Universitas Muhammadiyah Malang, East Java, Indonesia 

 

JPBI (Jurnal Pendidikan Biologi Indonesia) 
 

p-ISSN 2442-3750, e-ISSN 2537-6204 // Vol. 7 No. 1 March 2021, pp. 1-10  

 

 

        10.22219/jpbi.v7i1.15468                              http://ejournal.umm.ac.id/index.php/jpbi                     jpbi@umm.ac.id  1 

Research Article 

Filipino prospective teachers’ experiences in teaching in 
K12 science curriculum: A cross-sectional research  
 

Ace Mark R. Antipolo a,1, Danilo V. Rogayan Jr. a,2,* 
a College of Teacher Education, President Ramon Magsaysay State University, Zambales 2207, Philippines  
1 aceantipolo28@gmail.com; 2 danrogayan@gmail.com* 

* Corresponding author 

 

INTRODUCTION 

A myriad of concerns continues to hamper the advancement of biology education in the different parts of 
the globe (Rogayan & Albino, 2019). The role of universities and colleges is very indispensable in promoting 
quality biology education and science education in general. Teacher education institutions (TEIs) are tasked to 
develop future teachers proficient in the science content and well-versed in their pedagogy. The new teachers 
would better understand effective pedagogical approaches if their pre-service training has equipped them with 
enough experience. They should be equipped with the indispensable skills to be able to effectively contribute to 
the development of functionally-literate and scientifically-minded citizens (Laguatan & Abad, 2019). In 

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

 

Article history 
Received: 4 February 2021 

Revised: 8 March 2021 

Accepted: 11 March 2021 

Published: 29 March 2021 

 The K12 science curriculum in the Philippines uses spiral progression which is a 
concept of learning approach where students revisit the same topics throughout their 
school career that increases complexity and reinforcement of previous learning. This 
cross-sectional study determined the experiences of Filipino prospective science 
teachers (PSTs) specializing in biology and physical science in teaching in the K12 
science curriculum with emphasis of their challenges. The respondents of this study 
were 30 PSTs in five teacher education institutions (TEIs) in Central Luzon, Philippines. 
Results revealed that the PSTs rarely experience teaching challenges in the K12 
science curriculum in terms of content knowledge and pedagogy, learning environment, 
diversity of learners, curriculum and planning, assessment and reporting, community 
linkages and professional engagement, and in personal growth and professional 
development. No significant differences were noted in the challenges of PSTs when 
grouped according to profile variables. A positive significant moderate to high 
correlations were noted between and among the challenges variables. The study 
suggests that the administration continuously spearhead in-house seminars and equip 
prospective teachers with innovative teaching strategies. TEIs may also consider 
curriculum review to align the course syllabi in the teacher education curriculum to the 
Department of Education curriculum. Schools may further evaluate the policies, 
standards, and guidelines of the teacher education curriculum to make the science 
education degree programs relevant. 

 
Copyright © 2021, Antipolo & Rogayan  

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

    

 

 
Keywords 
Cross-sectional survey 

Experiences in K12 curriculum  

K12 science curriculum  

Science education  

Science prospective teachers 

 

  

 
How to cite:  Antipolo, A. M. R., & Rogayan, D. V. Jr. (2021).  Filipino prospective teachers’ experiences in teaching in K12 science 

curriculum: A cross-sectional research. JPBI (Jurnal Pendidikan Biologi Indonesia), 7(1), 1-10. doi: https://doi.org/10. 
2022219/jpbi.v7i1.15468 

 

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consonance, TEIs are challenged to develop globally-competitive, technologically-literate and value-laden 
would-be science teachers.  

Globally, the Philippines lags behind compared to its neighboring countries in terms of education quality, 
particularly in science education (Rogayan & Dollete, 2019). According to the 2018 Programme for International 
Student Assessment (PISA) 2018, the Philippines scored 353 in Mathematics, 357 in Science, and 340 in 
Reading, all below the average of participating countries (Department of Education [DepEd], 2019). The results 
were significantly lower than the Organization for Economic Co-operation and Development (OECD) average of 
487 points. PISA evaluation is comprised of three basic dimensions, literacy in reading, literacy in mathematics, 
and literacy in science. In high performing countries like Brunei, Australia and other first-world countries, they 
apply integrated approach and spiral progression. As Asian nations aspire to join the developed nations, some 
countries like Malaysia and Singapore implemented the spiral curriculum to establish global competency in the 
educational system.  

