c e p s  Journal | Vol.7 | No1 | Year 2017 111
Dissection of Mammalian Organs and Opinions about 
It among Lower and Upper Secondary School Students
Andreja Špernjak*1 and Andrej Šorgo2
• This article describes the results of a study that investigated the use of the 
dissection of organs in anatomy and physiology classes in Slovenian lower 
and upper secondary schools. Based on a sample of 485 questionnaires 
collected from Slovenian lower and upper secondary school students, we 
can conclude that dissection of mammalian organs during the courses on 
Human Anatomy would be a preferred activity for the majority of them. 
Opinions on such practices are positive, and only a minority of students 
would prefer to opt out. However, the practice is performed only occasion-
ally in regular classes, or even omitted, and a number of students never 
participate in it. According to the results, we can suggest the dissection of 
mammalian organs in combination with alternatives, such as 3D models 
and virtual laboratories, as a preferred strategy to increase knowledge of 
anatomy and to raise interest in science. However, students should know 
that the organs they are dissecting were dedicated to human consump-
tion, or are waste products in these processes. Opt-out options should be 
provided for those who do not want to participate in such activities.
 Keywords: biology laboratory work; dissection; interest in dissection; 
lower secondary students; upper secondary students 
1 *Corresponding Author. University of Maribor, Faculty of Natural Sciences and Mathematics, 
Slovenia; andreja.spernjak@uni-mb.si.
2 University of Maribor, Faculty of Natural Sciences and Mathematics, Slovenia.
112 dissection of mammalian organs and opinions about it among lower and upper ...
Seciranje organov sesalcev v osnovi in srednji šoli ter 
njihovo mnenje o sekciji v razredu
Andreja Špernjak in Andrej Šorgo
• V članku so predstavljeni izsledki raziskave o sekciji organov pri urah 
anatomije in fiziologije človeka v osnovnih in srednjih šolah. V študijo 
je bilo vključenih 485 učencev in dijakov iz različnih osnovnih in sred-
nji šol. Iz rezultatov lahko sklepamo, da si večina vprašanih pri urah 
biologije želi več sekcije organov. Učenci in dijaki v večini podpirajo 
izvedbo sekcije organov in le majhen odstotek vprašanih sekcije med 
izobraževanjem ne želi izvajati. Glede na rezultate vprašanih sklepamo, 
da je sekcija organov v slovenskih šolah redka praksa ali pa je med 
šolanjem sploh ne izvajajo in je popolnoma izpuščena. Ker si večina 
vprašanih pri urah biologije želi sekcije organov sesalcev kot prednostno 
strategijo za dvig znanja o anatomiji sesalcev in povečanje zanimanja za 
naravoslovje, predlagamo izvedbo sekcije v kombinaciji z rabo drugih 
učnih pripomočkov, kot so 3D-modeli organov ali virtualni laboratoriji. 
Pri sekciji organov je učence in dijake treba seznaniti, da so bili organi za 
sekcijo namenjeni za prehrano ljudi ali pa so kot odpadni produkt v pro-
cesih predelave hrane. Za učence in dijake, ki pri sekciji ne želijo sodelo-
vati, je treba zagotoviti možnost izbora in pripraviti druge dejavnosti.
 Ključne besede: biološko laboratorijsko delo, interes za seciranje, 
osnovnošolci, seciranje, srednješolci
c e p s  Journal | Vol.7 | No1 | Year 2017 113
Introduction 
Biology is a discipline about living beings, and there is no scientific evi-
dence about the presence of life outside organisms. Study of the interiors of 
‘homes of life’ is a part of the standard content of biology courses/subjects at 
the primary and secondary educational levels and is regarded as essential for 
biology, veterinary and medical students (Macchi, Porzionato, Stecco & Caro, 
2014) at the tertiary levels. In formal education, different instructional methods 
exist to attain knowledge and experience about the internal anatomy of animals 
and humans. Methods range from expository instructions, as verbal and mul-
timedia presentations, exposition of models and fresh or conserved animals 
by teachers or teaching assistants, to the first-hand experiences of students as 
dissection in biology/anatomy classrooms, and in recent times as interactive 
virtual dissections (Saltarelli, Roseth & Saltarelli, 2014) and use of 3D printed 
models (Fancovicova & Prokop, 2014; Fredieu, Kerbo, Herron, Klatte & Cooke, 
2015; McMenamin, Quayle, McHenry & Adams, 2014). All instructional meth-
ods used in anatomy teaching, except dissection itself, have in common that 
they can be recognised as derivatives of dissection, because there is no alterna-
tive to obtaining primary insight inside the bodies of members of the animal 
kingdom.
