashing practice with some sociodemographic characteristics using “one-way analysis of variance test” showed that the mean score varies with department, which is statistically significant (P<0.05). The result also showed that a small variation in the practice score related with living conditions, and the difference is statistically significant (P<0.05). The practice level of hand hygiene was higher among those who lived with family (51.6) compared to others and the lowest among those who lived alone (45.00).

Table 4.

Practice toward handwashing

Handwashing practice Always, n (%) Sometimes, n (%) Never, n (%)
Before meals 197 (98.5) 03 (01.5)
After meals 183 (91.5) 17 (08.5)
After coming from toilet 176 (88.0) 22 (11.0) 02 (01.0)
With water and soap 177 (88.5) 22 (11.0) 01 (00.5)
When come home 167 (83.5) 31 (15.5) 02 (01.0)
After handshaking 143 (71.5) 50 (25.0) 07 (03.5)
Before going to bed 131 (65.5) 63 (31.5) 06 (03.0)
After using public transportation 154 (77.0) 43 (21.5) 03 (01.5)
After waking up in the morning 117 (58.5) 74 (37.0) 09 (04.5)
After touching animals 138 (69.0) 57 (28.5) 05 (02.5)
Only if they are soiled 126 (63.0) 63 (31.5) 11 (05.5)
Before preparing meals 148 (74.0) 42 (21.0) 10 (05.0)
After money exchange 137 (68.5) 54 (27.0) 09 (04.5)
After blowing the nose 145 (72.5) 52 (26.0) 03 (01.5)
After touching garbage 131 (65.5) 63 (31.5) 06 (03.0)
Before touching sick people 128 (64.0) 66 (33.0) 06 (03.0)
After touching sick people 137 (68.5) 58 (29.0) 05 (02.5)
After combing my hair 111 (55.5) 72 (36.0) 17 (08.5)
After cleaning my home 134 (67.0) 38 (19.0) 28 (14.0)
After washing dishes 098 (49.0) 38 (19.0) 64 (32.0)
After doing laundry 071 (35.5) 33 (16.5) 96 (48.0)

Notes: Bold values indicate correct answer. ‘–’ indicates the number of responses is zero in terms of “never practiced” in response to the question.

Table 5.

Participants’ handwashing practice score based on some sociodemographic features

Name of the variable n Mean % SD SE 95% CI P-value
Practice score 200 50.81 80.6 4.79 0.33 50.1–51.4 0.000
Sex
Male 137 50.64 80.3 4.85 0.41 49.8–51.4 0.470
Female 63 51.17 81.2 4.65 0.58 50.1–52.3
Marital status
Married 55 49.34 78.3 4.88 0.65 50.0–53.0 0.007
Unmarried 145 51.37 81.3 4.6 0.38 50.1–51.4

Note: P-value was derived from independent t-test.

Abbreviations: SD, standard deviation; SE, standard error; CI, confidence interval.

Factors associated with hand hygiene practice

Table 6 shows the results of multiple regression analysis that analyzes the effect of handwashing practice score by demographic and socioeconomic characteristics. The regression model explains 43.1% of total variations (R2=0.431). The Breusch-Pagan/Cook-Weisberg test showed that heteroscedasticity was not present in the model. Variance inflation factor test with its mean (max) value of 2.4 (4.70) indicates that there is no evidence of multicollinearity problem in the regression model.17 Ramsey regression equation specification error test (RESET) showed that there was sufficient evidence against the hypothesis of omitted variable bias in the model. Regression coefficient demonstrated that age has a negative influence on hand hygiene practice as older students had lower scores compared to the younger ones (P<0.01). On the contrary, marital status showed that the unmarried students were influencing the incensement of handwashing practice more than the married students (P<0.01). The level of higher grade education of participants had also played a significant impact on handwashing practices compared to that of lower grade education.

Table 6.

