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JOURNAL OF RESEARCH IN SCIENCE TEACHING VOL. 50, NO. 1, PP. 1232 (2013)
Research Article
Teaching Science From Cultural Points of IntersectionBruna Irene Grimberg1 and Edith Gummer2
1Math Resource Center, Montana State University, Bozeman, 401 Linfield Hall, Science,
Bozeman, Montana 597172WestEd, 1350 Connecticut Ave. NW Suite 1050 Washington, District of Columbia 20036
Received 24 April 2012; Accepted 24 October 2012
Abstract: This study focuses on a professional development program for science teachers near or
on American Indian reservations in Montana. This program was framed by culturally relevant pedagogy
premises and was characterized by instructional strategies and content foci resulting from the intersec-
tion between three cultures: tribal, science teaching, and science. The study employs a quasi-experimen-
tal design and quantitative methods to examine the impact of the program on teachers practice and
beliefs, and to determine the relationship between student-centered equity-focused instruction and stu-
dents science test score gains. Results of the analyses indicate that after 2 years in the program teachers
changed their teaching practices and beliefs about their ability to teach science and to implement equita-
ble instruction in a way that positively impacted students performance. Using a multiple regression
analysis it was found that gains in teacher beliefs about their ability to implement equitable strategies
and the increase of teaching strategies that prompt students to make connections between science and
their real-life issues significantly explained the 36.7% of the variance of student science test scores gains
in treatment classrooms. No significant changes in beliefs or teaching strategies were found for compari-
son teachers. The results obtained from this study contribute to the identification of characteristics of a
professional development program that positively impacted the science teaching of American Indian
students. 2012 Wiley Periodicals, Inc. J Res Sci Teach 50: 1232, 2013
Keywords: professional development; equitable instruction; student science achievement
The development of an educational system that is supportive of diverse cultures is imper-
ative in light of rapid and sustained globalization. Globalizationdefined as the worldwide
redistribution of ideas, culture, organisms, goods, capital, and communication (Bencze &
Carter, 2011)links communities of different cultural backgrounds. In the U.S., globalization
accounts for three phenomena: the increase of first and second generation immigrant students,
estimated to be 30% in 2015 (Fix, Passel, & Ruiz De Velasco, 2004); the inclusion of non-
mainstream American students in mainstream public schools; and the national standardization
of education permeating all public schools. Globalization not only entails systemic changes
required of educational institutions to address the needs of students with multiple cultural
backgrounds; globalization also requires community-level reflections about the meaning and
role of education as a globalizing force.
Contract grant sponsor: NSF-MSP; Contract grant number: DUE-0634587.
Correspondence to: Bruna Irene Grimberg; E-mail: grimberg@montana.edu
DOI 10.1002/tea.21066
Published online 30 November 2012 in Wiley Online Library (wileyonlinelibrary.com).
2012 Wiley Periodicals, Inc.
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Culture and education confront each other when education becomes the vector of
one hegemonic culture, or a tool of colonialism. Consequently students and teachers of
non-mainstream groups may be forced into a dichotomy that sometimes necessitates strategies
to make the duality bearable, while at other times this dichotomy increases their marginaliza-tion. For example, Brayboy (2004) found experiences of American Indian college students in
Ivy League institutions to be reactive to mainstream perceptions of American Indians such
that students used strategies [of (in)visibility] that helped them maintain a connection with
their cultural and tribal backgrounds, and thus preserved their individual and group identities
within an uncomfortable and often oppressive context (p. 127). In ways similar to American
Indian students enrolled at Ivy League institutions, American Indian communities have
contested the detrimental effects of standardization on educational, cultural, and linguistic
self-determination and sovereignty with initiatives that have included the identification and
implementation of culturally responsive standards for teaching (AANE, 1998), Native
American charter schools (Lomawaima & McCarty, 2006), and full-immersion programs in
which instruction is delivered almost exclusively in the Native language and centered on the
tribal culture (Warner, 2001).
Globalization also imposes a least common denominator in terms of workforce qualifica-
tions, including communication skills, and scientific and technological knowledge, in order to
be part of the global community. Poor technological and scientific literacy presumably pose a
barrier for economic development (Chiu & Duit, 2011; DeBoer, 2011) and hinder integration.