Globally, differences between countries in the views and position on dis-
section exists, largely based on the dominant teaching culture and values of a 
society, with trends for the exclusion of animal dissection or its replacement 
by virtual alternatives (Demirhan, 2014; Osenkowski, Green, Tjaden & Cun-
niff, 2015). For instance, in the USA, the National Science Teachers Association 
(NSTA, 2005) supports the decision of science teachers to integrate live animals 
and dissection into the classroom. However, regardless of the support of NSTA 
authorities, the dissection of a whole animal or organ is a common practice 
only in some school districts’ biology curricula and absent in others (Mattheis, 
Ingram, Jensen & Jackson, 2015). Schools in five countries (Argentina, Israel, 
the Netherlands, Slovakia, and Switzerland) do not conduct dissections, and 
the practice is rare or being phased out in other countries, including England, 
Sweden, and India (Oakley, 2011). In German biology classes, dissections are 
required by educational authorities, e.g. by the Ministry of Culture and Educa-
tion in Lower Saxony (Holstermann, Grube & Bögeholz, 2009). At semi-formal 
levels, dissection is an obligatory activity of the practical part of International 
Biology Olympiads (A Guide to the International Biology Olympiad, 2015). In 
Slovenian schools, dissection of mammalian organs is encouraged by national 
documents on biology/science education but in practice entirely depends on 
114 dissection of mammalian organs and opinions about it among lower and upper ...
the teacher’s autonomous decision and discretion to include it in teaching or 
not. To our best knowledge, studies about the status of dissection in Slovenian 
schools do not exist, which was one of the main incentives to begin our research.
The dissection of organs as a part of biology laboratory work has been 
recognised as beneficial with arguments that dissection can help students to 
develop skills of observation and comparison, discover the shared and unique 
structures of specific organisms, and develop a greater appreciation for the 
complexity of life (NSTA, 2005). However, some authors have claimed that ani-
mal dissection is a controversial pedagogical practice. In educational contexts, 
it raises ethical and environmental concerns regarding the killing of animals, 
the ignoring of animal welfare standards, the weakening of respect for life, and 
the ‘turn-off ’ factor for some students (Balcombe, 2000; Bishop & Nolen, 2001; 
Hug, 2008; Jukes & Chiuia, 2003; Marr, 2001; Oakley, 2009; Sapontzis, 1995). As 
Balcombe (2000) writes, there is an ethical question underlying the justifica-
tion of killing animals to learn how they work, even if this is thought to be the 
best way to teach.
In Slovenian schools, teachers are allowed to dissect mammalian organs 
that have been obtained in a slaughterhouse or butcher shop unless they con-
tain bovine nervous tissues, due to possible BSE transfer. The same is true for 
other vertebrates, which leaves only the dissection of birds (poultry) and fish. 
However, the raising of vertebrates as model organisms in a school vivarium 
is encouraged, but not with the purpose of dissection. Practices of whole body 
mammalian dissection. such as dissection of rodents has been abandoned in 
elementary and secondary schools. By using animals or their parts for human 
consumption, ethical questions are largely reduced, because all dissections in 
schools are performed on organs or animals for which dissection was not the 
sole or primary purpose of killing the animal. However, due to different rea-
sons, some students would prefer to opt out of dissection. Since dissection can 
negatively impact students’ self-efficacy beliefs and interest levels, adolescents 
are not pressured to perform dissection or have contact with dead organs (Hol-
sterman et al., 2009). Based on conversations with teachers, which were part of 
regular visits to schools by the authors of the present paper, the most common 
practice is that students are allowed to opt out of dissection without penalty. 