In the school year 2012-2013, the K12 curriculum has been implemented. The curricular change in 
education resulted in congestion in the basic education curriculum. Thus, the government implemented the 
Republic Act 10533, also known as the K12 program for public and private institutions for the enactment of the 
spiral curriculum. The current curriculum, which uses spiral progression approach, provided a range of 
competencies to the learners in a knowledge-based and world of work civilization. It aims for the progress of 
environmentally, scientifically and technologically educated and prolific community of people who can solve 
serious problems, accountable users of environment, productive citizens, informed legislators, and effective 
communicators (K12 Science Curriculum, 2016).  

In the Philippines, the spiral curriculum in science presents the concepts and skills in all the branches of 
science including biology, chemistry, physics, and earth science, with increasing complexity levels from one 
grade level to another in spiral progression, thus the concrete way to a better understanding of core concepts. 
The incorporation of science across subjects and other disciplines will lead to meaningful learning in the 
concepts and their purpose in real-life situations. However, prospective teachers, especially those majoring in a 
specific discipline like biological sciences and physical sciences, face difficulties in teaching in a spiral 
curriculum since the science content is integrative. Mizzi (2013) supported this claim, which stated that the 
mismatch to the area of specialization offers considerable challenges, especially in the lesson planning; 
therefore, the teaching-learning process will later be affected due to lack of information. Teacher’s lack of 
expertise in the subject will affect their confidence manifested in different ways including lesson planning, 
answering the questions of students, proper set up of laboratory activities, involving and applying the concepts 
and principles to everyday life situations, generating the students' interest and excitement for the science area. 

Local studies regarding K12 science curriculum have been extensively done. These studies focused on the 
teachers’ and students’ perception on the implementation of the curriculum (Acosta & Acosta, 2017; Montebon, 
2014), the assessment of the curriculum (Cabansag, 2014; Rivera, 2017; Sañosa, 2013), spiral progression 
approach in teaching science (De Ramos-Samala, 2018; Dunton, 2015; Gonzales, 2019; Maing et al., 2019; 
Mangali et al., 2019; Orbe et al., 2018; Resurreccion, & Adanza, 2015), preparedness and self-efficacy of 
teachers in teaching in K12 science curriculum (Sakib & Obra, 2019; Walag et al., 2020), and the philosophical 
foundation of science education in the country (Miranda, 2014). Likewise, previous studies on science 
prospective teachers focused on their experiences in teaching beyond their specialization (Montebon, 2015), 
reasons for choosing general science as majorship (Manalansan et al., 2020), self-efficacy of prospective 
teachers (Aure & Jugar, 2017), science laboratory interest and preferences (Antonio, 2018), preservice science 
teacher preparation and education (Handa, 2012; Handa & Tippins, 2013), and technology integration in 
teaching science (Mercado et al., 2019).  

The biology and physical science prospective teachers' challenges in teaching in the K12 science 
curriculum need to be properly addressed to increase their teaching proficiency. With the current curriculum's 
spiral progression approach, the mastery of knowledge and skills after each level of the students will be 
ensured. With effective prospective teachers, quality of teachers who will teach in the field will be attained. The 
quality of teachers in the Philippines is also anchored on the Philippine Professional Standards for Teachers 
(PPST). PPST is a standardized measure to assess teacher performance, identify their needs, and provide 
support for professional development (Department of Education, 2017).  

Hence, the researchers conducted this study to explore the experiences of the prospective science 
teachers (PSTs) in teaching in K12 science curriculum. This paper is the first attempt to document the 
challenges of the PSTs in the spiral progression approach in the Philippine K12 curriculum based on the 
framework of the PPST which can be an important literature to further understand prospective teachers’ 
challenges in other specializations.   



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METHOD 

The study utilized a descriptive cross-sectional research. This research surveyed the challenges 
experienced by biology and physical science preservice science teachers in teaching in the K12 science 
curriculum. A descriptive survey was used to distinguish a condition, people, action, or phenomenon. According 
to Atmowardoyo (2018), descriptive research is used to describe the existing phenomena as accurately as 
possible and these phenomena are already available. The most common descriptive research method is the 
survey, which includes questionnaires, personal interviews, phone surveys, and normative surveys. 

