Universitas Muhammadiyah Malang, East Java, Indonesia 

 

JPBI (Jurnal Pendidikan Biologi Indonesia) 
 

p-ISSN 2442-3750, e-ISSN 2537-6204 // Vol. 6 No. 2 July 2020, pp. 305-316 

 

 

        10.22219/jpbi.v6i2.12207                              http://ejournal.umm.ac.id/index.php/jpbi                     jpbi@umm.ac.id  305 

Research Article 

Developing guided inquiry module in animal 
reproductive system material 
 

Nosi Qadariah a,1, Sri Rahayu Lestari a,2,*, Fatchur Rohman a,3  
a Department of Biology, Faculty of Mathematics and Natural Sciences, Universitas Negeri Malang, Jl Semarang No.5 Malang 65145, 

   East Java, Indonesia 
1 nosiqadariah1201355@gmail.com; 2 srirahayulestari@um.ac.id* ; 3 fatchur.rohman.fmipa@um.ac.id 

* Corresponding author 

 

INTRODUCTION  

Science process skills in the 21st century are abilities that can be transferred widely, involving scientific 
disciplines, and reflect scientific behavior, which emphasizes the learning process used to investigate and 
develop scientific concepts, be able to solve problems, make decisions, find answers, and have a scientific 
attitude (Ekici & Erdem, 2020). A learning method in IKIP Budi Utomo Malang Animal Physiology Semester 
Learning Plan used to develop science process skills in animal physiology courses should be conducted with 
a combination of small group discussion, class demonstration, independent assignment, and laboratory 
practice. Needs analysis questionnaire and interview with lecturers on May 24, 2018, suggests that the 

A R T I C L E  I N F O   A B S T R A C T   

 

Article history 
Received May 15, 2020 

Revised June 8, 2020 

Accepted June 17, 2020  

Published July 21, 2020 

 Guided inquiry module is one of alternative to improve students’ science process skills 
and cognitive learning outcomes. The aim of this research was to produce guided 
inquiry module in animal reproductive system material as well as improving student 
science process skills and cognitive learning outcomes. The research used ADDIE 
development model which consists of the following stages: analyze, design, develop, 
implement, and evaluation. The research instruments for collecting the data included 
material and media expert validation sheets, field practitioner questionnaire, module 
practicality questionnaire, pretest and posttest question sheets (used to measure 
science process skills and cognitive learning outcomes). The data analysis technique 
used were quantitative and qualitative descriptions as well as quade's rank analysis of 
covariance. The results of content and media expert validations were 94.84%  and 
92.43%  respectively. In addition, the field practitioner response reached 95.7% and the 
module practicality value was 91.3%. Furthermore, the module has significantly 
improved students’ science process skills [F(1,78) = 42.509, p < 0.05] and  cognitive 
learning outcome  [F(1,78) = 7.480, p < 0.05]. Hence, the module is recommended to 
be implemented in delivering animal reproductive system. 

 
 

Copyright © 2020, Qadariah et al  

This is an open access article under the CC–BY-SA license 

    

 

 
Keywords 
Animal reproductive system 
Cognitive learning outcomes 
Guided inquiry module 
Science process skills 
 
 

 

 

  

 
How to cite:  Qadariah, N., Lestari, S.R., & Rohman, F. (2020). Developing guided inquiry module in animal reproductive system 

material. JPBI (Jurnal Pendidikan Biologi Indonesia), 6(2), 305-316. doi: https://doi.org/10.22219/jpbi.v6i2.12207 
 

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learning process has not integrated science process skills, the general learning is conducted using 
presentation and discussion. This type of lecture causes low student cognitive learning outcomes. 

The cognitive learning outcome associates with student understanding, reasoning, and intellectual level on 
content studied (Bloom, Engelhart, Furst, Hill, & Krathwohl, 1956). The low student cognitive learning outcome 
is evidenced by a formative test value of 49.25, which is very low. Observation is also conducted on content in 
animal physiology course. The result of observation on lecturer and students indicates that the difficult topic is 
the reproduction system. The difficulty is related to the content that is abstract and complex (25% students), a 
concept taught is a comprehension (20.8% students), it is hard to apply in real life (12.5% students), and less 
availability of teaching materials that are relevant and applicable in real life (37.5% students). The main cause 
of difficulty in learning is less availability of teaching materials in reproduction system content. 