However, due to school regulations, they are not allowed to leave the classroom: 
in the most cases, they observe dissection from a distance, following the so-
called opt-out scheme (Cunningham, 2000).
Because of ethical concerns about dissection, alternatives have been 
sought, recently in virtual worlds (Peat & Taylor, 2005). Research based on all 
educational levels indicates that outcomes pertaining to learning anatomy and 
c e p s  Journal | Vol.7 | No1 | Year 2017 115
physiology can be met by virtual alternatives, and that students’ gained knowl-
edge can be equivalent, and sometimes superior, to traditional dissections 
(Cottam, 1999; Lalley, Piotrowski, Battaglia, Brophy & Chugh, 2010; Maloney, 
2005). In contrast, Kerby, Shukur, and Shalhoub (2011) claimed that while the 
use of computer simulations and virtual dissection serve as valuable teaching 
tools, they simply cannot replace hands-on experience that dissection affords. 
In a review of studies designed to compare the effectiveness of various forms of 
instruction for first-year medical students, Winkelmann (2007) found that the 
literature suggests advantages of traditional hands-on dissection, but does not 
discount the value of alternative methods, including prosection and the use of 
computerised multimedia imaging programs. Many medical educators view dis-
section as a learning experience that cannot be replicated through other means. 
De Villiers and Monk’s (2005) review of research on the topic not only revealed 
ongoing tensions within the field, but also acknowledged the fact that strong 
support remains for this type of hands-on learning of anatomy despite the in-
creased availability of alternative and virtual experiences. Additionally, as noted 
by Richardson (2011), even the best virtual dissection activities have inherent 
contradictions to the fundamental nature of anatomy, physiology, and science 
in general, as they do not entirely effectively convey the distinction between liv-
ing organisms and machines and the unpredictability of living organisms and 
systems. Richardson (2011) warned that virtual dissections may promote mis-
conceptions and lead to overgeneralisation. Most probably, the best learning 
outcomes are achieved by a combination of real and virtual dissection not as 
exclusive but as complementary. A body of research shows that a combination 
of real and virtual, both as used virtual for preparation for virtual dissection or 
used for confirmation and repetition outperformed using each technique sepa-
rately (Akpan & Andre, 2000; Akpan, 2002; Smetana & Bell, 2012).
The dissection of human organs is out of scope in Slovenian second-
ary schools and challenged at university levels. Because linking the structure of 
organs with function is considered to be a basic science concept, dissections of 
pig or cow organs are set in the context of human biology in order to illustrate 
how human organs are built and work (Entrich, 1996; Mattheis, Ingram, Jensen 
& Jackson, 2014).
Research questions and aim of the study
In Slovenian schools, the dissection of mammalian organs is recom-
mended but, to our best effort, we were not able to find a study about the actual 
use of dissection in schools or on interest and attitudes toward this practice 
116 dissection of mammalian organs and opinions about it among lower and upper ...
among students. This paper intends to contribute to this issue.
Our research questions were as follows:
•	 Which mammalian organs, if any, do students dissect during their bio-
logy laboratory work?
•	 Which mammalian organs would they prefer to dissect, if any?
•	 Would participants show more interest in the dissection of organs if they 
had such experiences from biology/science classes?
•	 Are there any differences in opinion between participants on the dissec-
tion of organs regarding school level and gender?
Methods
Sample and sampling
Our study is exploratory by design, and no interventions were made in 
classroom practice. The participants for this study were students of six differ-
ent lower secondary (Level 2 by ISCED, 2011) and six different upper secondary 
schools (Level 3, ISCED, 2011) from Slovenia. Interested readers can obtain more 
information on the Slovenian school system from international webpages, e.g. 
http://www.ukom.gov.si/en/media_room/background_information/education/
educational_system_in_slovenia/.
Prior to the survey, permission was obtained from the school authorities. 