The respondents of this study are the preservice science teachers in five teacher education institutions in 
Central Luzon, Philippines (Table 1). The respondents were chosen through stratified random sampling. 
Stratified random sampling is a method of sampling that involves the division of a population into smaller 
groups known as strata. In stratified random sampling, the strata were formed based on members’ shared 
attributes or characteristics. These subsets of the strata were then pooled to form a random sample.  

Table 1. Distribution of respondents 

School Classification Frequency Percentage (%) 

TEI A SUC 7 23.33 
TEI B SUC 9 30.00 
TEI C Private HEI 8 26.67 
TEI D Private HEI 2 6.67 
TEI E LUC 4 13.33 

Total  30 100.0 

 

where TEI: Teacher Education Institution, SUC: State University and College, HEI: Higher Education Institution, 
and LUC: Local University and College. As shown, the study involved two teacher education institutions from 
state universities and colleges (SUCs), two private higher education institution (HEIs), and one local college 
and university (LUC).  

Table 2 shows the profile of the science preservice teachers. 
 

Table 2. Profile of the science preservice teachers 

Profile Frequency Percentage (%) 

School Private 10 33.33 
Public 20 66.67 
Total 30 100.0 

Age 19-20 12 40.00 
21-22 12 40.00 
23-24 2 6.67 
25-above 4 13.33 
Total 30 100.0 

Sex Male 12 40.00 
Female 18 60.00 
Total 30 100.0 

Civil status Single 27 90.00 
Married 3 10.00 
Total 30 100.0 

Specialization BSEd Biological Science 23 76.67 
BSEd Physical Science 7 23.33 
Total 30 100.0 

Grade level handled* Grade 7 10 33.33 
Grade 8 13 43.33 
Grade 9 13 43.33 
Grade 10 13 43.33 
Grade 11 4 13.33 
Grade 12 8 26.67 

*multi-response 

 
As shown in the Table 2, most of the respondents enrolled in public education institutions like state 

universities and colleges (SUCs) and local universities and colleges with 20 or 66.67% while 10 (33.33%) 
enrolled in private higher education institutions (HEIs). Out of 30 respondents,12 (40.00%) is in the age of 19-
20 and 21-22, two or 6.67% are aged 23-24 and 4 or 13.33% are 25-above. This shows that a typical science 
preservice teacher is at their early 20s. 



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Out of 30 science preservice teachers, 18 or 60.00% are female and 12 or 40.00% are male. The result 
shows that there is a greater number of female respondents. This confirms with the trend that teaching is a 
female dominated profession. A majority (27 or 90.00%) are single and only few (3 or 10.00%) are married. 
The result shows that the greater number of respondents are single. Majority (23 or 76.67%) are biological 
science majors and 7 or 23.33% are physical science major. This implies that majority are takers of biological 
science majorship. A total of 13 (43.33%) handled Grade 8, 9 and 10, 10 (33.33%) handled Grade 7, 8 
(26.67%) handled Grade 12 and 4 (13.33%) handled Grade 11. The result shows that the greater number of 
respondents handled Grade 8, 9 and 10. 

The Challenges in Teaching K12 Science Curriculum questionnaire (CTK12SCQ) developed by the 
researchrs served as the main instrument in gathering the data. The survey tool is a researcher-made 
questionaire based from the Philippine Professional Standards for Teachers (Department of Education, 2017). 
The first part consists of the demographic profile of the participants. The profile of the preservice science 
teachers include age, sex, civil status, specialization and grade level handled. The second part assessed the 
challenges experienced by the preservice science teachers during their practice teaching which consists of 37 
items, which, include content knowledge and pedagogy (7 items); learning environment (6 items); diversity of 
learners (5 items); curriculum and planning (5 items); assessment and reporting (5 items); community linkages 
and professional engagement (4 items), and personal growth and professional development (5 items). 

The survey questionnaire was subjected to construct and content validity. Three experts were tapped to 
check the consistency of the items in each variable. A total of 10 preservice teachers who were not part of the 
study were asked to answer the survey questionnaire for pilot testing. The responses were processed and 
was subjected to a reliability test. The Cronbach alpha value of the questionaire was 0.80 to 0.99 which 
indicated high-reliability index that allowed the questionnaire to be used in the study. 