Reproduction system content requires students to understand the reproduction system's anatomy 
structure, connect the reproduction organ structure and function, and explain various mechanisms that 
occurred in the reproduction system (Seeley, Tate, & Stephens, 2008). An active and creative contextual 
learning is thus required that involves students to find knowledge, collect data, test hypotheses, find new 
understanding, conduct skill practice, and obtain knowledge based on learning experiences (Buck, Latta, & 
Pelecky, 2007). The appropriate learning model is a guided inquiry equipped with research results. One of the 
basic efforts to apply the research results in the learning process is through laboratory practice methods 
(Llewellyn, 2013). 

Animal physiology learning in IKIP Budi Utomo Malang has not implemented a laboratory practice method. 
The most reasonable laboratory practice in reproduction system content to be conducted in IKIP Budi Utomo 
Malang is sperm observation. The phenomenon that occurred in daily life in a community is the discovery of 
many hyperlipidemia conditions. Hyperlipidemia has an impact on the decrease in sperm quality. Single clove 
garlic (Allium sativum) is one of the natural ingredients that could reduce hyperlipidemia; thus, it could improve 
sperm quality. Mice are used as a model animal in the hyperlipidemia research (Qadariah, Lestari, & Rohman, 
2020). 

The learning approach based on research results is expected to help students comprehend between 
theoretical studies available in teaching materials and the reality of the research results (Newton & Tonelli, 
2020; Pambudiono, Suarsini, & Amin, 2016). Learning using a guided inquiry model that contains research 
results requires teaching sources. The observation results indicate that lecturer and 97% of students choose 
the module. The lecturer choose the module since it is one of the learning sources to facilitate teaching, 
whereas students choose it because it could be an interesting and good learning guide, it uses a learning 
model, it improves understanding and interest to study, and it could be used independently as well as with 
lecturer guidance. The module could load a guided inquiry model syntax; thus, it could be used as a learning 
source. The guided inquiry learning model can improve science process skills (Ekici & Erdem, 2020; Graaf, 
Segers, & Jong, 2020) and cognitive learning outcomes (Cho, Kim, & Choi, 2017; Donohoe, 2019). 

The guided inquiry module based on the research results could teach students to find knowledge 
independently through experiments, observations, and deepening concepts. A module that contains a 
research result could provide new information for students (Parmin & Peniati, 2012). The guided inquiry 
module based on a research result is selected because it is one type of teaching material suitable for 
understanding and age levels and improves knowledge of theoretical review and daily life realities. 

Recent studies related to this study include inquiry module in the Finland (Mamun, Lawrie, & Wright, 2020; 
Thuneberg, Salmi, & Bogner, 2018), and in the United States (Zhang, 2019). Research related to inquiry and 
science process in Turkey (Ekici & Erdem, 2020). Research related to inquiry and cognitive learning outcomes 
in South Korea (Cho et al., 2017), and in United Kingdom (Kovanovic, Gasevic, Joksimovic, Hatala, & 
Adesope, 2015). Research related to guided inquiry module in animal reproduction system content to improve 
student science process skills and cognitive learning outcome has yet to be done. Thus, the study's improved 
outlook is that no one has yet developed guided inquiry module in animal reproduction system content to 
improve student science process skills and cognitive learning outcome. This research contributes to the field 
of education. These contributions include being able to become a reference module for educators in teaching 
reproductive system material. Another gift is that this module is also a reference for educators to develop 
scientific process skills and student learning outcomes when studying reproductive system material.  

According to the background, a guided inquiry module in animal reproduction system content will be 
developed. The developed module is based on researching the potential of single clove garlic (Allium sativum) 
extract on sperm quality of hyperlipidemia model of male mice to improve student science process skills and 
cognitive learning outcome. Development research aims to produce, test the validity, practicality, and 



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effectiveness of guided inquiry modules on animal reproductive systems to improve student science process 
skills and cognitive learning outcomes. 

 

METHOD 

The research was development research using the ADDIE model that consisted of 5 (five) stages: 
analysis, design, development, implementation, and evaluation (Branch, 2009). The analysis phase serves to 
find out various problems and needs during the learning process. The analysis phase is carried out by 
observing learning activities, interviews, and the provision of needs analysis questionnaire. In the analysis, the 
stage also set development objectives to produce and test the guided inquiry module's validity and practicality 
based on research results. The module development target is the student offering A Biology Department, IKIP 
Budi Utomo Malang, which will be held from May 2018 to December 2018. 