Participants were asked to complete a questionnaire in paper-and-pencil for-
mat prepared for the purpose of the study during their regular classes, follow-
ing the standard protocol. During the initial phase, they were informed about 
the goals of the research, given specific instructions about filling the question-
naire fields, and guaranteed anonymity. Additionally, they were informed that 
answering was on a free will basis, so anybody could opt out anonymously by 
simply returning an unanswered questionnaire at the end of the session, and 
that no benefits were provided. There were no specific time constraints, but 
respondents typically needed about 10 minutes to complete the survey. We col-
lected 483 questionnaires. The students were aged between 14 and 18 years old; 
280 students were from the 8th grade (179 students; 37.1%) and 9th grade (101 stu-
dents; 20.9%). From seven high schools, 203 questionnaires were collected (44 
students (9.1%) from 1st year, 22 students (4.6%) from 2nd year, and 137 students 
(28.4%) from 3rd year). We collected 207 questionnaires from boys (42.9%) and 
276 questionnaires from girls (57.1%).
 
c e p s  Journal | Vol.7 | No1 | Year 2017 117
Structure of the survey instrument
The questionnaire contained three parts.
Demographics
The first part of the questionnaire solicited demographic data about 
school grade and gender.
Actual experiences of dissection and opinions about what items should 
be dissected
The second part required participants to mark in yes/no format if they 
had examined or touched or dissected some mammalian organs during biology 
classes, and if they had, which organs (see Table 1). In the same table, they also 
had to mark in yes/no format which organs they would like to examine or touch 
or dissect during school laboratory sessions.
Results of actual experiences with dissection of mammalian organs 
(Cronbach’s alpha = 0.612) can be recognised as biased, because of the small 
number of examined classes, which can influence outcomes because of the hab-
its and practices of the small number of teachers teaching our sample; this does 
not permit the transfer of findings to the whole population of students.
However, the results of opinions on which mammalian organs should be 
dissected (Cronbach’s alpha = 0.862) can be recognised as representative. 
Attitudes toward dissection as a school practice 
The third part was a scale with 12 statements created to explore partici-
pants’ attitudes toward dissection as a school practice. The answering format was 
a 5-point Likert scale, as follows: 1 = definitely disagree; 2 = disagree; 3 = neutral; 
4 = agree; 5 = definitely agree. The Cronbach reliability coefficient for the scale is 
0.87, which can be considered appropriate for further analyses.
Statistical procedures
The statistical procedures employed were as follows: 
a) Descriptive statistics: prior to statistical analysis, variables were checked 
for normality. The Kolmogorov-Smirnov Z test (KS test) at the 0.05 
significance level was used. Because all variables do not follow normal 
distribution, nonparametric statistic was preformed (Erceg-Hurn & Mi-
rosevich, 2008). Due to skewed data frequencies, mode and median are 
reported. Means and standard deviations are reported only to obtain a 
118 dissection of mammalian organs and opinions about it among lower and upper ...
better impression of data distribution. The reliability of the scales was 
explored by the calculation of Cronbach’s alpha, and by further analysis 
with the ‘alpha if item deleted’ procedure in order to foresee possible 
improvements of the scales. Due to satisfactory alpha levels and to pre-
serve the breadth of the scale, no items were deleted from a pool even if 
an increase in alpha was predicted.
b) Principal Component Analysis with Direct Oblimin rotation was used 
to explore the factorial structure of the attitudes toward dissection as a 
school practice scale because of correlated items. Prior to the analyses, 
KMO (.912) and Barlett’s test (Chi-Square = 2363,8; df = 66; sig < .001) 
were performed, with a scale falling into the range in which further analy-
ses are permitted. Principal components with Eigenvectors above 1, and 
items with loadings above the 0.4 level are reported due to the breath of 
the reported findings; however, parallel analysis (Flora & Curran, 2004) 
was the preferred choice to explore the number of factors to be retained. 
c) Correlations were checked as parts of analyses provided by Factorial 
and Regression procedures. Pearson’s correlation coefficients were cal-
culated; coefficients below the 0.05 level (two-tailed) were considered 
significant.
d) Regression analysis: Linear regression analysis was performed with the 
enter and case-wise deletion option; variables below the 0.05 level (two-
tailed) were considered significant.
e) Effect size was used to examine differences in opinions by students’ school 
level (between lower secondary and upper secondary school) and gen-
der. With the next equation:                was calculated Effect size; where 
Z = Kolmogorov - Smirnov Z and         = the square root of the sample 
size (Field, 2009, p. 550), and in the case of related data output of Wil-
coxon’s matched pair test.
