a 
  

© 2021 Indonesian Society for Science Educator 220 J.Sci.Learn.2021.4(3).220-229 

 

Received:  27 December 2020 

Revised: 03 March 2021 

Published: 03 July 2021 

 

 

Secondary School Students' Knowledge and Views on Laboratory Safety 

Belkız Caymaz1* 

1Ministry of National Education, Turkey 
 
*Corresponding Author caymazbelkiz@gmail.com 

ABSTRACT Laboratory studies are very important for science education but also involve various risks. It is possible to minimize 
these risks by providing a safe working environment. This study aims to determine the knowledge and views of secondary school 
students on laboratory safety and to identify their deficiencies in this regard. The survey method was used in the study. The study 
sample consists of 136 students from 6th, 7th, and 8th-grade students of a public secondary school in Kastamonu Province, 
Turkey. An open-ended questionnaire was used to determine the students' knowledge and views on the subject, and the data 
obtained were analyzed by the content analysis method. As a result of the study, it was seen that although secondary school 
students have some general information about laboratory safety, they have deficiencies in terms of most of the information. It 
was determined that students do not know most of the behaviors that must/must not be made in the laboratory, and they are 
not aware of some of the safety symbols in the science textbooks. In addition, most of the students stated that they don't feel 
competent about laboratory safety and need training on this subject. 

Keywords Science Lesson, Laboratory Safety, Secondary School Students 

1. INTRODUCTION 
Laboratory studies are an integral part of science 

education and provide students with various opportunities 
to learn by doing and experiencing (Hamurcu, 1998; Yazıcı 
& Özmen, 2015). Well-designed laboratory studies 
encourage students to question, think scientifically and 
interpret the events around them (Aydoğdu, 2018). It also 
contributes to developing students' psycho-motor skills 
and communication skills (Hofstein & Lunetta, 2004). 
Despite its various benefits, the teachers do not want to do 
laboratory studies for various reasons (Hackling, Goodrum 
& Rennie, 2001; Yazıcı & Özmen, 2015). Insufficient 
course time (Hackling, Goodrum & Rennie, 2001; Hodson, 
1990; Yazıcı & Özmen, 2015), crowded classes (Aydoğdu, 
2018; Uluçınar, Cansaran & Karaca, 2004), labs being 
inadequate in terms of equipment (Hofstein & Lunetta, 
2004; Nakiboğlu & Sarıkaya, 1999; Yazıcı & Özmen, 2015) 
are among the factors that hinder laboratory studies. 
Böyük, Demir & Erol (2010) found in their study that 
secondary school science teachers did not know the 
laboratory materials sufficiently, could not use them and 
did not have enough knowledge of maintenance and repair 
of these materials. Teachers feel insufficient in terms of 
knowledge and skills for laboratory use and have difficulty 
providing classroom management. For this reason, they 
prefer to teach science in the classroom, even if the physical 

conditions in the laboratory are suitable. Another reason 
teachers avoid using the laboratory is the insecurity they 
feel about laboratory safety (Nakiboğlu & Sarıkaya, 1999; 
Yazıcı & Özmen, 2015). Laboratory studies are required for 
effective science education; however, they must be planned 
very carefully due to the dangers they may contain. At this 
point, ensuring laboratory safety is the essential condition.  

Laboratory safety is the process of taking precautions 
against accidents and dangers that may occur during 
laboratory studies, determining the problems that may 
occur in the laboratory, and solving the problems with 
scientific methods (Bayraktar, Erten & Aydoğdu, 2006). In 
addition, laboratory safety can be defined as following 
specific laboratory rules to protect people and the 
environment during laboratory studies and utilize 
laboratory equipment in the most appropriate way (Deniz 
& Ercan-Kalkan, 2013). Laboratory accidents are inevitable 
when safety precautions are not observed. These accidents 
may result in simple injuries as well as very serious 
situations such as loss of life. The main causes of accidents 
include the incorrect design of laboratories, improper 
storage of materials and equipment, the absence or non-use 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i3.30752 221  J.Sci.Learn.2021.4(3).220-229 
 

of protective equipment for safety. In addition, crowded 
classes, unwanted student behaviors, carelessness, 
tiredness, teachers and students not having enough 
information about the properties of chemicals are among 
the other reasons (Aydoğdu & Yardımcı, 2013; Aydoğdu & 
Pekbay, 2016; Nwele, 2013; West, Westerlund, Stephenson, 
Nelson & Nyland, 2003). There have been many accidents 
due to these reasons. For example, methanol caught fire 
during the experiment, and one student had severe burns 
(Gerlovich, Parsa & Jordan, 2004). A student who did not 
listen to the teacher's warnings added water over the acid 
in another accident. As a result of the laboratory explosion, 
both the careless student and his partner were injured (Hill 
& Finster, 2010). These accidents show that unconscious 
and careless work can lead to many dangerous situations. 

Both teachers and students have significant 
responsibilities to carry out laboratory studies safely. 
According to America's Lab Report (Singer, Hilton & 
Schweingruber, 2006), teachers' responsibilities are: (1) the 
duty of teaching (the teacher must predetermine possible risks, 
inform the students in advance of possible dangers, teach 
the laboratory rules), (2) the duty of supervision (the teacher 
must constantly watch the students, not ignore those who 
exhibit wrong behavior, increase supervision in more 
dangerous studies), (3) the duty of maintenance (the teacher 
must never use a damaged material, prepare a written 
report for the maintenance and repair of the materials, act 
following the procedures for regular checks of the safety 
equipment). Eliminating the conditions that can cause 
injuries and accidents in the laboratory is one of the 
teacher's primary duties. However, students who will work 
in the laboratory should not forget that they are responsible 
for their safety and their people. Students should get 
information about the possible risks of the experiment in 
advance, follow and apply the safety instructions, listen to 
the warnings of the teacher carefully, learn what to do in 
case of an emergency, and inform the teacher about 
possible dangerous situations (Hasenekoğlu, 2003; 
Topsakal, 2006).  