The design phase functions to design a guided inquiry module based on research results. At the design 
stage, a list of tasks to be designed in the guided inquiry module based on the research result, the display of 
the module objects, the validation questionnaire, and the practicality questionnaire (Qadariah, Lestari, & 
Rohman, 2019). 

The development phase serves to develop the module design result made at the design stage (Branch, 
2009). Stage of development includes the design of content in the module, including research results, the 
potential of single clove garlic (Allium sativum) extract on sperm quality of hyperlipidemia model of male mice. 
At the development stage, also used supporting media in doing module and making instructions for using the 
module. The module that has been developed is tested for validity b material experts, the media, and field 
practitioners. The material expert validator is Prof. Dr. Abdul Gofur, M.Si., and the media expert validator is 
Dr. Munzil, S.Pd., M.Si., validator od field practitioners namely Dwi Candra Setiawan, S.Si., S.Pd., M.Pd., and 
Nila Kartika Sari, S.Si, M.Si. Educational background and areas of expertise are the basis for selecting a 
guided inquiry module validator. After being declared valid by the module validator, it was tested on 15 
offering A students majoring in Biology IKIP Budi Utomo Malang who were taking Animal Physiology courses 
to test the practicality of the module. 

The implementation phase is carried out using guided inquiry modules in animal reproductive system 
material based on research results to improve science process skills and students' cognitive learning 
outcomes. Implementation of guided inquiry modules based on research results using a quasi-experimental 
design. The quasi-experimental research design chosen was the nonrandomized control group pretest-
posttest system (Leedy & Ormrod, 2016). The research designs are approved in Table 1. Information (1) O1= 
Pretest control class; (2) O2= Posttest control class; (3) O3= Pretest experiment class; (4) O4= Postest 
experiment class; (5) X1= Learning without using modules; (6) X2= Learning by using modules.  

 
Table 1. Research design nonrandomized control group pretest-posttest design 

Subject Pretest Treatment Postest 

Control (-) O1 X1 O2 

Experiment O3 X2 O4 

 

The research population is students who are taking IKIP Budi Utomo Malang animal physiology course. 
The sampling technique used is simple random sampling because the cognitive abilities of students are 
considered homogeneous. The study was conducted in class A as an experimental class (using the guided 
inquiry module based on the survey) as many as 40 students and class B as a control class (conventional 
methods without modules) as many as 40 students. 

The evaluation stage functions to find out the deficiencies in the module as a basis for module 
improvement. The evaluation phase is carried out at each stage of the previous ADDIE development (Branch, 
2009). The research instruments for collecting data included a material expert validation sheet by one material 
expert validator, a media expert by one media expert, a field practitioner expert by two field practitioners 
expert validator, a practicality questionnaire module for 15 students, a pretest-posttest question sheet 
validated science process skills and cognitive learning outcomes. 

The data analysis technique of guided inquiry module development research is quantitative and qualitative 
descriptions. Qualitative analysis is done by grouping information in the form of opinions, suggestions, and 
remedial comments from validators and students as practicality testing subjects. Quantitative data analysis for 
the validation questionnaire and practicality test uses the following Formula 1. 



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                                                                                (1) 

Percentage assessment data obtained were converted into descriptive quantitative data using the validity 
criteria shown in Table 2. This is intended to give meaning and make decisions about the quality of the 
product modules that are developed. Percentage assessment data obtained were converted into descriptive 
quantitative data using practical criteria shown in Table 3. This is intended to give meaning and make 
decisions about the quality of the product modules that are developed. 