Microsoft® Excel 2010 was used for data input. The analyses were per-
formed with the SPSS 21® statistical package according to the procedures sug-
gested by Field (2009).
Results 
Students’ dissection and their interest in it regarding school level and 
gender
The students had two tasks. The first was to mark if they had examined 
touched or dissected fresh mammalian organs during biology classes and, if 
they had, which organs. The second task was to mark whether they would like 
c e p s  Journal | Vol.7 | No1 | Year 2017 119
to examine, touch, or dissect fresh mammalian organs and, if so, which organs. 
A list of seven mammalian organs regularly available to the teachers and the 
open-ended option ‘other’ were given (Table 1).
Table 1. Frequency of students, who have examined, touched or dissected 
mammalian organs and their interest in such practice to be performed in biology 
classes (N = 483)
Organ
In biology classes, we have exam-
ined, touched or dissected organs
For better understanding, I would like 
to examine, touch, or dissect organs
Difference 
(N2 – N1)
Frequency (N1) Percent Frequency (N2) Percent Diff
bones 200 41.41 310 64.18 110
eyes 156 32.29 300 62.11 144
hearth 117 24.22 341 70.60 224
livers 117 24.22 262 54.24 145
kidneys 98 20.29 270 55.90 172
brains 79 16.36 333 68.94 254
stomach 44 9.11 254 52.58 210
other 16 3.31 28 5.79 12
From Table 1, we can recognise that bones and eyes are the most com-
monly dissected mammalian organs in Slovenian schools, while brains and liv-
ers were the least commonly dissected. Except for eyes, which are normally 
discarded in slaughterhouses, all other organs are easily obtainable in local su-
permarkets for human or animal consumption. However, students’ ‘wish list’ 
about what should be examined differs significantly from what they actually do 
in a school in all cases, with heart and brains at the top, and no organ falling 
below the 50% margin.
We were not able to find any statistically significant differences on per-
formance and opinions about dissection between genders, except for the field 
‘other’ in the opinion part, where boys are more enthusiastic than girls with 
their proposals about organs to be added. Statistically significant differences are 
also present among lower and upper secondary students; however, differences 
expressed as effect sizes are almost non-existent and small, all falling below r < 
.12 levels. Differences in actual dissection between lower and upper secondary 
schools also exist, but do not exceed small or lower margin of medium levels, 
with the highest sizes for brains (r = 0.2) and bones and livers (r = 0.4).
120 dissection of mammalian organs and opinions about it among lower and upper ...
Table 2. Number of organs that students actually dissected and number of organs 
they would like to dissect
Number of 
organs
In biology classes we have examined, 
touched, or dissected organs
For better understanding, I would like to 
examine, touch, or dissect organs
Frequency Percent Frequency Percent
0 111 22.98 67 13.87
1 176 36.44 30 6.21
2 75 15.53 32 6.63
3 46 9.52 57 11.80
4 33 6.83 46 9.52
5 25 5.18 45 9.32
6 13 2.69 32 6.63
7 4 0.83 160 33.13
8 0 0.00 14 2.89
Total 483 100.0 483 100.0
From Table 2, we can recognise that about 23% of students from our 
sample had never examined, touched or dissected animal organs as laboratory 
work, and less than 10% had experiences with more than five organs. The statis-
tical difference between elementary and secondary schools in the performance 
of actual dissection is insignificant (U = 27958; p = .75; r = .01). 