Most accidents are caused by human errors (Canel, 
2002; Kerimak-Öner, 2020). For this reason, both teachers 
and students should have the necessary knowledge and 
skills to ensure laboratory safety. The most important thing 
to do is to identify the deficiencies of teachers and students 
in laboratory safety and provide the training they need. 
Aydoğdu & Yardimci (2013) analyzed the news about 
laboratory accidents in local and national newspapers. As a 
result of the examination, it was determined that there were 
accidents such as test tube explosion, chemical spreading, 
gas release, etc. These accidents' leading causes include 
having inadequate/incorrect information about chemicals, 
carelessness, and unauthorized use of experimental 
materials by students. When the studies on laboratory 
safety were examined in the literature, it was seen that most 
of the studies were carried out with teachers and teacher 

candidates. In Demir's (2016) study, the "Laboratory Safety 
Knowledge Test" was applied to 74 science teachers, and it 
was observed that very few of them were successful in the 
test. Muhammad (2017) conducted a study that measured 
laboratory-related skills of science teachers in Nigeria, such 
as laboratory safety, using materials, experimenting, first aid. As a 
result of the study, it was reported that teachers have 
deficiencies in laboratory safety. Gudyanga (2020) 
researched the levels of chemical laboratory safety (CLS) 
awareness of physical sciences teachers. Teacher CLS 
awareness was generally suboptimal, especially concerning 
awareness of safe chemical storage and waste disposal and 
emergency laboratory safety procedures. The teacher 
candidates’ knowledge and views on laboratory safety were 
investigated (Aydın, Diken, Yel & Yılmaz, 2011; Kırbaşlar, 
Özsoy-Güneş & Derelioğlu, 2010). It was reported that 
teacher candidates have general knowledge about 
laboratory safety, but they had deficiencies and did not 
sufficiently know the laboratory safety symbols. In the 
studies conducted by Anılan (2010), Gökmen & Atmaca 
(2019), it was determined that the teacher candidates' level 
of awareness about safety symbols was low. The state of 
the secondary schools having laboratory safety equipment 
(Emendu, 2007; Nwele, 2013) was also investigated. The 
results showed that the laboratory conditions were not 
suitable for safety and the safety equipment was 
insufficient. Gerlovich, Parsa & Jordan (2004) found that 
most teachers were not sufficiently aware of their legal and 
professional responsibilities regarding laboratory safety, 
and they prepared a safety education program. 

The number of studies conducted with students on 
laboratory safety is very limited. In the study conducted by 
Yılmaz (2005), a test including laboratory safety and the 
dangers of chemical substances was applied to high school 
students.  It was observed that the students had the basic 
knowledge required for laboratory studies, but their safety 
knowledge on chemical substances was insufficient. 
Alaimo, Langenhan, Tanner & Ferrenberg (2010) prepared 
a training program on laboratory safety. Stating that the 
students were bored of reading the papers on which the 
safety rules were written, they trained them for a year in 
remarkable ways such as safety games, puzzles, cartoons, 
and videos. Ali et al. (2018) selected eight secondary 
schools to determine students' awareness of laboratory 
safety in Pahang, Malaysia. A Likert-type questionnaire 
with five components (work procedure, safety equipment, 
handling experiments, chemical waste management, 
emergency response plan) was applied to the students from 
schools located in urban and rural areas. This study 
indicates that the overall level of students' awareness on 
laboratory safety is at medium-high level, and this has 
shown that the existing measures in secondary school to 
enhance awareness of laboratory safety are adequate. It 
might help minimize the accidents that may occur if the 
students act consciously during the laboratory studies, obey 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i3.30752 222  J.Sci.Learn.2021.4(3).220-229 
 

the safety rules, and realize possible safety problems. When 
the studies were examined, there was no study investigating 
secondary school students' knowledge and views on 
laboratory safety. Due to the scarcity of studies on 
laboratory safety, it is aimed that this study will contribute 
to the field. 

This study aims to determine the knowledge and views 
of secondary school students on laboratory safety and to 
identify their deficiencies in this regard. For this purpose, 
answers to the following questions were sought: (1) What 
is the knowledge of secondary school students about 
laboratory safety?. (2) What are the views of secondary 
school students on laboratory safety?. 

 
2. METHOD  

This research was carried out using the survey method, 
which is one of the quantitative research methods. The 
survey method aims to describe an existing situation as it 
is, and the individual or object is tried to be defined as it is 
in its conditions (Karasar, 2004). 

2.1 Sampling 
The research was conducted with 6th, 7th, and 8th-

grade students of a public secondary school in the fall 
semester of the 2019-2020 academic year in Kastamonu 
Province, Turkey. A total of 136 students, including 39 
students from the 6th Grade, 54 students from the 7th 
Grade, and 43 students from the 8th Grade, voluntarily 
participated in the study. The criterion sampling method 
was used in determining the sample. It is the sampling 
method in which people, events, objects, or situations with 
predetermined qualities are selected (Yıldırım & Şimşek, 
2006). The school has two science teachers and a 
laboratory. Before the research, science teachers were 
interviewed, and information was obtained about their 
laboratory use. The most important criterion in choosing 
the school was that science teachers use the laboratory 
actively and alternately. 

2.2 Data Collection Tool 
The researcher developed an open-ended questionnaire 

to determine the students' knowledge and views on 
laboratory safety. First, a draft form consisting of eight 
questions was created. Similar studies in the literature were 
examined (Aydın, Diken, Yel & Yılmaz, 2011; 2011; Demir, 
2016; Kırbaşlar, Özsoy-Güneş & Derelioğlu, 2010), and 
these studies were used to form some questions. For 
example, Aydın, Diken, Yel & Yılmaz (2011) asked the 
teacher candidates to write down the safety errors they saw 
in the picture. In this study, students were shown a picture 
and asked to write down the right and wrong behaviors 
they saw. The picture used by Aydın, Diken, Yel & Yılmaz, 
2011 (2011) and the picture used in this study were 
different. The draft form was submitted for expert opinion 
(two faculty members, three science teachers, and two 
Turkish teachers) to be examined in terms of language and 
content. Necessary corrections were made in line with 

expert opinions, and two questions were removed from the 
questionnaire. Then, five students selected from a different 
school were interviewed to check the questionnaire's 
comprehensibility. In line with the interviews, the students' 
expressions were not understood or perceived differently, 
and the questionnaire consisting of six questions was 
finalized. 

The questionnaire consists of two parts (Appendix). In 
the first part, there are two questions for determining the 
students' knowledge: (1) The picture of students working 
in the laboratory was given. The correct and wrong 
behaviors of the students were asked. (2) 11 safety symbols 
were given, and they were asked what they mean. These are 
common symbols found in 6th, 7th, and 8th-grade science 
textbooks. In the second part, there are four questions for 
determining the views of the students. The students were 
asked: (1) do they have enough information about 
laboratory safety?, (2) what should be considered in terms 
of safety during laboratory studies, (3) what kind of 
problems may arise when safety precautions are not taken 
into consideration in laboratory studies. (4) what are their 
expectations from science teachers and school 
administrators regarding laboratory safety? The first and 
second parts of the questionnaire were applied on different 
days. One lesson hour (40 minutes) was given to students 
for both parts. There was a possibility that taking a long 
time to answer the questionnaire could cause students to 
get bored and carelessly answer the last questions. This 
possibility has been taken into consideration, and possible 
data loss has been tried to be prevented. 