 
Table 2. Research criteria data percentage of product validity 

No. Validity criteria (%) Level of validity 

1. 85.01  - 100.00  Very valid, or can be used 
2. 70.01  - 85.00  Valid enough, or can be used but needs a little revision 
3. 50.01%- 70.00  Invalid, it is recommended not to use it because it needs a lot of revisions 
4. 01.00 – 50.00 Invalid, or may not be used 

 
Table 3. Evaluation criteria for percentage of product practicality 

No. Practical criteria (%) Practicality 

1. 81.00 - 100.00 Very practical, or can already be used  
2. 61.00 - 80.00 Practical, or can be used but needs to be revised slightly 
3. 41.00 - 60.00 Less practical, it is recommended not to use because it needs a lot of revisions 
4. 21.00 - 40.00 Impractical or may not be used 
5. 00.00 - 20.00 Very impractical, may not be used 

 
Data analysis of science process skills and cognitive learning outcomes using non-parametric analysis 

techniques, namely quad’s rank analysis of covariance. Data analysis serves to test whether there are 
differences in the mean of bound variables between two groups by controlling other variables that affect the 
dependent variable. 

 

RESULTS AND DISCUSSION 

The development's end product was a guided inquiry module in animal reproduction system topics based 
on a research result. The module was a teaching material containing content unit made according to the 
learning achievement. The module guided planned learning that could be studied independently by students 
with or without teacher assistance. The module production's important components included content, student 
worksheet, question sheets, and critical answers (Mulyasa, 2006).   

The module compiled had been through analysis, design, development, implementation, and evaluation 
stages (Branch, 2009).  Questionnaire analysis of the needs of the reproductive system material for lecturers’ 
shows learning is done through the method of presentation and discussion, learning resources in the form of 
scientific articles, and effectively improving students' understanding of concepts. The results of the needs 
analysis questionnaire for lecturers also showed that the learning process had never used a guided inquiry 
module based on the study results. In addition to giving questionnaires, an interview was conducted at the 
lecturer. Interviews show that learning resources in the form of modules and scientific articles as learning 
resources are not yet available in all materials, such as in the reproductive system. Therefore we need 
learning resources on the fabric of the reproductive system. Subject lecturers strongly agree if a guided 
inquiry module is developed based on research results. This is very good as an innovation in education to 
facilitate educators during the learning process. Research results can also be an essential part of 
understanding the reproductive system and are useful for providing the latest information for students (Parmin 
& Peniati, 2012). 

Learning is done by presentation and discussion (87.9% of students) is the result of a questionnaire 
analysis of students' needs. But the use of specific learning models to increase interest and motivation to 
learn is the advice given by students. As many as 60.6% of students have difficulty in understanding the 
reproductive system because the material is abstract and complicated (25% students), concepts are 
understanding (20.8% students), difficult to apply in real life (12.5% students), and lack of availability of 
relevant teaching materials (37.5% students). The method used to overcome difficulties in the reproductive 
system material is finding other learning resources, asking the lecturer, and discussing with friends in one 



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class. In general, animal physiology learning has used various learning resources, but only limited to certain 
materials. During the learning process, 69.7% of students had never used a guided inquiry-based module, 
and 97% of students agreed to develop a guided inquiry module. The research objective is to produce a 
guided inquiry module based on research results on the reproductive system material for animal physiology 
courses that are valid, practical, and effective. The module will be implemented in Offering A Biology 
Department Student IKIP Budi Utomo Malang during animal physiology learning. The use of modules in the 
form of mold size B5. How to guide students in learning the reproductive system in modules through guided 
inquiry models. The result of the analysis stage can generally be inferred that a guided inquiry module in the 
reproduction system topic based on research results was needed to be developed to improve student science 
process skills and cognitive learning outcomes. 

The design stage was conducted by planning all components to be loaded in the module. Once the design 
was completed, the module was developed. At the design stage, prototype guided inquiry module design 
including arranging objects in the module. The module developed was expected to become an alternative 
learning source that helped students understand the reproduction system content. The core part of the 
module contained learning activities. The guided inquiry module based on research results consisted of three 
learning activities: learning activity one on reproduction organs, learning activity two on reproduction 
physiology, and learning activity three on fertilization, pregnancy, and labor. 

Each learning activity is complemented by the syntax of the inquiry model, namely the exploration of 
phenomena, focusing questions, planning investigations, conducting investigations, analyzing the results of 
studies, constructing new knowledge, and communicating knowledge (Llewellyn, 2013) designed in the form 
of student worksheets located at the beginning of each activity learn. The phenomenon loaded in each 
learning activity was the result of research conducted. The research results could provide a real learning 
experience for students (Parmin & Peniati, 2012; Tasir & Pin, 2012), improve students' understanding, and 
provide information about development and invention in content discussed. Besides, the research results 
were practice to be used in learning (Faot, Zubaidah, & Kuswantoro, 2016), improved learning quality and had 
adaptability to science and technology (Mahfudhillah, Al-Muhdhar, & Sueb, 2017). The research results were 
loaded in the module where the potential of single clove garlic (Allium sativum) extract on male mice sperm 
quality. The phenomenon of exploring phenomena serves to train the observing aspects of the science 
process skills (Llewellyn, 2013). 