However, only 13.9% of students declared that they would not like to 
examine, touch or dissect organs, and more than half (51.9%) declared that they 
would like to examine, touch or dissect more than five different organs. Prior to 
the study, we thought that practice would predict desired practice in negative 
or positive ways, but correlations between the sum of actually dissected organs 
from the list and organs that students would like to dissect practically do not 
exist (r = –0.06, p = 0.20). Differences between genders are statistically insig-
nificant (U = 27248.5; p = .38; r = .04). Slightly larger, but marginally significant 
at p < .01 levels, are differences in the desire to dissect between elementary and 
secondary school students (U = 25526; p = .05; r = .09): elementary school stu-
dents show slightly more enthusiasm for such activities.
c e p s  Journal | Vol.7 | No1 | Year 2017 121
Table 3. Differences between the number of mammalian organs students actually 
dissected and the number of organs they would (dis)like to dissect
Difference Frequency Percent
-8 2 0.41
-7 48 9.94
-6 64 13.25
-5 50 10.35
-4 53 10.97
-3 47 9.73
-2 47 9.73
-1 33 6.83
0 61 12.63
1 26 5.38
2 19 3.93
3 14 2.89
4 8 1.66
5 10 2.07
7 1 0.21
Total 483 100.0
Differences for individual students between what was actually dissected 
and what is on their wish list shows that only 12.6% of students (difference is 
0) are satisfied with what happens in their biology classes. The negative values 
show that most of them (71.2%) would like to dissect more organs than they 
actually did, and only about 16.2% would like to dissect fewer. Differences be-
tween genders are not statistically significant (U = 26945.5; p = .28; r = .05), and 
between elementary and secondary schools as well (U = 25889; p = .09; r = .08) 
in favour of elementary schools.
Opinions about teaching and learning practices in which fresh 
mammalian materials are used
Results of opinions provided by elementary and secondary school stu-
dents are provided in Table 4; differences between genders and school levels, 
calculated by Mann Whitney test, ranks, p-values and effect sizes are provided 
in the Appendix.
122 dissection of mammalian organs and opinions about it among lower and upper ...
Table 4. Opinions about teaching and learning practices in which fresh mammalian 
materials are used
Note: Results are sorted by decreasing values of Principal Components (PC1–PC3). Percentages are 
given below frequencies (F1–F5). Values in Values in brackets in Median (Me) and Modus (Mod) Col-
umns are reverse coded.
Three principal components (Table 4) were extracted using eigenvalue > 
1 criteria, but only one factor is retained. From the factor itself and frequencies 
of answers (items) composing it can be revealed that most of the students are 
No Statement N F1 F2 F3 F4 F5 M SD Me Mod PC1 PC2 PC3
14
Work with fresh materials should 
be included in lessons about the 
human body.
482 5511.42
53
11.00
109
22.62
123
25.48
142
29.48 3.51 1.32 4 5 .88 -.08 .12
9 I would like to work with fresh materials more often.
482 60
12.45
58
12.03
96
19.92
105
21.78
163
33.82 3.52 1.39 4 5 .85 .00 -.00
3
When we work with fresh mam-
malian organs (brains, eyes, etc.) 
in biology lessons, it motivates me 
more for classroom cooperation 
and learning.
482
65
13.49 489.96
85
17.63
101
20.95
183
37.97 3.60 1.42 4 5 .85 -.02 .03
1
During anatomy and physiology 
lessons about the human body, I 
would like to examine, touch or 
dissect mammalian organs.
481 4910.19
45
9.36
111
23.08
98
20.36
178
37.01 3.65 1.33 4 5 .83 -.03 .14
15
Because of work with fresh ma-
terials, I would more easily make 
a decision about a profession in 
medicine.
482 7014.52
64
13.28
118
24.48
86
17.84
144
29.88 3.35 1.40 3 5 .68 -.09 .24
4 I do not like to work with fresh materials. 483
176
36.44
104
21.53
102
21.12
41
8.49
60
12.42 2.39 1.37
2 
(4)
1
(5) .68 .18 -.22
10
I prefer that a teacher show us a 
model or a picture of an organ 
than showing us a fresh one. 
483 10822.36
124
25.67
119
24.64
55
11.39
77
15.94 2.73 1.35
3
(3)
2
(4) .64 .14 -.37
5 When I see fresh mammalian organs, I feel sick. 482
178
36.93
105
21.78
88
18.26
48
9.96
63
13.07 2.40 1.40
2
(4)
1
(5) .42 .33 -.40
6
I cannot recognise a difference 
between learning from fresh ma-
terial or plastic model of brains. 