2.3 Analysis of the Data 
Descriptive statistics such as frequency and percentage 

were used to analyze the first part and the first question in 
the second part of the questionnaire. Content analysis was 
used to analyze the 2nd, 3rd, and 4th questions in the 
second part. There are two types of approaches in content 
analysis, namely "inductive" and "deductive." If there is not 
enough information about the subject under study, then 
the inductive approach will go from specific to general 
(Hsieh & Shannon, 2005). In this context, the inductive 
content analysis approach was used in this study. In content 
analysis, data are analyzed in four stages; (1) coding, (2) 
finding themes, (3) organizing codes and themes, (4) 
defining and interpreting the findings (Çepni, 2012). The 
data obtained were first coded, and themes were created. 
Then, themes and codes were tabulated, and the frequency 
and percentage value of each code were calculated. 

The questionnaires collected in the study were given to 
a science educator working at the state university's 
education faculty. The science educator randomly and 
equally selected and analyzed questionnaires from each 
grade level (25%). The codings made independently by the 
researcher and the science educator were compared. The 
reliability percentage was calculated with the formula 
suggested by Miles & Huberman (1994). As a result of the 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i3.30752 223  J.Sci.Learn.2021.4(3).220-229 
 

calculation, a value of .80 and above indicates that the 
evaluation is reliable (Miles & Huberman, 1994; Miles, 
Huberman & Saldana, 2014). In this study, the agreement 
percentage between coders was found to be .94. This result 
shows that the evaluation made is reliable. Non-compliance 
points were reviewed together, and a common decision was 
reached. 

 
3. RESULT AND DISCUSSION  

 

In this section, the data obtained from the questionnaire 
were arranged and interpreted according to each sub-
problem. The data were analyzed both in general (all 
students) and separately for each grade level. 

3.1 Secondary School Students' Knowledge About 
Laboratory Safety 

In the first part of the questionnaire, two questions were 
asked to the students. In the first question, the students 
were asked what the right and wrong behaviors were in the 
picture's laboratory environment. The frequency and 
percentage values of the obtained findings are given in 
Table 1. 

When Table 1 is examined, it is seen that the most 
determined right behaviors in the picture are "regularity of 
the materials on the shelf (46.3%), a student wearing lab 

glasses (38.2%) and a student wearing a lab coat (30.1%)". 
The most determined wrong behaviors are "some students 
eating and drinking somethings (88.9%), disorganized 
laboratory (79.4%), spilling the liquid in the broken glass 
beaker to the floor (56.6%)". All right and wrong behaviors 
in the picture have been identified. However, the number 
of students varies according to the grade level. "The 
regularity of the materials on the shelf" is the most 
emphasized right behavior at each grade level (48.7%-
57.4%-30.2%). "A student wearing lab glasses and wearing 
a lab coat" is the right behavior mainly detected by 7th 
graders (72.2%-44.4%). While the "the material cabine has 
fixed to the wall", which is very important in terms of 
laboratory safety, was determined as the right behavior by 
only two 6th grade students, it is noteworthy that no 
students detected this the 7th and 8th grades. Students 
identified 19 wrong behaviors in the picture. "Some 
students eating or drinking somethings" (97.4%-90.7%-
79%) and " disorganized laboratory" (84.6%-81.4%-72%) 
are the most defined wrong behaviors at every grade level. 
Besides, "spilling the liquid in the broken glass beaker to 
the floor" (43.5%-68.5%-53.4%) and "the microscope not 
unplugged" (43.5%-38.8%-58.1%) was reported as wrong 
behaviors by most students. Very few students mentioned 
wrong behaviors such as not using protective equipment 

Table 1 The right and wrong behaviors seen in the laboratory environment  

Themes Codes 6th Grade 7th Grade 8th Grade Total 

f % f % f % f % 

Right 
Behaviors 

Some chairs are in place 4 10.2 8 14.8 12 27.9 24 17.6 

Regularity of the materials on the shelf 19 48.7 31 57.4 13 30.2 63 46.3 

The material cabine has fixed to the wall 2 5.1 - - - - 2 1.4 

A student sitting in place 4 10.2 - - 5 11.6 9 6.6 

A student wearing lab glasses 3 7.6 39 72.2 10 23.2 52 38.2 

A student wearing a lab coat 4 10.2 24 44.4 13 30.2 41 30.1 

There is no right behavior 15 38.4 8 14.8 11 25.5 34 25 

Wrong 
Behaviors 

Some students eating or drinking somethings 38 97.4 49 90.7 34 79 121 88.9 

Spilling the liquid in the broken glass beaker to the floor 17 43.5 37 68.5 23 53.4 77 56.6 

Disorganized laboratory (bag and chair thrown on the 
floor) 

33 84.6 44 81.4 31 72 108 79.4 

The microscope not unplugged 17 43.5 21 38.8 25 58.1 63 46.3 

A student holding the test tube facing himself 5 12.8 4 7.4 5 11.6 14 10.2 

Putting food on the experimental table 4 10.2 3 5.5 10 23.2 17 12.5 

Two students playing games in the lab 6 15.3 1 1.8 1 2.3 8 5.8 

Most students are not wearing lab glasses 2 5.1 8 14.8 - - 10 7.3 

Lab coat not worn - - 3 5.5 1 2.3 4 2.9 

Gloves not worn while doing the experiment 2 5.1 8 14.8 10 23.2 20 14.7 

The lab is not clean 4 10.2 5 9.2 9 20.9 18 13.2 

A student sniffs the gas he doesn't know 6 15.3 1 1.8 2 4.6 9 6.6 

Most students walking around 6 15.3 2 3.7 3 6.9 11 8.1 

Students touching materials they do not know 2 5.1 7 12.9 12 27.9 21 15.4 

Damaging to materials/stuffs in the laboratory 1 2.5 4 7.4 3 6.9 8 5.8 

Safety precautions not taken 3 7.6 2 3.7 8 18.6 13 9.5 

The materials used has not removed in place 1 2.5 1 1.8 2 4.6 4 2.9 

Glass beaker on the table is about to fall to the floor 4 10.2 - - 4 9.3 8 5.8 

Students experimenting on their own without teacher 
supervision 

4 10.2 11 20.3 9 20.9 24 17.6 

 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i3.30752 224  J.Sci.Learn.2021.4(3).220-229 
 

(lab glasses, lab coat, gloves) and making experiments 
dangerously without teacher supervision.  