Students are asked to write questions based on the phenomenon that has been explored. This activity 
aims to improve thinking skills and curiosity in the syntax of focusing problems. The focus phase of the 
question trains aspects of asking questions of science process skills (Conn, Bohan, Pieperc, & Musumeci, 
2020; Gultepe, 2016). Next, students are asked to plan an investigation. The investigation was carried out 
following the items that were formulated (Llewellyn, 2013). Investigating the syntax was loaded in a laboratory 
practice method in sperm calculation, motility observation, and sperm morphological normality. Students are 
asked to determine the data to be collected to answer questions. The planning phase of the investigation 
trains aspects of formulating hypotheses and planning the investigation of science process skills. 

The next activity analyzes the investigation results in the form of interpreting and interpreting data, looking 
for patterns and relationships between variables, modifying, and drawing initial conclusions. The purpose of 
analyzing the results of research is so that students can find answers to questions made. The stage of 
analyzing the results of an inquiry trains aspects of analyzing data from science process skills. The 6th syntax 
of student guided inquiry is asked to form new knowledge. Developing new knowledge is defined as new 
knowledge gained from the investigation results to answer the questions given. This activity aims to build a 
new understanding of students. The stages of forming unique knowledge train aspects of applying the 
concepts of science process skills. The syntax further communicates new knowledge. New knowledge is 
disseminated through explanations with oral reports, PPT, or other media needed. The purpose of this activity 
is for students to convey new knowledge gained. The stage of communicating unique knowledge trains 
aspects of communication in science process skills (Curtis, Brownlee, & Spooner-Lane, 2020; Martin, Sigur, & 
Schmidt, 2005). 

Each learning activity was ended with a formative test. The productive test was equipped with a critical 
answer so that students could measure their understanding independently following the module 
characteristics. The formative test was an essay question. The essay question was used since it has a better 
information function value (Susongko, 2010). Students were provided with the freedom to express 
understanding. It was useful to measure the achievement level of cognitive learning outcomes. The module's 
end part consisted of a summative test and the critical answer, glossary, and reference. The summative test 



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served to measure the overall student understanding of all content in the module. The dictionary helped 
students learn the definition of terms in the module and understand the concept being studied (Elfeky, 
Masadeh, & Elbyaly, 2020; Faot et al., 2016; Post, Guo, Saab, & Admiraal, 2019; Ucar & Trundle, 2011). 

The development phase includes designing content, developing supporting media, developing user 
manuals for students and lecturers, making formative revisions, and conducting preliminary trials (Branch, 
2009). At the development stage, module validation is performed. The content expert, media expert, and field 
practitioner expert validated the developed inquiry module based on a research result. The validation was 
intended to determine the module's weaknesses and be used as a material for improvement and produce a 
module suitable to student needs. 

The material expert validator is Dr. Abdul Gofur, M.Si. The validator is a physiology lecturer at the 
Department of Biology FMIPA UM, who has a research background in reproductive systems. The material 
expert validator's validation results stated that the modules from aspects of content worthiness, presentation 
of content worthiness, and language worthiness were very valid and could be used in learning. The module's 
strength is that it can help understand the reproductive system and as additional teaching material in the 
teaching and learning process. Therefore the module can be used in learning with revisions (Akbar, 2013).  
The content expert's validation value category was 94.84, with an excellent variety for all validation aspects. 
The module expert validation questionnaire consisted of three major components: the element of content 
eligibility, which included 12 points of evaluation, the feasibility of presenting content with 10 points of 
assessment, and language eligibility, which had 9 points of evaluation. A summary of the results of the 
material expert validation results can be seen in Table 4. 