483 17035.20
118
24.43
108
22.36
43
8.90
44
9.11 2.32 1.29
2
(4)
1
(5) .42 .05 -.10
7 I do not like to learn about the human body. 482
219
45.44
114
23.65
88
18.26
38
7.88
23
4.77 2.03 1.18
2
(4)
1
(5) .09 .77 .11
12
Processes inside our body that 
we cannot see are not important, 
so it is unnecessary to burden us 
with them.
482 25051.87
94
19.50
93
19.29
22
4.56
23
4.78 1.91 1.15
1
(5)
1
(5) -.13 .87 .07
8 I like themes that are connected to everyday life.
483 17
3.52
15
3.11
80
16.56
149
30.85
222
45.96 4.13 1.03 4 5 .17 .25 .83
Cronbach’s alpha .89 .57 NA
Variance explained 43.0 10.3 9.60
Eigenvalue 5.17 1.23 1.15
c e p s  Journal | Vol.7 | No1 | Year 2017 123
supportive toward the inclusion of fresh mammalian organs in their instructions. 
They recognise learning about human body and processes inside it as important 
and like themes connected to everyday life. Differences between genders (See Ap-
pendix), even if statistically significant, are expressed as effect size values, small, 
and exceed the .2 level in only one item, showing a greater interest of girls toward 
processes inside their body. Similarly, all differences in opinions between elemen-
tary and secondary school students fall below .15 margins. Small effect size values 
allow us to treat the whole sample as one group in our analyses.
Discussion
Dissection of mammalian organs is a preferred activity for the largest 
number of students, regardless of gender or school levels. These findings are in 
line with previous knowledge that practical and active work is what students 
missed the most in Slovenian biology education (Šorgo & Špernjak, 2007). 
However, many students do not have this opportunity, because a number of 
teachers rely on presentations, even if laboratory alternatives are available 
(Šorgo, Usak, Aydogdu, Keles & Ambrozic-Dolinsek, 2011); active methods, 
laboratory work included, is recommended by syllabi of science subjects (Šorgo 
& Špernjak, 2012). From the study, we cannot make definite conclusions about 
the reasons of teachers for the exclusion of dissections from their laboratory 
practices. Implicitly, for a number of teachers, the reasons are most probably 
a combination of overloaded curricula, preferred explanatory style of instruc-
tions, commodity, costs of fresh materials, and the safety of avoiding critiques 
or pressures from the minority of parents and opinion makers who are oppo-
nents of such practices. A study answering these questions is necessary.
From the presented results (Tables 1, 2, 3), we can conclude that only 
a minority of students (less than 15%) would potentially like to opt-out from 
dissection practice or perform it in an alternative way; most of the students 
would like to dissect more frequently. Statistical differences between genders 
and school levels are insignificant, so we can differentiate between them only 
on the basis of their abilities. This finding can be used as an incentive toward 
the introduction of more interesting and active teaching practices, dissection 
included, often absent from Slovenian science education (Ploj Virtič & Šorgo, 
2016; Šorgo & Kocijančič, 2011; Šorgo & Špernjak, 2012). 
Given that science is not one of the most popular subjects for a majority 
of students, the exclusion of dissection from laboratory work would sacrifice 
valuable teaching practice that can make it more interesting and appealing to 
them. Although we respect most of the arguments against dissection of animals 
124 dissection of mammalian organs and opinions about it among lower and upper ...
in a school classroom, we would not recommend discarding dissection, but 
would allow an opt-out scheme for the minority of them who would not like 
to perform or attend dissection, allowing them to fill missing knowledge gaps 
with alternative methods, such as virtual dissection, or learning from charts.