In a globalized world, education in science, technology, engineering, and mathematics
(STEM) becomes a gatekeeper for participation in global productivity and wealth systems.
That is, globalization simultaneously leads to an increase of cultural encounters and diversi-
ty and, in the case of universally valid science, to an increase of homogeneity (van Eijck &
Roth, 2011, p. 825). The tension between unifying and decentralizing tendencies is at the
core of science education in a globalized society. This study examines the impact of a profes-
sional development program on science teaching practice and teachers beliefs, and subse-
quently on the science achievement of non-mainstream students in American Indian
reservations. The program was designed based on the ideas of culturally relevant pedagogy,
and culturally responsive and congruent instruction.
Theoretical Perspectives
Culture, Culturally Relevant Pedagogy, and Culturally Responsive and Congruent Instruction
Culture can be conceptualized as the combination of norms, values, beliefs, expecta-tions, and conventional actions of a group (Phalen, Davidson, & Cao, 1991). The outcome
of cultures is knowledge, which in turn impacts cultures. The cyclic nature of culture-
knowledge makes culture a dynamic construct. How knowledge is produced, and what
knowledge is produced are the most defining differences among cultures. The realization of
the discontinuity between the cultures of school and community, and its negative impact
on the schooling experience of non-mainstream students led to instructional approaches that
focused on the positive interaction between culture and learning. Ladson-Billings (1995)
proposed a culturally relevant pedagogy framework for the collective empowerment of
non-mainstream students and educational systemic change. This pedagogy is based on
three main ideas: (a) students academic success; (b) students cultural competence; and(c) students critical social consciousness (Ladson-Billings, 1995). Thus, instruction that
approaches content knowledge in such a way that it affirms students values and competences
related to a particular cultural group (students cultural competence) and enhances their
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communities (students critical social consciousness) would result in students achievement
gains (students academic success).
Culturally responsive instructional models are framed by the conceptual premises of cul-
turally relevant pedagogy and are implemented through culturally congruent instruction.Culturally responsive models can be explained as instruction that makes sense to students
who are not members of, or assimilated into, the dominant social group (Klug & Whitfield,
2003, p. 151). These models require the integration of multicultural content, and the use of
instructional approaches that are aligned with students cultural learning styles (Pewewardy,
1998). Responsiveness also implies awareness of students cultural differences and how these
differences might impact students learning. Indeed, research findings provide evidence of the
benefits of making explicit connections between students cultural experiences in and outside
the school on students learning (Apthorp, DAmato, & Richardson, 2002; Lee & Luykx,
2006; Lipka, 2002) and on increasing parental involvement and support (Simpson & Parsons,
2009). Culturally congruent instruction intends to bridge the cultural differences between
school, and homes and communities of non-mainstream students (Parsons, Foster, Travis, &
Simpson, 2005). Such instruction requires teachers to: (a) understand and value students
language and cultural backgrounds; (b) have knowledge of the nature of science; and (c) be
able to connect science to students experiences (Lee, 2004; Lee & Fradd, 1998). Cultural
congruence emphasizes that shared ways of communication and interaction between teachers
and students facilitate non-mainstream students learning. In contrast, cultural incongruence
hinders access to quality science education for non-mainstream students (Parsons, Foster,
Gomillion, & Simpson, 2008). Concurrently, research on classroom uses of students funds
of knowledgedefined as historically accumulated cultural knowledge, skills, and resources
students bring from their households (Moll, Amanti, Neff, & Gonzalez, 1992)shows an
increase in the learning experience of all students (Barton & Tan, 2009; Rios-Aguilar, 2010).
In summary, science learning opportunities for all students occur when values and experiences
students bring from their homes and communities are included in the classroom through the
integration between disciplinary, and cultural and linguistic knowledge; and when support
systems and resources for science learning are in place (Lee & Buxton, 2011). As First
Nations community members expressed, the education system should be able to espouse
traditional values and at the same time meet the changes taking place in society (Agbo,
2004, p. 14).