After developing the research questionnaire and validation of four experts, the researchers asked 
permission from school administrators of the four higher education institutions to conduct the survey. All the 
PSTs were involved in the data gathering and the informed consent was secured before they answered the 
questionnaires. The research survey was floated to 30 prospective teachers. Retrieval of the survey tools was 
done on the same day.  

The computer software SPSS version 20 and MS Excel 2013 were used for the processing of data. The 
statistical tools which used in the analysis and interpretation of data and hypotheses were fequency count, 
percent, weighted mean, analysis of variance (ANOVA) and Pearson-r correlation.  

The researchers followed strict ethical protocols in the conduct of this study. The respondents’ names 
were not mentioned in any part of this research. The respondents were not  emotionally or physically harmed 
in the duration of the survey. Coding scheme was used in identifying the subjects of the study. Proper in-text 
and reference citation were followed in the preparation of the research article. Prior approval of the authorities 
was secured before conducting the survey to the intended respondents. 

RESULTS AND DISCUSSION 

Table 3 shows the challenges experienced by science prospective teachers (PSTs) in seven domains. As 
shown in the table, the respondents rarely encounter challenges in teaching in K12 science curriculum using 
spiral progression approach based on the overall mean of 2.19 (SD= 0.59).  

 
Table 3. Challenges experienced by prospective teachers 

Indicators m sd Description 

1. Content knowledge and pedagogy 2.36 0.54 Rarely 
2. Learning environment 2.11 0.50 Rarely 
3. Diversity of learners 2.09 0.61 Rarely 
4. Curriculum and planning 2.27 0.60 Rarely 
5. Assessment and reporting 2.06 0.65 Rarely 
6. Community linkages and professional development 2.44 0.65 Rarely 
7. Personal growth and professional development 2.01 0.60 Rarely 

Total 2.19 0.59 Rarely 

 
The highest means were obtained in community linkages and professional development (M= 2.44, SD= 

0.65), content knowledge and pedagogy (M= 2.36, SD= 0.54) and curriculum and planning (M= 2.27, SD= 
0.60). This implies that the PSTs rarely experience difficulties in linking with parents and community people, 
mastering their content matter and instructional approaches, and designing their learning plans.  



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The lowest means were obtained in the domains of learning environment (M= 2.11, SD= 0.50), diversity of 
learners (M= 2.09, SD= 0.61), assessment and reporting (M=2.06, SD=0.65), and personal growth and 
professional development (M= 2.01, SD= 0.60). This suggests that the respondents likewise do not encounter 
challenges in designing their learning spaces, dealing with a multitude of learners, evaluating the learners 
through varied tools and techniques, and furthering their skills and capabilities as prospective science 
teachers.  

In content knowledge and pedagogy, the respondents seldom face difficulties in the use of English in 
teaching science, positive use of ICT in science classes and in developing critical and creative thinking among 
students. The teachers’ subject content knowledge is a prerequisite to effective teaching practice. Even if 
teachers are aware of the dynamic forces and intricacy of living systems in biology and geography, they might 
not deliver its relevance to the students effectively (Rosenkranzer et al., 2017). 

The respondents also rarely face problems in the learning environment. They can employ positive and 
non-violent discipline in dealing with learner action. Also, they understand well the learning environments that 
uphold equality, reverence, and care to inspire learning. If teacher educators are prepared to support the 
education of students, it is imperative to know the interest of the students. Students have different preferences 
when acquiring knowledge in education (Plackle et. al., 2014). 

As to diversity of learners, PSTs barely experience challenges in utilizing science teaching strategies that 
are responsive to students’ various backgrounds. They were also well-versed in selecting inclusive teaching 
strategies that cover marginalized groups like the indigenous groups and learners with disabilities. The result 
is supported by the study of Beutel and Tangen (2018) that emphasized that the consensus of curriculum 
offered in teacher education has a significant impact in developing the competencies of future teachers, the 
greatest challenge is how to give them enough experiences to teach in the future effectively. 