 
Table 4. Value of material expert validity 

No. Rated aspect 
Number of 

aspects 
Maximum 

score 
Earnings 

score 
Validity 

value (%) 
Validity category 

1. Content eligibility 12 60 57 95 Very valid 
2. Feasibility of content 

presentation 
10 50 49 98 Very valid 

3. Language feasibility 9 45 41 91.11 Very valid 

 Earnings score 31 155 147 94.84 Very valid 

 

A product suitable for learning must be valid regarding its content feasibility, content presentation, and 
language feasibility aspects. Content loaded in the module must be correct, right, and thorough. The 
validation criteria of the content expert indicated the correctness of the content substance in the module. The 
media expert validator is Dr. Munzil, S.Pd., M.Si. The validator is a lecturer in education in the Department of 
Natural Sciences FMIPA UM. The validation results by the validator of the media experts stated that the 
modules from the aspects of graphics, presentation, linguistics, and modules have been very valid and can be 
used in learning. The module is suitable to be used as a learning resource. The advice given by the validator 
is to pay attention to the distance between paragraphs. Therefore the module can be used in learning with 
small revisions.  A summary of the results of the validation of media experts can be seen in Table 5. 

 
Table 5. Value of media expert validity 

No. Rated sspect 
Number of 

sspects 
Maximum 

score 
Earnings 

score 
Validity 

value (%) 
Validity category 

1. Grapefruit 10 50 44 88 Very valid 
2. Presentation 7 35 33 94.29 Very valid 
3. Linguistic 6 30 28 93.33 Very valid 
4. Module 14 70 66 94.29 Very valid 

 Earnings score 37 185 171 92.43 Very valid 

 

A good module had an attractive appearance with a combination of color, figure shape, and clear title. The 
module's language aspect must use an easy to understand language and the correct spelling (Akbar, 2013). 
Validator expert field practitioners, namely Dwi Candra Setiawan, S.Si., S.Pd., M.Pd. (validator 1) and Nila 
Kartika Sari, S.Si., M.Si. (validator 2). The validator is a lecturer in animal physiology courses at IKIP Budi 
Utomo Malang. The expert field validator's validation results stated that the modules from aspects of language 
feasibility, content eligibility, presentation feasibility, and guided inquiry were very valid. Field practitioner 
expert validator 1 gave some comments, the language used is good. Still, some writing needs to be improved. 
The content worthiness is excellent, but it needs to add the initial narrative to each sub-chapter to facilitate 
student understanding. The feasibility of presentation and guided inquiry is very good. Field practitioner expert 



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validator 2 commented that the use of the language used was following EYD and the level of understanding of 
students' thinking. The material presented was feasible and pursued learning outcomes, but it would be better 
to add fertility period calculation material to the menstrual cycle. Therefore the module can be used in 
learning. A summary of the results of the field practitioner expert validation results can be seen in Table 6. 

 
 

Table 6. Validity value of field practitioner expert 

No. Rated aspect 
Number of 

aspects 
Maximum 

score 
Earnings 

score 
Validity 

value (%) 
Validity category 

1. Language feasibility 7 35 32 91.53 Very valid 
2. Content eligibility 5 25 24 96 Very valid 
3. Feasibility of presentation 10 50 48.5 97 Very valid 
4. Guided inquiry 8 40 39 97.5 Very valid 

 Earnings score 30 150 143.5 95.67 Very valid 

 
 

The development phase is carried out as a preliminary trial to determine the practicality of the module. The 
preliminary trial was conducted on 15 students who were taking IKIP Budi Utomo Malang animal physiology 
course. The preliminary trial category is divided into four aspects of assessment, including student interest, 
use, activeness, and evaluation. A summary of the results of practicality data analysis can be seen in Table 7. 

 
 

Table 7. Student response data on guided inquiry module 

No. Rated aspect Score Practicality category 

1 Attractive module display 90.67 Very practical 
2 Modules motivate to learn 90.67 Very practical 
3 Attractive module color choices 89.33 Very practical 
4 The material in the module is easy to understand 86.67 Very practical 
5 Modules can guide finding concepts 88.00 Very practical 
6 The material in the module relates to everyday life 89.33 Very practical 
7 Modules motivate to discuss 97.33 Very practical 
8 Modules help improve scientific thinking 88.00 Very practical 
9 Modules help independent learning 97.33 Very practical 
10 Modules make learning more effective 88.00 Very practical 
11 Modules increase learning activities 92.00 Very practical 
12 Practical modules are used in learning 89.33 Very practical 
13 Modules make learning not boring 86.67 Very practical 
14 Module languages are easy to understand 92.00 Very practical 
15 The letters used are easy to read 96.00 Very practical 
16 The picture presented clarifies the concept  96.00 Very practical 
17 Evaluations in modules can be a benchmark in 

understanding the material od the animal reproductive 
system 

94.67 Very practical 

Amount 1164 Very practical 

Validity value 9.29  

 
 

A valid and practical module would be used in the learning process.  The results of modules that have 
been valid and practical can be seen in Figure 1 dan Figure 2. 