Science, School Science, and Science Teaching Cultures
Practices reflect their associated culture because they involve patterns of norms, values,and beliefs; in this regard, the practice of science entails a process of gradually engaging in
sciences culture (Aikenhead, 2001; Krogh & Thomsen, 2005; Lyons, 2006; Taconis & Kessels,
2009). Scientific knowledge is constantly monitored against validated theories and constrained
by dominant paradigms. In the context of this study, science culture is defined as the combina-
tion of norms, values, beliefs, expectations, and conventional actions of a group with the pur-
pose to produce and warrant knowledge following scientific epistemic ways. In turn, the
produced knowledge changes the norms, values, and beliefs of science practice; it is in this
regard that science culture is viewed as a practiceknowledge cycle. As in any community of
cultural practice, science practices, policies, and foci are related to their historical time and
place (they have a chronotopic nature). Chronotopic backdrops that shape scientific activityreflect power tensions between the groups engaged in the practice of science. The culture of
science is defined by the attributes and paradigms of the scientific activity itself, but its practice
echoes the social dynamic, place, and historical circumstances of the practitioners.
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Although school science is expected to transfer science attributes into the classrooms
(AAAS, 1993; NRC, 1996, 2007, 2012), the culture of schools radically changes some
aspects of science. For example, the organization of the school day using limited time
periods, and the authoritarian structure of schools, constrain the open-ended activity of sci-ence. Similarly, the dynamic nature of scientific knowledge characterized by the practice
knowledge cycle is at odds with teacher-centered instruction. In this study, school science and
science will be considered as different cultures. School science entails a socio-cultural process
highly dependent on the culture of the school and the classroom, and is shaped by the social
dynamics among students, the curriculum, teacher and administrator expectations, and teach-
ing approaches (Carlone, Haun-Frank, & Webb, 2011). Curriculum, instruction, and teacher
and administrator expectations reproduce social and political tensions (Mickelson & Velasco,
2006), such that science education can be perceived as chronotopic (Lemke, 2005; van Eijck
& Roth, 2011) because its practice and outcomes are time and place bound. The culture of
science teaching is characterized by shared practices, expectations, discourse (Bartholomew,
Osborne, & Ratcliffe, 2004), knowledge derived from the practice of teaching science, and
beliefs about science teaching (Luft, 2001). These characteristics of science teaching depend
on the socio-cultural and historical circumstances in which teaching is embedded.
Cultural Border-Crossing, Cultural Flexibility, and Hybridization
In this section three theories related to students scientific knowledge construction are
discussed: cultural border-crossing, cultural flexibility, and hybridization. These theories view
science learning from a cultural perspective implying learners integration or incorporation of
science knowledge in students cultural schemata. In his seminal work on science learning
and cultural border-crossing, Aikenhead (1996) argues about the need to recognize the
inherent border crossings between students life-world subcultures and the subculture of sci-
ence, and that we need to develop curriculum and instruction with these border crossings
explicitly in mind, before the science curriculum can be accessible to most students (p. 2).
In this framework, science learning is viewed as culture acquisition; it requires developing
proficiency in the discourse and semiotics of science (Gee, 2004; Lemke, 1990). Border-
crossings are mediated by one of two processes: (i) enculturation when the culture of
science agrees with students worldview, or (ii) assimilation when the culture of science is
at odds with students worldview (Aikenhead, 1996, 2001; Aikenhead & Jegede, 1999). How
conflictive a cultural border crossing is depends on the process that mediates it. Although
science learning requires all students to cross a cultural border, school science has connota-
tions of social status and power putting non-mainstream students at a disadvantage either dueto linguistic differences (Zuniga, Olson, & Winter, 2005), dissonances with their home culture
(Gilbert & Yerrick, 2001), or intrapersonal conflicts (Brown, 2004).
Cultural flexibility theory claims that students over the course of their social develop-
ment, effectively navigate diverse social environs such as the workplace, communities, and
neighborhoods (Carter, 2010, p. 1529). Cultural flexibility promotes participation in many
different cultures, as opposed to acceptance of one rigid or homogenous worldview. Sussman
(2000) introduced the notion of intercultural identity in which students are able to interact
effectively in many different cultural settings. Cultural flexibility can be seen as the develop-
ment of students individual identity through a process of multiple assimilations into multiple
cultural settings. School science provides a ground for students and teachers to develop anintercultural identity and cultural flexibility.
Unlike previous views of pre-existing constructs of culture with well-defined boundaries,
the concept of hybridity implies students actively constructing meanings and understandings
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through the creolization of communication around school science (Elmesky & Seiler, 2007).