Effect of hand hygiene practice score on different factors

Variables Practice score (mean ± SD) Model 1 Model 2

Unadjusted coefficient (95% CI) Adjusted coefficient (95% CI) VIF
Constant 53.8*** (50.9, 56.6)
Age group
<19 years (ref) 54.9±3.6
19–20 years 53.2±5.06 −1.71 (−3.7, 0.24) −1.4 (−3.23, 0.42) 2.9
21–22 years 51.5±4.61 −3.5*** (−5.6, −1.31) −2.3** (−4.7, −0.1) 3.5
≥23 years 51.4±4.8 −3.5*** (−5.9, −0.9) −4.2*** (−7.7, −0.6) 4.7
Sex
Male (ref) 52.6±4.9
Female 53.1±4.7 0.5** (−0.9, 2.0) 0.1 (−1.2, 1.5) 1.4
Marital status
Married (ref) 51.3±5.0
Unmarried 53.4±4.7 2.1*** (0.6, 3.6) 1.9*** (0.5, 3.3) 1.3
Educational status
First year (ref) 51.6±5.2
Second year 53.4±4.9 1.8** (−0.2, 3.9) 1.7 (−0.2, 3.7) 3.3
Third year 52.7±4.6 1.1 (−1.2, 3.4) 3.1*** (0.8, 5.5) 2.9
Fourth year 52.0±4.6 0.41 (−2.0, 2.9) 3.4** (−0.0, 6.7) 4.2
Mother’s education
Up to primary 48.3±3.7 −7.1*** (−9.0, −5.3) −6.1*** (−8.7, −3.4) 3.2
Secondary 50.3±4.6 −5.1*** (−6.8, −3.4) −5.2*** (−7.5, −2.9) 3.2
Higher secondary 54.5±3.8 −1 (−2.5, 0.5) −1.9** (−3.5, −0.2) 2.4
Higher 55.5±4.1
Father’s education
Up to primary 48.4±4.0 −5.7*** (−7.8, −3.5) −1.69 (−4.1, 0.7) 1.9
Secondary 50.3±4.1 −3.8*** (−6.0, −1.6) −0.02 (−2.3, 2.3) 1.7
Higher secondary 53.2±4.0 −0.87 (−2.3, 0.5) 0.83 (−0.8, 2.5) 2.3
Higher (ref) 54.1±4.2
Household size, n
<4 (ref) 51.3±4.5
4–5 53.1±5.0 1.80** (−0.0, 3.7) 0.64 (−1.0, 2.2) 1.6
>5 53.3±3.9 2.06 (−0.8, 5.0) 2.78 (0.3, 5.3) 1.6
Living condition
With family (ref) 53.6±4.4
With relatives 51.1±5.6 −2.4** (−4.4, −0.4) −1.1 (−2.8, 0.63) 1.2
Hostel or with friends 52.1±5.1 −1.45** (−3.0, 0.1) −0.7 (−2, 0.7) 1.2
Others 51.0±4.7 −2.6 (−6.9, 1.8) −0.5 (−4.2, 3.2) 1.2
R2 0.431
F-Statistics 6.78***
Mean (VIF) 2.4
Ramsey RESET 3.72***
Breusch-Pagan/Cook-Weisberg test χ2(1) =2.41

Notes:

***

1% level of significance.

**

5% level of significance.

Abbreviations: SD, standard deviation; CI, confidence interval; VIF, variance inflation factor; ref, reference; RESET, regression equation specification error test.

Conversely, the lower grade of mother education level was negatively associated with the handwashing practice than the higher level of education (Table 6). On the contrary, the sex of the participating students, father’s education level, as well as the current living conditions were not significant predictors of handwashing practice.

Discussion

The present study attempted to assess hand hygiene knowledge and practice among private university students of Bangladesh. It also determined the associations with some sociodemographic features and provided several significant findings. The results of the study indicate that most of the respondents maintained hand hygiene but not sufficiently enough to prevent infection. In this study, most of the participants washed their hands three to five times a day, which is an insufficient number for proper hand hygiene. In contrast, majority of the respondents had separate soap for hand wash in their homes; it is also promising that the majority use instant hand sterilizer when they are outside of home or if water or soap is not available. Our study also indicated that the main reasons for skipping handwashing at home, and in the university setting were participants’ beliefs on “keep forgetting”, “no need”, and poor water supply. Another study encompassing health workers inquired about the reasons for not washing their hands and they pointed out similar attitudes such as “not think about it at the moment”, “forgetting”, and “being busy”.18 Other relevant studies on handwashing showed that “skin drying effect of hand hygiene products, soap or paper towels unavailability”, “lack of time”, “lack of knowledge”, “not thought and forgotten”, and “lack of role models in school or among adults” were the main obstacles in promoting handwashing as the habit of proper hand hygiene.18,19

Regression analysis showed no significant variation in the hand hygiene practice among sexes, but it showed significant difference in the marital status, where the hand hygiene practice score was more among the unmarried students. A previous study on the topic did not show any difference between males and females, which is similar to a study done in Africa. However, the study from Africa did not show any difference in the frequency of handwashing between sexes.20 Participants’ faculty was also associated with the scores in the current study. Our study also showed that handwashing practice is associated with the living condition of the participants and is significantly higher among those who live with their family. This study found that the level of education had a significant impact on handwashing practices and that higher grade students practice handwashing frequently than the lower grade students, indicating that the university-based hygiene education is also vital in order to decrease the rates of transmissible diseases.21

Limitations

There are several limitations to this study. As the survey was restricted to the undergraduate students of the selected private university in urban Dhaka, it does not reflect Bangladeshi population as a whole and also does not represent all university students of the country. The participants were quite homogenous as a group, and so it was impossible to compare knowledge about and attitudes toward hand hygiene with regard to the sociodemographic context. Future nationwide research is needed to address these issues.

Conclusion

The findings of this study may indicate widespread insufficient hand hygiene in the university-going population. Moreover, low scores related to participants’ handwashing knowledge and practice may indicate a need for an extensive public health education program on the topic. The hand hygiene awareness and compliance among the university students were found to be relatively low. The study shows the need for further improvement in the existing hand hygiene behavioral change communication programs to address the gaps in knowledge, attitudes, and practices. Furthermore, multifaceted and dedicated efforts must be undertaken to rectify this attitude and behavior from early on. Therefore, supporting quantity and/or quality of the available campus-based public health education programs and development of hand hygiene promotion programs for the general public based on the findings of this study are recommended.

Acknowledgments

We gratefully acknowledge Government of the People’s Republic of Bangladesh; the Department of Foreign Affairs, Trade and Development, Canada; Swedish International Development Cooperation Agency (Sida); and the Department for International Development (UK Aid) for their unrestricted support and commitment to the International Centre for Diarrhoeal Disease Research, Bangladesh’s research efforts. The authors would also like to thank all the participating students.

Footnotes

Disclosure

The authors report no conflicts of interest in this work.

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