Most of the students do not know precisely what is right 
and what is wrong during laboratory studies. This may be 
due to the teacher's attitude during laboratory studies. The 
teacher's warnings, the rules he/she cares about, the 
behaviors he/she pays attention to affect and shape the 
students' behavior. For example, if the teacher warns the 
students about the subject more often, their attention may 
be directed to that behavior. Similarly, if the teacher does 
not use protective equipment such as gloves or lab glasses 
in laboratory studies, it may cause students to perceive this 
behavior as a normal situation and not see it as a deficiency. 
Aydın, Diken, Yel & Yılmaz, 2011 (2011) asked prospective 
science and biology teachers to explain the safety errors 
they saw in the picture. Some errors were detected by most 
prospective teachers, while some errors were detected by a 
very small number of prospective teachers. In other studies 
in the literature, it was concluded that science teachers 
(Demir, 2016; Muhammad, 2017) and prospective teachers 
(Kırbaşlar, Özsoy-Güneş & Derelioğlu, 2010) had 
insufficient knowledge about laboratory safety. Although 
the sample groups of these studies and the present study 
are different, their findings are similar. 

In the second question, the meanings of some 
laboratory safety symbols were asked. The frequency and 
percentage values of the students who gave the right 
answer are given in Table 2. 

In Table 2, it is seen that the eye safety (92.6%) symbol 
is the most known, while the symbols of plant safety 
(22.7%) and animal safety (22.1%) are the least known. It 
is also seen that most students know some safety symbols 
(eye safety, sharp and pointed objects, hand safety, 
chemical substance warning, hand cleaning warning, lab 
coat warning) at all grade levels. While most of the 7th and 
8th graders were known while the heat safety symbol was 
known, the rate of correct answers was found to be low in 
6th graders. While nearly half of the 7th graders (51.8%) 
explained the plant safety symbol correctly, only one 
student (2.5%) from the 6th Grade and two students from 

the 8th Grade (4.6%) explained it correctly. Similarly, half 
of the 7th graders (53.7%) answered the animal safety 
symbol correctly, only one of the 8th graders (2.3%) gave 
the correct answer. It is noteworthy that no student from 
the 6th Grade gave the right answer about the animal safety 
symbol. The most known and least known symbols differ 
by grade level. In the 6th Grade, the symbol of "hand 
safety" is the most known. The symbol of "animal safety" 
is unknown. In the 7th Grade, the symbol of "eye safety" 
is the most known, and the symbol of "plant safety" is the 
least known. In the 8th Grade, the symbol of "eye safety" 
is the most known, and the symbol of "animal safety" is the 
least known.  

When the explanations of the students were examined, 
it was seen that the students made explanations according 
to the picture in the symbol. For example, the animal safety 
symbol has a mouse image representing the live animal. 
Most students thought this symbol was only about the 
mouse because of the picture and explained this direction. 
Similarly, the presence of a picture of glasses in the eye 
safety symbol may have facilitated the symbol's 
recognition. The study's findings show that the pictures on 
the symbols facilitate the recognition of the symbol but do 
not provide enough information for students. Similar 
findings have been reached in studies conducted on 
different samples in the literature. Aydın, Diken, Yel & 
Yılmaz, 2011 (2011) found that some safety symbols were 
known by most prospective teachers, while a small number 
knew some of them. In other studies, it was reported that 
prospective science teachers (Anılan, 2010), prospective 
classroom teachers (Gökmen & Atmaca, 2019) and 
prospective biology teachers (Derman & Çakmak, 2016) 
did not know the safety symbols. Artdej (2012) investigated 
Thai undergraduate students' scientific understanding of 
safety symbols. The findings indicated that most of the 
students experienced confusion in the meaning of chemical 
safety symbols ,and they did not pay attention to safety 
symbols labeled on containers during experiments. Tepe 
and Tekbıyık (2019) evaluated secondary school science 
textbooks in terms of experiment and activity safety. It has 

Table 2 Students' knowledge of safety symbols 

Themes Codes 6th Grade 7th Grade 8th Grade Total 

f % f % f % f % 

Safety 
Symbols 

Eye Safety 32 82 53 98.1 41 95.3 126 92.6 

Sharp and Pointed Objects 27 69.2 52 96.2 33 76.7 112 82.3 

Hand Safety 35 89.7 47 87 40 93 122 89.7 

Heat Safety 10 25.6 38 70.3 36 83.7 84 61.7 

Electrical Safety 16 41 32 59.2 25 58.1 73 53.6 

Chemical Substance Warning 27 69.2 47 87 37 86 111 81.6 

Plant Safety 1 2.5 28 51.8 2 4.6 31 22.7 

Animal Safety - - 29 53.7 1 2.3 30 22.1 

Glass Equipment Warning 5 12.8 29 53.7 14 32.5 48 35.2 

Hand Cleaning Warning 31 79.4 36 66.6 29 67.4 96 70.5 

Lab Coat Warning 27 69.2 45 83.3 36 83.7 108 79.4 

 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i3.30752 225  J.Sci.Learn.2021.4(3).220-229 
 

been determined that the science textbooks mainly include 
activities requiring low-level security measures and few 
activities that require medium and high-level security 
measures. In addition, it was observed that safety symbols 
were used enough to take necessary precautions in the 
activities. It is necessary but not sufficient to include safety 
symbols in the science textbooks. To reduce the risk of 
accidents, students must recognize the safety symbols and 
act accordingly in laboratory studies. In this study, although 
the students were asked about the safety symbols in science 
textbooks, it was seen that the meaning of each symbol was 
not known enough. 

3.2 Secondary School Students' Views on Laboratory 
Safety 

In the second part of the questionnaire, four questions 
were asked to the students. First of all, the students were 

asked if they had enough information about laboratory 
safety. The frequency and percentage values of the answers 
are given in Table 3 

According to Table 3, 34.5% of the students think that 
they have sufficient knowledge about laboratory safety, 
while 65.5% think that they do not have sufficient 
knowledge. While 33.3% of 6th graders, 37.1% of 7th 
graders, and 32.5% of 8th graders think that they have 
sufficient knowledge, 66.7% of 6th graders, 62.9% of 7th 
graders, and 67.5% of 8th graders think that they do not 
have sufficient knowledge about laboratory safety. In short, 
most of the students do not think they have sufficient 
knowledge about laboratory safety.  

In the second question, their views were asked about 
what should be considered in terms of safety during 

Table 3 Students' views on having sufficient knowledge about laboratory safety 

 6th Grade 7th Grade 8th Grade Total 

f % f % f % f % 

Yes  13 33.3 20 37.1 14 32.5 47 34.5 
No  26 66.7 34 62.9 29 67.5 89 65.5 

 
Table 4 Student views on safe working environment 

Themes Codes 6th Grade 7th Grade 8th Grade Total 

f % f % f % f % 

Use of 
chemicals 

Storing the chemicals in a separate cabinet 1 2.5 2 3.7 - - 3 2.2 

Storing flammable and volatile substances in closed 
bottles 

- - - - 1 2.3 1 0.7 

Not touching/not smelling chemicals 10 25.6 20 37 18 41.8 48 35.2 

Not mixing different chemicals 1 2.5 4 7.4 5 11.6 10 7.3 

Not using out-of-date materials - - - - 1 2.3 1 0.7 

Not exposing chemicals that could cause explosions 3 7.6 - - 2 4.6 5 3.6 

Layout of 
the 
laboratory 
environment 

Keeping the lab clean and tidy 23 58.9 41 75.8 5 11.5 69 50.7 

Checking around before leaving the laboratory (Is the 
plug pulled out? Is the spirit extinguished? etc.) 