Hybridity theory attempts to describe how non-mainstream learners generate science knowl-
edge (Barton & Tan, 2009; Barton, Tan, & Rivet, 2008; Elmesky, 2011; Seiler, 2011). It
claims that teachers and students establish new forms of participation that merge the firstspace of school science with the second space of the home (Barton et al., 2008, p. 73). In a
study focused on the incorporation of students home knowledge into a teaching unit on nutri-
tion, Barton and Tan (2009) elicited the generation of hybrid spaces and noted their positive
impact on students engagement and learning. In a later study, Seiler (2011) focused on the
hybridization of teachers identity and science teaching as a vehicle for students identifica-
tion with school science. In both examples hybridity results from the synergy of students and
teachers, differing from the notion of a determined socio-cultural space achieved through
teacher-controlled instruction (Richardson Bruna, 2009). Instead, hybridity depicts students
and teachers co-constructing the school science culture.
In summary, the ideas and theoretical frameworks that are relevant to this study are the
following:
Equitable science instruction, or instruction that attempts to provide learning opportu-
nities for all, is imperative in a globalized, and presumably democratic, world.
Science culture is characterized by a practice-knowledge cycle producing a dynamic,
chronotopic body of knowledge.
School science is strongly shaped by the school culture and teaching and learning.
Learning and teaching science requires engagement in cultural processes.
Science learning can be described as: (i) cultural border-crossing, either through
assimilation or enculturation; (ii) cultural flexibility; or (iii) hybridization.
Instructional approaches conducive to science learning of non-mainstream studentsare supported by a culturally relevant pedagogical framework, and facilitated by the
implementation of culturally responsive and culturally congruent instruction.
This study focuses on the impact on school science teaching, teachers beliefs, and stu-
dents science achievement of a professional development program for teachers of predomi-
nantly American Indian students that was framed by the premises of culturally relevant
pedagogy.
Overview of the Study
After the implementation of Not Child Left Behind Act of 2001 (NCLB, 2002), the timeallocated to teaching science at elementary schools decreased considerably, and in schools
that have not attained the adequately yearly progress (most often focused on language arts
and mathematics) teachers seldom teach science throughout the year (NSTA, 2009). This
situation reflects the status of science teaching in many of the schools included in this project.
The lack of continuity in science teaching and the cultural distance between school science,
students culture, and teachers culture also hinder science teaching. So, one main goal of
the program was to facilitate professional development meaningful and feasible for the
teachers near or on American Indian reservations in Montana. Building on the theoretical
frameworks discussed above, the professional development was designed under the following
assumptions:
(1) Learners constantly cross cultural borders among the many cultures to which they
belong. Yet, there are points of intersection blurring these borders.
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(2) Effective teaching occurs when intersection points are made explicit to the learners.
(3) Teachers need to be able to identify intersection points between school science and
students real-world cultures.
The intersection points between school science (science content knowledge), science
teaching (how to teach science), and contemporary American Indian culture of the schools
communities (cultural knowledge), guided the design of the professional development science
curriculum, modes of delivery, and assessment tools. American Indian contemporary culture
results from the merging of traditional tribal culture with mainstream cultural elements, and
is characterized by the preservation and revitalization of the tribal cultural heritage (van
Hamme, 1995; Henze & Vanett, 1993). Traditional values, beliefs and conventional activities
of American Indians are closely related to the tribal land and natural environment, hence the
cultural diversity among American Indian people. Relevant cultural elements of the tribal
communities involved in this study include: spiritual, ritual, linguistic, and family relations
aspects. This research examines the effects of a professional development program framed by
the premises of culturally relevant pedagogy on teachers science teaching practice and
beliefs, and on American Indian students science test score gains. The research questions
that guide this study are: (1) To what extent does a teacher professional development program
built upon cultural intersection points between school science, science inquiry teaching, and
American Indian cultures facilitate a shift in science teaching? (2) How do shifts in teaching
practices and teachers beliefs contribute to science test score gains of American Indian
students?
Methodology
Implementation of the Professional Development Program
This study focuses on a teacher professional development program that links the theoreti-
cal frames of culturally relevant pedagogy, program implementation, and impact on teaching
practices and students test score gains. Culturally relevant pedagogy provided the conceptual
premises from which the assumptions of the intervention were draw; culturally responsive
models assisted in the identification of topics relevant to the tribal communities; and cultural-
ly congruent instruction guided the design of the activities by determining which tribal cultur-
al elements and practices would be matched up with science content. It involved the joined
effort of tribal advisory teams, faculty of institutions of higher education, and participant
teachers.Program Characteristics. This research was conducted in the frame of a professional
development (PD) program for teachers near or on American Indian reservations in Montana.