We do not support the killing of animals in elementary and secondary 
schools solely for the purpose of dissection. However, we strongly support a 
practice in which animals or their parts to be used as human or animal food 
are to be presented in a classroom to students as ‘homes of life’. In such a way, 
arguments regarding the ethics of school dissection can be largely weakened on 
the basis of arguments that: 
a) no animal was sacrificed for the purpose of dissection; 
b) they have been slaughtered by professionals according to the existing 
standards for human consumption; 
c) that the presentation of animal organs to the students can not present 
a greater stress than that of walking through the meat department in 
supermarkets; 
d) that stress from dissection cannot exceed that experienced by home 
meat preparation for consumption; 
e) and last and not least that no part of dissected organs will be discarded, 
but used to feed other animals, such as lizards, frogs and fish in school 
aquaria and terraria, or domestic animals, such as dogs and cats. 
Dissection as a teaching practice can raise interest in biology, competing 
with the falling interest in science worldwide among adolescents. The results 
from our study on attitudes (See Table 4) are similar to findings that dissec-
tion is a preferred method of anatomy laboratories at college levels (Lombar-
di, Hicks, Thompson & Marbach-Ad, 2014). Osenkowski, Green, Tjaden and 
Cunniff (2015) also reports students’ great interest in dissection and that this is 
the reason that educators still use it, although they would like to exchange dis-
section with alternatives. According to Lombardi et al. (2014), plastic models 
may be more effective than organ dissections or virtual dissections for teach-
ing heart anatomy and physiology content, but organ dissections may have the 
highest perceived practical value and may be superior for improving students’ 
attitudes toward science. In classrooms, a variety of hands-on (including dis-
section) and model-assisted activities should be used, as this may accommo-
date students of varied learning styles, and different activities are best suited 
to achieving different goals. Holstermann et al. (2009) claimed that topics that 
relate to aspects of human biology are of interest to students, which is con-
firmed by this study: students like to learn about anatomy and physiology of 
c e p s  Journal | Vol.7 | No1 | Year 2017 125
the human body, which is connected to everyday life. Holstermann et al. (2009) 
also investigated students’ disgust and interest in dissection; the results show 
that dissection has a high potential to influence students’ intrinsic motivation 
positively if the students do not feel disgust. This empirical evidence might be 
an important argument to justify – and improve – dissection in biology classes. 
Differences between genders are present in our study, but are, according 
to calculated effect sizes, small or even non-existent, and cannot affect teaching. 
Some studies in the effects of dissection-room experiences in medical schools 
have also found no gender differences of the impact of dissection (Bernhardt, 
Rothkötter & Kasten, 2012), while several others have reported higher levels of 
stress among women than men (Bernhardt et al., 2012; Dempster, Black, Mc-
Corry & Wilson, 2006). Bernhardt et al. (2012) thought that this may have been 
due to women being more prepared than men are to admit and divulge their 
own emotional reactions.
Conclusions
Based on our results, we can make some conclusions and recommen-
dations to improve biology instruction, to make it more interesting and more 
effective.
Even if there are many studies arguing that knowledge on anatomy and 
physiology can be achieved by virtual methods, or using 3D models, we can 
argue that a number of studies shows that combinations of hands-on models, 
and virtual activities should be the preferred choice. Dissection of organs is 
important for several reasons: students can make a connection between theory 
and practice; they can feel the structures of organs, observe organs in real size 
and real colour; observe the inner structures of organs like cardiac valves in 
the heart or the whiteness and greyness of brain, they can make experiments 
with the eye lens and observe retina, determine the significance of the cor-
nea strength, determine the flexibility and hardiness of bones, and observe the 
stomach structure and kidneys. According to Mayer (2007), dissection contrib-
utes to more adequate epistemological beliefs. It is also a scientific hands-on 
activity that develops students’ manual skills.
As a final conclusion, we can advise teachers, contributors, and authors 
of the Slovenian biology syllabi (curricula) that even if dissection is rare in Slo-
venian biology classes, and some ethical concerns on dissection may exist, this 
practice should be encouraged. Because of students’ interest, and to provide 
students with the best alternatives toward study of ‘homes of their lives’, we 
should encourage dissection together with models and computer simulations 
126 dissection of mammalian organs and opinions about it among lower and upper ...
to make the learning process more effective and interesting. For those who do 
not wish to participate in dissection, opt-out option should be provided.
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