1 2.5 6 11.1 3 6.9 10 7.3 

Venting the lab - - - - 2 4.6 2 1.4 

Not leaving the windows open 2 5.1 3 5.5 1 2.3 6 4.4 

Unwanted 
student 
behavior 

Using laboratory materials without permission 17 43.5 19 35.1 7 16.2 43 31.6 

Running in the lab 14 35.8 6 11.1 12 27.9 32 23.5 

Joking/fighting in the lab 5 12.8 3 5.5 1 2.3 9 6.6 

Using laboratory materials carelessly/ damage to 
materials 

- - 16 29.6 - - 16 11.7 

Eating and drinking somethings 1 2.5 - - 1 2.3 2 1.4 

Pouring water on the ground - - 2 3.7 - - 2 1.4 

General 
measures 

Fixing cabinets to the wall 1 2.5 - - - - 1 0.7 

Keeping a first aid kit - - - - 1 2.3 1 0.7 

Hanging signs with safety warnings - - - - 1 2.3 1 0.7 

Staying calm in adverse situations such as fire. etc. 2 5.1 - - 3 6.9 5 3.6 

Not to panic in the event of an accident - - - - 3 6.9 3 2.2 

Working 
rules 

Listening to the teacher/paying attention to warnings 11 28.2 8 14.8 6 13.9 25 18.3 

Seeking help from the teacher with dangerous 
experiments 

- - - - 1 2.3 1 0.7 

Using protective equipment such as gloves, lab 
glasses, lab coat during the experiment 

4 10.2 17 31.4 31 72.1 52 38.2 

Doing experiment with security measures 5 12.8 5 9.2 8 18.6 18 13.2 

Not watching dangerous experiments closely 2 5.1 - - 5 11.6 7 5.1 

 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i3.30752 226  J.Sci.Learn.2021.4(3).220-229 
 

laboratory studies. The frequency and percentage values of 
student views are given in Table 4 

When Table 4 is examined, it is seen that students' views 
about a safe working environment are grouped under five 
themes. Students mainly stated that chemicals should not 
be touched/smelled (35.2%). In the theme of the laboratory 
environment's layout, it was mostly stated that the laboratory 
should be kept clean and tidy (50.7%). Most of the students 
emphasized the wrong behaviors that threaten the safe 
working environment at all grade levels. In the theme of 
unwanted student behavior, students mostly explained that 
behaviors such as "using laboratory materials without 
permission (31.6%)" and "running in the lab (23.5%)" are 
wrong. In the theme of general measures, it is noteworthy that 
7th-grade students did not give any opinion, and very few 
students from the 6th and 8th Grade made statements. In 
the theme of working rules, students mostly stated that 
behaviors such as "using protective equipment such as 
gloves, lab glasses, lab coat during the experiment 
(38.2%)", "listening to the teacher/paying attention to 
warnings (18.3%)", "doing an experiment with security 
measures (13.2%)" must be done. When the table is 
examined in general, it is noteworthy that the number of 
students explaining the behaviors that must/must not be 
done is low and that 8th graders have more views about the 
safe working environment. 

Most of the behaviors were expressed by a small 
number of students, showing that they lack knowledge on 
this subject. Most of the students do not know what 
must/must not be done during laboratory studies, and they 
have already expressed this view in the previous question. 
Okebukola et al. (2020) investigated the awareness level 
and implementation of the best practices of chemical safety 
by senior secondary school chemistry students in Nigerian. 
Students in rural schools were found to have a lower level 
of awareness of chemical safety than the students in urban 
schools. It was stated that this situation was due to a low 
level of chemistry laboratory resourcing, inadequate 
chemical safety training of the teachers, inadequacies in 
safety tools, charts, and kits, and weak enforcement of 
safety regulations. In some studies, it was observed that 
students were not given sufficient information about 
laboratory safety (Aydoğdu & Pekbay, 2016) and students 
had deficiencies about the precautions to be taken (Ateş & 

Özarslan, 2013; Yılmaz, 2005). However, specific rules 
must be followed in laboratory studies. Students must be 
informed about these rules and raise awareness. Teachers' 
lack of informing and raising students' awareness is an 
essential factor in the occurrence of problems in the 
laboratory (Aydoğdu & Pekbay, 2016). 

In the third question, it was asked what kind of 
problems may arise when safety precautions are not 
considered in laboratory studies. The frequency and 
percentage values of student views are given in Table 5. 

According to Table 5, students think that problems may 
arise in the laboratory environment or people working in 
this environment. Students mostly think that problems 
such as "injury/disability (63.9%)", "explosion (36.7%)", 
"fire (30.1%)" may occur. The 6th and 8th graders mostly 
stated that laboratory-related problems such as "explosion 
(43.5%-37.2%)", "fire (38.4%-46.5%)" may occur; 7th 
graders mostly stated that laboratory-related problems such 
as "explosion (31.4%)" and "damage to lab materials 
(14.8%)" may occur. While "injury/disability (61.5%-
64.8%-65.1%)" was mostly stated as the people-related 
problem at each grade level, "electric shock" was reported 
only by 7th graders (22.2%). Students may have made such 
inferences due to an accident they had or news they heard 
about it. This is in line with Ateş & Özarslan (2013) 
findings that students think that injury problems may occur 
mostly if safety precautions are not taken into account in 
laboratory studies. Deniz & Ercan-Kalkan (2013) explained 
that "fire, poisoning, electric shock, explosions, chemical 
spills, toxic smoke formation, etc." problems may occur if 
safety measures are not considered. Tekbıyık & Tepe 
(2017) examined the laboratory accidents that occurred 
between the years 2001-2017 and concluded that students 
caused the most accidents and that the accidents mostly 
occurred in the form of poisoning/burning/injury. 
Accidents in the laboratory are mostly caused by factors 
such as the ignorance of teachers and students, careless and 
unconscious behaviors of them, and not knowing how to 
intervene in possible accidents (Aydoğdu & Yardımcı, 
2013; Aydoğdu & Pekbay, 2016). This can cause problems 
from simple injuries to fatal accidents in laboratory studies. 
In this context, both teachers and students must take the 
necessary measures for a safe working environment. 