The overall project was 5 years long such that two cohorts of teachers received 3 years of PD
with an overlap of cohorts in year 3. Each cohort comprised treatment and comparison teach-
er groups. The PD took place simultaneously in two regions in the state, each with a high
concentration of tribal communities. The northwest region included the Flathead Reservation,
contemporary home of the Salish-Kootenai and Pend d Oreille tribes; and the southeast
region, on the Crow and Northern Cheyenne Reservations. These communities share many
characteristics of rural communities but they also have differences in relation to their cultures
that can be characterized as differences in cultural repertoires of practices due to variationsin the way people participate in common practices (Gutierrez & Rogof, 2003). Although the
PD model and science content was common to both sites, each site had an advisory team
composed of tribal members and teacher leaders to provide guidance on cultural knowledge,
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protocol, and culturally relevant pedagogy suitable to the tribal cultures. The professional
development was delivered in a blended way combining face-to-face and online interactions.
All face-to-face interactions were onsite, including: day-long monthly academies, a 2-week
Summer Institute, and 3-day summer cultural camps. The ongoing year-long online
component supported teachers discussion about the science content and culturally relevant
pedagogy presented during the face-to-face events.
The aim of the professional development was to: (1) develop teachers knowledge of the
tribal cultures; (2) model teaching methods and science content applications congruent with
the cultural practices of the tribal communities; (3) enhance teachers science knowledge; and
(4) enhance teachers knowledge of how to teach science. Because all professional develop-
ment activities wove three cultural strandstribal community, science teaching, and school
sciencescience and education faculty involved in the program worked closely with
tribal advisory teams to identify intersection points between American Indian culture, school
science, and science teaching. The advisory teams included experienced teachers and tribal
elders that have the recognition of their communities, and were actively involved in the com-
munity life. Advisory teams were consulted during the planning and implementation of
the professional development, in order to identify common and unique cultural elements
of the tribes involved in the project. Tribal advisory teams mainly provided suggestions about
the relevance of the science topics and meaningful contexts for science teaching. The science
content foci of the program included Earth Science, Astronomy and Weather and Climate,
and Physics and the topics addressed by the program aligned with the Montana State Science
Standards (OPI, 2011). Cultural intersection points were identified by matching science con-
cepts to cultural practices. Teaching approaches that allowed to incorporate tribal values and
students learning styles were modeled in the face-to-face meetings. Then, teachers imple-
mented these approaches in their classrooms, and the impact of the teaching was discussedonline or in the face-to-face meetings.
An example of a unit on accelerated motion that incorporates cultural points of intersec-
tion is presented in Table 1. In this unit the major science concept woven throughout is:
Table 1
Cultural points of intersection for a unit on accelerated motion
Science Content
American Indian
Cultural Element
Science Teaching
Cultural Element
Cultural Points of
Intersection
Accelerated motion Arrow making andthrowing
Formative assessment Result from thecommon concepts of
arrow making and thegame of Basketball
with the science contentUnbalanced forces Basketball game Collaborative activities Result from the
common practicesbetween science
teaching and AmericanIndian ways of knowing
Vectors Community festivals Naturalisticobservations
Story-telling by com-munity elders
Modeling exploratoryactivities
Learning by observingNative language
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Accelerated motions result from the application of an unbalanced force. The pedagogy
component addressed the use of formative assessment, the implementation of collaborative
activities, the use of naturalistic observations, and modeling exploratory activities. The forma-
tive assessment emphasized the use of multiple representational modes (text-based, diagrams,picture-based, kinesthetic, etc.) and being authentic in the context of students everyday life.