In terms of curriculum and planning, the respondents rarely struggle in identifying learning objectives that 
are aligned with science learning competencies and using a variety of teaching and learning resources. Hsu 
(2017) stated that many subjects in teacher education programs for prospective teachers, including content 
and methodology subjects, draw on conventional and lecture-delivered approaches. In contrary, the results 
show that the PSTs rarely experience difficulty in curriculum and planning that indicates a good curriculum 
offered in the teacher education. 

The prospective teachers do not often experience challenges in understanding the role of assessment 
data as feedback mechanisms to improve practice, develop programs and inform policies. Likewise, the PSTs 
are good at monitoring and evaluating the students’ progress and achievement using assessment data.  
Assessment is critical in the teaching-learning process. Through proper assessment, teachers will be able to 
classify students accordingly (Tosuncuoglu, 2018). The result is also supported by the study of Khosravi and 
Cooper (2018), which emphasized that the application of assessment for different offerings of a curriculum 
(within or across terms), providing significant response about student achievements, and the track of student 
development over time is all challenging job. 

In terms of community linkages and professional development, the respondents rarely encounter 
challenges. PSTs infrequently experience low participation of school community and parents in science-
related activities. It is also evident that the prospective teachers have awareness of the rules and regulations 
applicable to the profession where they are in. Parents and teachers' good relationships can develop the 
teachers’ perception and perspective of students' specific character such as family background and learning 
needs (Thijs & Eilbracht, 2012). The results show that science preservice teachers have high engagements to 
parents which led to high engagement of the community in science learning. This conforms to the study of 
Mautone et al (2015), which emphasized that understanding facilitates greater individualization of support that 
educators give to learners and families will also reduce the negative prejudices on the part of educators 
toward learners and families. The future teachers were aware of the crucial importance of parental 
involvement in students’ academic development and achievements. The student teaching practice contributed 
significantly to their current level of parental involvement training and an awareness of varied family patterns 
(Sukhbaatar, 2018).  

Likewise, the respondents rarely encounter challenges in terms of personal growth and professional 
development. They do not experience difficulties in applying practices that sustain the dignity of science 
teaching as a vocation. They also exhibit well learner-centered teaching philosophy. Akhmetova et al (2016) 
emphasized that the would-be teachers must be ready for ethical and spiritual growth of high-school students 
in the context of holistic manifestation of all facets of personality. Additionally, TEIs must be aggressive in 



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implementing programs and activities that will develop prospective teachers’ personal growth and professional 
development (Reusia et al., 2020).  

Based on the independent sample t-test, there is no statistically significant difference between the 
challenges experienced of private/public science preservice teachers. Although not significant, science 
preservice teachers from public have greater challenges than the private school counterparts in terms of 
content knowledge and pedagogy and learning environment. Though not significant, science preservice 
teachers from private have greater challenges than their public-school counterparts in terms of diversity of 
learners.  

There is no significant difference between private and public school in terms of challenges in mastery of 
subject matter content in contrary to the findings of the study of Turkcapar (2015) which highlighted that there 
is a significant difference in school variable favored to public schools in terms of orientation and mastery. 
Likewise, there were no statistically significant differences at the 0.05 level of significance in the challenges 
mean scores of the respondents by age. There is no sufficient evidence to show statistically significant 
differences in the respondents’ challenges by age which is probably due to the small sample size taken or 
might be due to the large error of measurement. Moreover, there were no significant differences between the 
means of the challenges of science preservice teachers by sex. Although not significant, female respondents 
faced greater challenges compared to the male respondents in all domains.  

There were also no significant differences between the challenges of science preservice teachers by civil 
status. Regardless of being single or married, prospective teachers experience the same level of challenges. 
This confirms the findings of Elom and Egba (2015) that marital stress will not affect the job satisfaction of 
women teachers. it was concluded that marital stress could not predict job satisfaction among married women 
teacher. This implies that a teacher's civil status does not contribute to teachers' performances that might later 
affect their capability in teaching. This also indicates that the civil status cannot be considered a factor that 
affects a teacher's effectiveness whether he or she is married or not. 

Lastly, there existed no significant differences between the means of science preservice teachers' 
challenges according to specialization and grade level handled. This implies that whether the PSTs specialize 
in biological science or physical science, they have experienced the same level of challenges. In relation, 
Mizzi (2013) concluded that there are substantial differences when teaching within and beyond areas of 
specialization. Teachers are more confident when they teach in the area of their expertise.  