Table 5 Problems that may arise in laboratory studies 

Themes Codes 6th Grade 7th Grade 8th Grade Total 

f % f % f % f % 

Laboratory 
Related 

Fire 15 38.4 6 11.1 20 46.5 41 30.1 

Explosion 17 43.5 17 31.4 16 37.2 50 36.7 

Cabinets may fall over 3 7.6 1 1.8 - - 4 2.9 

Lab materials may be damaged 5 12.8 8 14.8 9 20.9 22 16.1 

People 
Related 

Injury/disability 24 61.5 35 64.8 28 65.1 87 63.9 

Fatal accident  6 15.3 6 11.1 9 20.9 21 15.4 

Poisoning 6 15.3 5 9.2 8 18.6 19 13.9 

Electric shock - - 12 22.2 - - 12 8.8 

 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i3.30752 227  J.Sci.Learn.2021.4(3).220-229 
 

In the fourth question, the students were asked about 
their expectations from science teacher and school 
administrators regarding laboratory safety. The frequency 
and percentage values of student opinions are given in 
Table 6 

According to Table 6, students expect science teachers 
and school administrators to take some laboratory safety 
precautions. At all grade levels, the science teacher is mainly 
expected to inform students about safety precautions 
(17.9%-18.5%-44.1%) and introduce the materials used in 
the experiment (23%-12.9%-18.6%). In addition, students 
expect most from the school administration to provide 
training on laboratory safety. It is also noteworthy that 
many students made irrelevant explanations and stated that 
they had no expectations from the science teacher (25.6%-
42.5%-23.2%) or school administrators (30.7%-29.6%-
11.6%). Although other safety measures that are expected 
to be taken by the science teacher or the school 
administrators are also crucial, they were mentioned by 
very few students. These findings are in line with Ateş & 
Özarslan (2013) findings that the students stated that they 
must be educated about laboratory safety and that various 
techniques (such as presentation, film, animation) must be 
used in this training. The laboratories must always be kept 
ready for a safe education environment, and students must 
be reminded of safety rules frequently. Stepenuck (2002) 

prepared a report describing the dangers of chemical 
materials and explained that the safety information 
specified in the report must be taught to students. 
Mogopodi, Paphane, & Petros (2015) researched the 
chemical management practices and safety in junior 
secondary school laboratories in Gaborone. It was seen 
that there is a lack of knowledge and awareness on sound 
chemical management, and there are no measures in place 
for disposal of out-of-date stock or expired chemicals. In 
addition, chemical containers were either not labeled or had 
fading labels, and incompatible chemicals were stored 
together, increasing the risks of chemical accidents. 
Ezrailson (2013) stated that science teachers and school 
administrators have responsibilities such as checking 
whether there is safety equipment in the laboratory and 
taking necessary precautions. Some studies determined that 
safety equipment in school laboratories was insufficient 
(Demir, 2016; Emendu, 2007; Nwele, 2013). According to 
Ritch & Rank (2001), science laboratory safety at all levels 
must be taken seriously. Accidents are commonly reported 
in science laboratories worldwide, which underlined the 
need for awareness and adequate information on the 
importance of prioritizing safety in science laboratories 
 

4. CONCLUSION 
As a result of the study, it was seen that although 

secondary school students have some general information 

Table 6 Expectations regarding laboratory safety 

Themes Codes 6th Grade 7th Grade 8th Grade Total 

f % f % f % f % 

Expectations 
from the 
Science 
Teacher 

Working more carefully and meticulously in the 
laboratory environment 

3 7.6 4 7.4 4 9.3 11 8.1 

Locking the lab door when there is no course 2 5.1 2 3.7 - - 4 2.9 

Putting laboratory materials in the right place (storing 
chemicals in a different cabinet) 

2 5.1 4 7.4 - - 6 4.4 

Providing information about the materials to be used in 
the experiment 

9 23 7 12.9 8 18.6 24 17.6 

Informing us about safety measures 7 17.9 10 18.5 19 44.1 36 26.4 

Taking more precautions 1 2.5 1 1.8 2 4.6 4 2.9 

Helping us in dangerous experiments 2 5.1 4 7.4 1 2.3 7 5.1 

Acting exemplary by using protective equipment 1 2.5 - - 2 4.6 3 2.2 

Preventing our contact with harmful substances such as 
chemicals. etc. 

- - 5 9.2 4 9.3 9 6.6 

No expectation/Unrelated response 10 25.6 23 42.5 10 23.2 43 31.6 

Expectations 
from School 
Administrators 

Keeping a fire extinguisher and first aid kit in the 
laboratory for emergencies 

3 7.6 - - 8 18.6 11 8.1 

Fixing the cabinets 5 12.8 3 5.5 - - 8 5.8 

Training on laboratory safety 10 25.6 16 29.6 9 20.9 35 25.7 

Purchasing new and quality materials for the laboratory 4 10.2 1 1.8 3 6.9 8 5.8 

Detecting broken/non-working materials 1 2.5 1 1.8 10 23.2 12 8.8 

Putting warning signs on the walls/cupboards 1 2.5 3 5.5 6 13.9 10 7.3 

Providing safety equipment such as gloves/lab glasses 1 2.5 - - 2 4.6 3 2.2 

Having special cabinets for chemicals - - 7 12.9 1 2.3 8 5.8 

Installing a camera in the laboratory and detecting 
students who commit security violations 

- - 2 3.7 - - 2 1.4 

Doing safety drills - - - - 2 4.6 2 1.4 

No expectation/Unrelated response 12 30.7 16 29.6 5 11.6 33 24.2 

 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i3.30752 228  J.Sci.Learn.2021.4(3).220-229 
 

about laboratory safety, they have deficiencies in terms of 
most of the information. It was determined that students 
do not know most of the behaviors that must/must not be 
made in the laboratory, and they are not aware of some of 
the safety symbols in the science textbooks. Besides, most 
of the students stated that they don't feel competent about 
laboratory safety and need training on this subject. 

The following suggestions can be made in line with the 
results of the study: 

• As a result of the study, it was observed that although 
secondary school students had general knowledge 
about laboratory safety, they did not have detailed 
information. Therefore, students should be informed 
about some issues such as safety symbols, the purpose 
of using laboratory materials, what to do 
before/during/after the experiment, and how to 
behave in possible accidents.  

• Although the students were asked about the safety 
symbols found in the textbooks, it was determined that 
they did not have any idea about some safety symbols. 
This shows that the presence of safety symbols in 
textbooks alone is not enough. Teachers should show 
the necessary sensitivity in conveying this information 
to students. 

• The students explained the behaviors that should and 
should not be done in a safe working environment. 
Long-term laboratory observations can be made to 
compare whether students' views and actions coincide. 

• Students expect both science teachers and school 
administrators to provide information about 
laboratory safety. They expressed that they felt 
inadequate in this area. Interviews can be done with 
school administrators and science teachers about this 
issue. "Have students been trained on this subject 
before? If so, by whom and how often?" Answers to 
such questions can be sought. Besides, the laboratory 
safety knowledge test can be used to determine which 
subject students need information. 