The cultural component was present through two contemporary cultural practicesarrow
making and throwing, and basketball gamesand by the fact that members of the community
presented such topics. A tribal elder gave a presentation about the art of making and throwing
arrows and also explained who and when it is appropriate to engage in this practice according
to the Northern Cheyenne tradition. He introduced words in the Native language and related
the practice of arrow throwing to festivals and community events familiar to the teachers of
the community. The game of basketball is a very important community event for Montana
tribes as it incorporates family related cultural values. Moreover, basketball games are also
part of contemporary Powwows-competitions of traditional dances and drumming that
involves multigenerational members of the community. High school Crow students demon-
strated different ways to throw the ball providing opportunities to discuss applied forces and
parabolic motion. The curriculum and instruction of this unit reflected a culturally responsive
approach because the culture of the tribes was integrated in an authentic way: on-site, relevant
to the students and teachers life experiences, and presented by community members who
held mastery of the cultural practices. Content knowledge resulted from finding intersection
points between tribal, science teaching, and school science cultures.
In the example provided above, the science concept of accelerated motion was identified
in the cultural practice of arrow making and throwing. The shape of the bow, the elasticity of
the materials of the arrow and bow, the tension in the string, the body position in the throw,
and many more intricacies of this practice were matched to the concept of force and acceler-
ated motion. In this example the empirical epistemology of the tribal practice was matched to
the abstract, model-based epistemology of school science as both knowledge bases have the
same purpose: the prediction of the motion of an object subject to an unbalanced force.
School and Classroom Characteristics. The schools involved in the project included 25
K-8 schools on the Flathead, Northern Cheyenne and Crow Reservations and surrounding
areas. These schools are small, isolated, and resource-limited. Poverty rates vary from 31% to
75% of the students participating in the Free and Reduced Lunch program. Students transfer
rate between schools is high; and the lack of curriculum continuity and alignment leads to
disjointed educational experiences for these students. The quality of the science programs inthe schools varied: 43% of the teachers rated their school science program high quality (4 or
5 on a 5-point scale), 30% gave it a middle rating, and 28% gave it a low rating (1 or 2 on a
5-point scale). In 75% of cohort 1 schools, classes were organized as self-contained, likewise
in 79% of schools of cohort 2. The number of students per class varied: about 45% of cohort
1 and 2 treatment classrooms had 2125 students, and 10% of the classrooms had 2630
students; while for comparison groups, about 33% of the classrooms had 2125 students, and
21% of the classrooms had 2630 students. The grade bands considered in this study were:
G34, G56, G78; their distribution in both cohorts for treatment and control groups peaked
at the G34 grade band.
Teachers and Students Characteristics. Teachers volunteered to participate in the pro-gram; the assignment into treatment or comparison roles was the choice of the teacher. Both
treatment and comparison teachers received a stipend for their participation. Forty percent of
the teachers enrolled in the program were American Indians while 60% were Caucasians. The
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teachers gender distribution varied between cohorts. In cohort 1 the percentage of females
teachers was 89% in the treatment group and 79% in the comparison group; in cohort 2 the
percentage of females teachers was 80% for both treatment and comparison groups. The high-
est education degree of 80% of the treatment teachers of both cohorts was B.S. or B.A. in
Elementary Education. Comparison teacher groups held a higher degree of education: 58% of
cohort 1 comparison teachers had a B.S. or B.A., while 37% a M.S. or higher; 47% of cohort
2 comparison teachers had a B.S. or B.A, while 50% held a higher degree. More than 90% of
all teachers involved in the program (both cohorts and treatments) have a certification
for teaching elementary grades and about 30% have multiple certifications (elementary and
middle grades). Teachers expertise, indicated by the number of years in the profession, was
consistent across cohorts and treatment groups. Teachers with more than 15 years of expertise
constituted the largest category.
The fidelity of the treatment varied per cohort group. Forty-eight cohort 1 treatment
teachers were enrolled in the program, but 36 teachers completed the 3 years of professional
development. Forty treatment teachers enrolled in cohort 2, but only 29 completed the pro-
gram. Comparison teachers had a lower attrition rate. Twenty-nine comparison teachers
started in cohort 1 and 24 completed the period of the professional development; and 36
comparison teachers for cohort 2 started and ended in the program. The number of teachers
included in each analysis corresponds to the teachers that had a complete set of data required
by the analysis.
The teachers that participated in this project (treatment and comparison groups) taught
classrooms with about 10030% students enrolled as American Indians, depending on the
school district. The American Indian students live either on or near a reservation, and in most
cases with American Indian family members. Students gender distribution varied per cohort
and treatment group, such that between 53% and 80% of the classrooms had between 50%and 60% male students. The percentage of Limited English Proficient (LEP) students was
consistent across cohorts and treatment groups, about 72% or more of the classrooms includ-
ed in the project had less that 10% LEP students.