The implementation phase is carried out using guided inquiry modules on reproductive system material 
based on research to improve students' science process skills and cognitive learning outcomes in learning. 
The result of data analysis suggested that there was a significant difference between students who learned 
using the module and those who did not use the module. The guided inquiry module in animal reproduction 
system topics based on a research result was developed to improve student science process skills and 
cognitive learning outcomes. 

The result of hypothesis testing using Quade’s rank analysis of covariance suggested a difference in 
science process skills between students in the experimental class and control class. Hypothesis test results 
can be seen in Table 8. The learning outcome in the experimental class was significantly higher than the 
control class. It implied that the guided inquiry-based module in the reproduction system content based on a 
research result could improve students’ science process skills. 

 
 



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Figure 1. Front and back cover of the module 
 

  
 

Figure 2. Guided inquiry learning syntax in modules 
 

 

Table 8. Summary of final results of the quade’s rank analysis of covariance science process skills 

 Sum of squares dF Mean square F Sig. 

Between groups 9098.994 1 9098.994 42.509 .000 
Within groups 16695.944 78 214.051   

Total 25794.938 79    

 
Students in the experimental class used an inquiry-based module based on a research result in the 

learning while learning in the control class was conventional using presentation and lecture methods. Efforts 
to improve science process skills in the module were trained through student worksheets that contained a 
guided inquiry model learning syntax. Student activities in the student worksheet were based on an inquiry 
syntax, namely: exploring the phenomenon, focusing questions, planning an investigation, conducting 
research, analyzing the investigation result, constructing new knowledge, and communicating the experience. 

Each of the inquiry learning model stages trained a specific aspect of science process skills. The first 
syntax in the guided inquiry, exploring the phenomenon, trained the observing aspect. The second syntax, 
focusing on the phenomenon, trained the asking question aspect. The third syntax, planning an investigation, 
trained two aspects of the science process skills: planning an investigation and formulating a hypothesis. The 
fourth syntax, conducting research, trained two aspects of the science process skills: using tools and 
materials, and conducting an experiment. The fifth syntax, analyzing the investigation result, trained the data 
analysis aspect. The sixth syntax, constructing new knowledge, trained the implementing concept aspect. Last 



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but not least, the seventh syntax, communicating the knowledge, trained the communicating aspect of the 
science process skill.  

Stages in the inquiry learning model syntax have proven effective in improving science process skill 
aspects. There were differences in the value of each science process skill aspect measured. The average 
value of (1) observing aspect was 75; (2) asking question aspect was 79.4; (3) formulating hypothesis aspect 
was 90; (4) planning an investigation aspect was 60; (5) using tools and materials aspect was 87; (6) 
conducting an experiment aspect was 75.6; (7) analyzing data aspect was 71.2; (8) applying a concept aspect 
was 75, and (9) communicating aspect was 97.5. Based on the values of the science process skill aspects, 
each syntax of the guided inquiry model was generally capable of improving students’ science process skills. 
The syntaxes that had the most significant influence in improving students’ science process skill included: (1) 
focusing questions syntax that trained to ask question aspect of the science process skill; (2) conducting 
investigating syntax that trains using tools and materials aspect, and (3) communicating syntax that trained to 
communicate an aspect of the science process skills. 

The result of hypothesis testing using Quade’s rank analysis of covariance indicated an influence on 
students' cognitive learning outcomes in the experimental and control classes. Hypothesis test results can be 
seen in Table 9. 

 
Table 9. Summary of final results of the quade’s rank analysis of covariance cognitive learning outcomes 

Model Sum of squares dF Mean square F Sig. 