Table 4 shows the relationship among the variables of the challenges of science preservice teachers in 
teaching in K12 science curriculum. As gleaned from the Table 4, inter-correlations among all dimensions of 
challenges in teaching spiral curriculum in science are positive and significantly correlated. There is a low to 
very high correlations between and among the dimensions of challenges experienced by the prospective 
teachers. This suggests that as one dimension of challenge increases, another corresponding dimension will 
likely increase. 

 
Table 4. Correlation between respondents’ challenges of science preservice teachers in teaching in K12 science curriculum 

Variables 1 2 3 4 5 6 7 

1. Content knowledge and 
pedagogy 

–       

2. Learning environment 0.717** –      
3. Diversity of learners 0.629** 0.779** –     
4. Curriculum and planning 0.834** 0.756** 0.695** –    
5. Assessment and reporting 0.779** 0.633** 0.684** 0.871** –   
6. Community linkages and 

professional engagement 
0.745** 0.587** 0.590** 0.745** 0.708** –  

7. Personal growth and 
professional development 

0.473** 0.531** 0.622** 0.611** 0.709** 0.690** – 

**Correlation is significant at the 0.01 level (2-tailed) 
*Correlation is significant at the 0.05 level (2-tailed) 

 
Equipping the would-be science teachers with the necessary skills, attitudes and values with the support 

of their family, mentors and school administration, would minimize the challenges they encounter in their 
preservice education. Science prospective teachers should be equipped with the necessary knowledge and 
skills in pedagogy, assessment, teaching material development, classroom-based action research and other 
trends and issues in STEM education (Rogayan, 2019). Teacher educators should lead in the enhancement 



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of the prospective teachers’ TPACK as they embrace the challenges of Education 4.0 and the VUCAD2 
(volatile, uncertain, complex, ambiguous, diverse, and disruptive) world. 

CONCLUSION 

 The study determined the experiences of prospective science teachers (PSTs) in teaching under K12 
science curriculum which uses spiral progression approach. The PSTs rarely encounter challenges in teaching 
in the spiral curriculum in terms of the seven dimensions which include content knowledge and pedagogy, 
learning environment; diversity of learners; curriculum and planning; assessment and reporting; community 
linkages and professional engagement, and personal growth and professional development. There is no 
significant difference in the challenges of science prospective teachers when grouped according to profile 
variables. There are low to very high positive significant relationship between and among the seven dimensions 
of challenges experienced by preservice teachers. 

The administration may allocate adequate funding for the provision of additional instructional facilities and 
equipment. The college administration may in-house spearhead seminars and trainings inside the university to 
equip prospective science teachers with innovative teaching strategies and to develop content knowledge and 
another pedagogical dimensions. An orientation on spiral progression approach of the K12 science curriculum 
may be conducted to make science preservice teachers be aware of the curriculum policies, standards and 
guidelines. The teacher educators teaching special education courses may revisit their course syllabi to 
address the need for science integrative teaching to align this in K12 curriculum. Science teachers in the 
college may also do mentoring session to address the least mastered topics of preservice science teachers 
before their teaching internship. An assessment of the PSTs’ technological pedagogical and content knowledge 
(TPACK) may be considered a baseline for pedagogical intervention. 

Since the study was conducted during the pre-pandemic period, further study may also look into the 
challenges of the prospective science teachers in the VUCAD2 world which was aggravated with the COVID-19 
pandemic. The PPST framework may also be utilized as lens in understanding the challenges of the PSTs 
during the emergency remote education brought about by the COVID-19 pandemic. The experiences of the 
prospective teachers in navigating the new normal science education may also be explored where flexible 
learning modality during educational disruption is used. Facilitating biology and other science laboratory 
experiments during COVID-19 educational disruption may also be explored. Lastly, conducting student 
assessment during the COVID-19 learning era may be probed in future studies.  

ACKNOWLEDGEMENT 

The authors would like to acknowledge the school administrators of the higher education institutions for the 
approval to conduct the study, to the prospective teachers for the participation, to the College of Teacher 
Education of the President Ramon Magsaysay State University – San Marcelino Campus for the support to this 
research work, to the critics, editors and anonymous reviewers for the valuable insights which improved this 
research article.  

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