• To properly educate the students about laboratory 
safety, he/she must first have the correct and sufficient 
knowledge. Therefore, teachers' knowledge and views 
about laboratory safety can be investigated. 

• Similar studies can be conducted on different samples 
in different schools. Increasing the number of 
researches will provide more information on the 
subject and reveal whether there is consistency among 
the results.A quantitative data collection tool was used 
in this study. By using qualitative data collection tools, 
research can be done, and in-depth information can be 
accessed. For example, "Are students taking enough 
personal responsibility or do they see it as their 
teacher's job? What are the responsibilities of students 
and teachers regarding laboratory safety?". Answers to 
such questions can be sought by conducting interviews 
with students and teachers 

REFERENCES   
Alaimo, P. J., Langenhan, J. M., Tanner, M. J., & Ferrenberg, S. M. 

(2010). Safety teams: An approach to engage students in laboratory 
safety. Journal of Chemical Education, 87(8), 856-861. 

Ali, N. L., Ta, G. C., Zakaria, S. Z. S., Halim, S. A., Mokhtar, M., Ern, 
L. K., & Alam, L. (2018). Assessing awareness on laboratory safety: 
A case study in Pahang, Malaysia. Jurnal Pendidikan Malaysia, 43(2), 
73-80. 

Anılan, B. (2010). The recognition level of the students of science 
education about the hazard symbols of chemicals (Case of 
ESOGU, Eskisehir). Procedia Social and Behavioral Sciences, 2(2), 4092-
4097. 

Artdej, R. (2012). Investigating undergraduate students’ scientific 
understanding of laboratory safety. Procedia Social and Behavioral 
Sciences, 46, 5058-5062. 

Ateş, İ., & Özarslan, M. (2013). Üstün zekalı ve yetenekli öğrencilerin 
fen bilimleri laboratuvar çalışmalarındaki güvenlik önlemleri ile 
ilgili görüşleri [The opinions of gifted and talented students about 
security measures in science laboratory studies]. Journal of 
Educational Science, 2(3), 42-49.  

Aydın, S., Diken, E. H., Yel, M., & Yılmaz, M. (2011). Fen ve teknoloji 
ile biyoloji öğretmen adaylarının laboratuvar güvenliği hakkındaki 
bilgi düzeylerinin belirlenmesi [Determining the science and 
technology and biology teacher candidates' knowledge levels about 
laboratory safety]. Journal of Gazi Education Faculty, 31(2), 583-604. 

Aydoğdu, C., & Yardımcı, E. (2013). İlköğretim fen laboratuvarlarında 
meydana gelen kazalar ve öğretmenlerin geliştirebilecekleri davranış 
tarzları [Accidents that occur in primary education science 
laboratories and behaviors that teachers can develop]. Hacettepe 
University Journal of Education Faculty, 44, 52-60. 

Aydoğdu, C., & Pekbay, C. (2016). Sınıf öğretmen adaylarının 
laboratuvarlarda yaşanan kazaların nedenlerine yönelik görüşleri 
[The opinions of the classroom teacher candidates about the causes 
of the accidents in the laboratories]. Journal of Education Science and 
Technology Research, 1(2), 103-112. 

Aydoğdu, C. (2018). Historical development of laboratory in the 
elementary school science program in Turkey. M. Shelley & S. A. 
Kıray (Eds.), Education Research Highlights in Mathematics, Science and 
Technology (pp. 141-174). Iowa: ISRES Publishing. 

Bayraktar, Ş., Erten, S., & Aydoğdu, C. (2006). Fen ve teknoloji 
öğretiminde laboratuvarın önemi ve deneyler [The importance of 
the laboratory and experiments in science and technology 
teaching]. M. Bahar (Editor), Science and technology teaching (pp. 219-
248). Ankara: Pegem A Publishing.  

Böyük, U., Demir, S., & Erol, M. (2010). Fen ve teknoloji dersi 
öğretmenlerinin laboratuvar çalışmalarına yönelik yeterlik 
görüşlerinin farklı değişkenlere göre incelenmesi [Examination of 
science and technology lesson teachers' efficacy opinions on 
laboratory studies according to different variables]. TUBAV Journal 
of Science, 3(4), 342-349. 

Canel, M. (2002). Laboratuvar güvenliği [Laboratory safety]. Ankara 
University, Faculty of Science, Revolving fund business 
publications, No:26, Ankara. 

Çepni, S. (2012). Araştırma ve proje çalışmalarına Giriş (6. Baskı) [Introduction 
to research and project work (6th Edition)]. Trabzon: Celepler 
Publishing. 

Demir, E. (2016). Fen laboratuvarlarının fiziki şartlarının ve fen bilimleri 
öğretmenlerinin laboratuvar güvenliği konusundaki bilgi 
düzeylerinin araştırılması [Investigation of the physical conditions 
of science laboratories and science teachers' knowledge level about 
laboratory safety]. Master Thesis, Gazi University, Ankara. 

Deniz, V., & Ercan-Kalkan, M. (2013). Laboratuvar kazaları [Laboratory 
accidents].https://www.isgturkiye.com/konu/laboratuvar-
kazalari.3551/  

Derman, M., & Çakmak, M. (2016). Biyoloji öğrencilerinin laboratuvar 
güvenliği konusundaki görüşlerinin incelenmesi [Examination of 

https://www.isgturkiye.com/konu/laboratuvar-kazalari.3551/
https://www.isgturkiye.com/konu/laboratuvar-kazalari.3551/


Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i3.30752 229  J.Sci.Learn.2021.4(3).220-229 
 

biology students' opinions on laboratory safety]. Bartın University 
Journal of Education Faculty, 5(1), 178-187. 

Emendu, N. B. (2007). The status of safety precaution and adequacy of 
equipment in chemistry laboratories in senior secondary schools in 
Anambra State. In The Nigerian Academic Forum: A Multidisciplinary 
Journal, 12, 84-89. 

Ezrailson, C. M. (2013). Danger in the school science lab: Are students 
at risk? Proceedings of the South Dakota Academy of Science, 92, 149-164.  

Gerlovich, J., Parsa, R., & Jordan, L. (2004). The 2003 status of science 
safety in Tennessee secondary schools. Journal of the Tennessee 
Academy of Science, 79(4), 83-90. 

Gökmen, A., & Atmaca, S. (2019). Öğretmen adaylarının laboratuvar 
güvenlik işaretleri konusundaki farkındalıkları [Pre-service teachers' 
awareness of laboratory safety signs]. Journal of Education and Social 
Research, 6(2), 426-442. 

Gudyanga, R. (2020). Probing physical sciences teachers' chemical 
laboratory safety awareness in some South African high schools. 
African Journal of Research in Mathematics, Science and Technology 
Education, 24(3), 423–434.Hackling, M., Goodrum, D., & Rennie, 
L. (2001). The state of science in Australian secondary schools. 
Australian Sciences Teachers' Journal, 47(4), 12-17. 