1 Regression 3726.481 1 3726.481 7.480 .008b 
Residual 38858.519 78 498.186   
Total 42585.000 79    

 
The learning outcome in the experimental class was significantly higher than in the control class. It 

suggested that the guided inquiry module based on a research result could improve student cognitive learning 
outcomes. Learning in the experimental class used an inquiry module based on a research result, whereas 
learning in the control class used a conventional way using presentation and lecture methods. They were 
learning using an inquiry module based on a research result guided students to have more experience than 
traditional learning. An inquiry model involves students to learn actively (Acar, 2014; Llewellyn, 2013; Warin, 
Kolski, & Sagar, 2011). Efforts to improve the module's cognitive learning outcome were conducted through 
LKM, content description, and formative tests in each learning activity. 

The inquiry learning model syntax loaded in the student worksheet was designed to facilitate the 
improvement of student cognitive learning outcomes. The exploring phenomenon and focusing question 
syntax facilitated cognitive level 2 (C2) or understanding. In both syntaxes, students were trained to construct 
an understanding related to reproduction system content. The syntaxes had proven to be able to improve 
students’ cognitive level 2 (C2) value. The planning of an investigation syntax facilitated the improvement of 
cognitive level 4 (C4) or analysis. Conducting an investigation, constructing new knowledge, and 
communicating the knowledge syntax facilitated cognitive level 3 (C3) or applied. The analysis investigation 
result syntax facilitated the improvement of cognitive level 5 (C5) or evaluation. 

Stages in the inquiry learning model syntax have proven effective in improving students' cognitive learning 
outcomes. There was a difference in value in each cognitive level measured. The average value of cognitive 
level 2 (C2) or understand was 75.4, the cognitive level 3 (C3), or applied was 73, the cognitive level 4 (C4) or 
analysis was 71.2, and the cognitive level 5 (C5) or evaluated was 70. The average value of each cognitive 
level suggested that the higher the cognitive level measured, the lower the students' average value. The 
difference in each cognitive level value, however, was not significant. It can be inferred, thus, that learning 
using a guided inquiry-based module could improve the cognitive level of understanding (C2), apply (C3), 
analyze (C4) and evaluate (C5). The guided inquiry emphasized the investigation so that students could find 
new knowledge independently, and it could be an effort to improve student cognitive learning outcomes (Yuni 
Pantiwati, Permana, Kusniarti, & Miharja, 2020; Uiterwijk-Luijk, Kruger, Zijlstra, & Volman, 2019). 

The improvement of students' cognitive learning outcomes is also related to improving students' science 
process skills.  Students who learned using a guided inquiry-based module in the reproduction system content 
indicated improved science process skills and cognitive learning outcomes due to the developed module that 
was constructive (Kefi & Uslu, 2015; Ozgelen, 2012; Pantiwati, Permana, & Kusniarti, 2020). It provided many 
learning experiences to conduct an investigation and guided students to solve the phenomenon given. 
Students who had learning experience using a guided inquiry-based module in the reproduction system based 
on a research result improved their science process skills and cognitive learning outcome. 



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CONCLUSION 

A guided inquiry module based on a research result was very valid and practical. The content expert's 
validation result was 94.84%, the media expert was 92.43%, and the field practitioner expert was 95.7% with 
a very valid category. The result of module practicality was 91.3%, with a category of very practical. There 
was a significant difference in the science process skills between students who learned using a guided inquiry 
module in the animal reproduction system based on a research result and those who did not use it. The 
module could improve students’ science process skill with Fcalculate of 42,509 and p-value = 0.000< α (α = 
0.05). There was a significant difference in the cognitive learning outcome between students who learned 
using a guided inquiry module in the animal reproduction system topic based on a research result and those 
who did not use the module. The module could improve students’ cognitive learning outcome with Fcalculate 
of 7.480 and p-value = 0.008 < α (α = 0.05). 

Suggestions that can be given for research related to this are observation sheet is a necessity to further 
assess the student science process skills, research is needed related to woman reproduction system so that it 
could become additional research results to be loaded in the module, an implementation is required to find out 
the influence of the module on related variables other than students’ science process skill and cognitive 
learning outcome. 

 

ACKNOWLEDGMENT 

The research was a part of a research project by Dr. Sri Rahayu Lestari with decree 188/SP2H/LT/DRPM, 
the contract number 19.3.81/UN32.14.1/LT/2019. The researchers would like to send their gratitude to all 
research group members. 

 

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