Hamurcu, H. (1998). Fen derslerinde güvenlik [Safety in science classes]. 
Hacettepe University Journal of Education Faculty, 14(14), 29-32. 

Hasenekoğlu, İ. (2003). Laboratuvar güvenliği (2-3) [Laboratory safety (2-
3)]. Erzurum: Kazım Karabekir Education Faculty Publications. 

Hill, R. H., & Finster, D. C. (2010). Laboratory safety for chemistry students. 
New Jersey: John Wiley & Sons Publishing. 

Hodson, D. (1990). A critical look at practical work in school science. 
School Science Review, 70, 33- 40. 

Hofstein, A., & Lunetta, V.N. (2004). The Laboratory in science 
education: Foundations for the twenty-first century. Science 
Education, 88, 28-54. 

Hsieh, H. F., & Shannon, S. E. (2005). Three approaches to qualitative 
content analysis. Qualitative Health Research, 15(9), 1277-1288. 

Karasar, N. (2004). Bilimsel araştırma yöntemi (13. baskı) [Scientific research 
method (13th edition)]. Ankara: Nobel Publishing. 

Kerimak-Öner, M. N. (2020). Kimya eğitiminde laboratuvar güvenliği 
kültürünün yerleştirilmesi [Placement of laboratory safety culture 
in chemistry education]. ISG Academic, 2(1), 15-25. 

Kırbaşlar, F.G, Özsoy-Güneş, Z., & Derelioğlu, Y. (2010). Fen bilgisi 
öğretmen adaylarının laboratuvar güvenliği konusuna yönelik 
düşünce ve bilgi düzeylerinin araştırılması [Investigation of pre-
service science teachers' level of thought and knowledge on 
laboratory safety.]. Journal of Gazi Education Faculty, 30(3), 801-818. 

Miles, M. B., & Huberman, A. M. (1994). Qualitative data analysis: An 
expanded sourcebook. Thousand Oaks, CA: Sage Publications. 

Miles, M., Huberman, M., & Saldana, J. (2014). Qualitative data analysis: A 
methods sourcebook. European journal of science education. Los Angeles: 
Sage Puplication, Thousand Oaks. 

Mogopodi, D., Paphane, B., & Petros, S. (2015). Assessment of chemical 
management practices and safety in junior secondary school 
laboratories in Gaborone. Journal of Chemical Health & Safety, 22(5), 
17–27. 

Muhammad, R. (2017). Assessing the laboratory safety and security skills 
among science, technology and mathematics (STM) teachers in 
Sokoto State, Nigeria. American Journal of Education and 
Learning, 1(2), 62-68. 

Nakiboğlu C., & Sarıkaya, Ş. (1999). Orta öğretim kurumlarında kimya 
derslerinde görevli öğretmenlerin laboratuvardan yararlanma 
durumlarının değerlendirilmesi [Evaluation of the use of laboratory 
by teachers working in chemistry lessons in secondary education 
institutions]. Journal of Buca Education Faculty, 11, 395- 405. 

Nwele, C. N. (2013). Extent of availability of safety 
instruments/equipment in science laboratories in secondary 
schools in Ebonyi State of Nigeria. Academic Journal of 
Interdisciplinary Studies, 2(10), 131-136. 

Okebukola, P. A., Oladejo, A., Onowugbeda, F., Awaah, F., Ademola, 
I., Odekeye, T., & Ajayi, O. A. (2020). Investigating chemical safety 

awareness and practices in Nigerian schools. Journal of Chemical 
Education, 98(1), 105-112.  

Ritch, D., & Rank, J. (2001). Laboratory safety in the biology lab. Bioscene, 
27(3), 17-22. 

Singer, S. R., Hilton, M. L., & Schweingruber, H. A. (2006). America's lab 
report: Investigations in high school science. Committee on high school science 
laboratories: Role and vision. Washington D.C.: National Research 
Council, National Academies Press. 

Stepenuck, S. (2002). Material safety data sheets. NEACT Journal, 21(1), 
28-32. 

Tekbıyık, A., & Tepe, M. (2017). Türkiye’de 2001-2017 yılları arasında 
yaşanan laboratuvar ve deney kazalarının değerlendirilmesi 
[Evaluation of laboratory experiments and accidents that occurred 
between the years of 2001-2017 in Turkey]. International Journal of 
Innovative Approaches in Education, 1(1), 11-20. 

Tepe, M., & Tekbıyık (2019). Ortaokul fen bilimleri ders kitaplarının 
deney ve etkinlik güvenliği bakımından değerlendirilmesi 
[Evaluation of secondary school science textbooks in terms of 
experiment and effectiveness safety]. Journal of National 
Education, 48(1), 223-240. 

Topsakal, S. (2006). Eğitim fakülteleri sınıf ve fen bilgisi bölümü öğrencileri ile 
sınıf ve fen bilgisi öğretmenleri için ilköğretim 6. 7. ve 8. sınıflar fen ve teknoloji 
öğretimi [Primary 6th, 7th and 8th grades science and technology education for 
students of education faculties, classroom and science departments, and 
classroom and science teachers]. Ankara: Nobel Publishing. 

Uluçınar, Ş., Cansaran, A., & Karaca, A. (2004). Fen bilimleri laboratuvar 
uygulamalarının değerlendirilmesi [Evaluation of science 
laboratory applications]. Turkish Journal of Educational Sciences, 2(4), 
465- 475. 

West, S. S., Westerlund, J. F., Stephenson, A. L., Nelson, N. C., & 
Nyland, C. K. (2003). Safety in science classrooms: what research 
and best practice say. In The Educational Forum, 67(2), 174-183. 

Yazıcı, E.K., & Özmen, H. (2015). Fen ve teknoloji öğretim 
programında yer alan deney ve etkinliklerin uygulanabilirliğine 
ilişkin öğretmen görüşleri [Teachers' views on the applicability of 
the experiments and activities in the science and technology 
curriculum]. Amasya University Journal of Education Faculty, 4(1), 92-
117. 

Yıldırım, A., & Şimşek, H. (2006). Sosyal bilimlerde nitel araştırma yöntemleri 
[Qualitative research methods in the social sciences]. Ankara: Seçkin 
Publishing. 

Yılmaz, A. (2005). Lise 1 kimya ders kitabındaki bazı deneylerde 
kullanılan kimyasalların tehlikeli özelliklerine yönelik öğrencilerin 
bilgi düzeyleri ve öneriler [Students' knowledge levels and 
recommendations regarding the dangerous properties of chemicals 
used in some experiments in the high school 1 chemistry 
textbook]. Hacettepe University Journal of Education Faculty, 28, 226-
235.