Characteristics of the Study
The tapestry of characteristics of schools, classrooms, teachers, and students reflects the
nature of rural school settings with low-density populations, very small school districts, and a
small number of teachers. Thus, the treatment and comparison groups were matched based on
their teaching grade-band as they have comparable teaching demands (in terms of curriculum
and instruction). All comparison and treatment teachers belong to the same pool of school
districts housed on the Flathead, Northern Cheyenne and Crow Reservations, and surrounding areas.
Methods and Tools for Data Collection. Various methods of data collection were used to
document the impact of the professional development on teachers science instruction, on teach-
ers science content knowledge, on teachers beliefs about their ability to implement equitable
instruction and confidence about their science knowledge, and on students science learning.
These methods included: classroom observations, portfolios with lesson plans and students
work, teacher surveys on culturally congruent instruction and on science teaching practices and
beliefs, and teachers and students science content tests. This study used a teacher survey
called Surveys of Enacted Curriculum (SEC; CCSSO, 2005), and students pre/post-sciencetests for Earth Science, and Astronomy, Weather and Climate. The content areas addressed in
this study relate to topics that were taught by cohort 1 and 2 teachers. This study uses data
corresponding to the first and second year of teachers being in the program.
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Teachers completed the SEC individually and online, in early fall (baseline) and sub-
sequently once a year at the end of the school year. SEC is comprised of 17 dimensions
and captures the way teachers allocate classroom time to different instructional tasks, and
documents teachers beliefs about their readiness to teach science content and to implementequitable instruction. Qualitative data, including classroom observation field notes and teach-
ers portfolios, were used to provide fidelity of the professional development intervention and
to identify instructional strategies that were most frequently observed in the classrooms and
documented in teachers portfolios. These strategies included approaches that prompted stu-
dents to: (1) communicate understandings and findings using multiple modalities, (2) analyze
information, (3) perform exploratory activities such as hands-on investigations and simula-
tions, and (4) make connections between science and topics relevant to students life and their
community, and between science content and hands-on activities that involves predicting and
designing new experiments. A description of these dimensions is included in Table 2.
Table 2
List of items in the dimensions of teachers survey
Communicate
Understanding Analyze Information Performing Procedures Make Connections
Teaching practicesWrite about sciencein science papers
Analyze and interpretscience data
Do a laboratory activity,investigation, orexperiment
Make educated guesses,or predictions usingprior knowledge
Complete writtenassignments from the
textbook or workbook
Make a predictionbased on the data
Follow step-by-stepdirections
Change a variable inan experiment to test
a hypothesisWrite up results orprepare a presentationfrom an investigation,or experiment
Analyze and interpretthe informationorally or in writing
Use science equipmentor measuring tools
Design their owninvestigation toanswer a scientificquestion related totheir community
Work on a writing projectseeking peer comments
Display and analyzedata
Collect data
Have class discussionsabout the data
Organize and displayinformation in tablesor graphs
Organize and display the
information in tables orgraphs
Make observations
Practice proceduresUse sensors or probes
Content Readiness Equity Readiness
Teachers believes about their ability to . . .Teach science at your assigned level Teach students with disabilitiesIntegrate science with other subjects Teach classes with students with diverse
abilitiesProvide science instruction that meetsscience standards
Teach science to students from a variety ofcultural backgrounds
Use a variety of assessment strategies Teach science to ELL studentsManage using hands-on activitiesTake into account students prior conceptionswhen planning
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In this study we focused on six dimensions, four of which are the aforementioned practi-
ces, in addition to teachers beliefs about their readiness to teach science content at their
grade level, and to implement equitable instruction. Each dimension consisted of a different
number of items; the number of items per dimension (n) and its reliability coefficient estimat-ed by the Cronbach alpha correlation are: content ready (n 6), 0.90; equity ready (n 4),
0.78; performing procedures (n 8), 0.79; communicate understanding (n 7), 0.79; ana-
lyze information (n 4), 0.84; and make connections (n 3), 0.82. The internal consistency
of each of the SEC dimension was estimated using the full sample size, both treatment and
comparison teachers. Changes in teaching practices and teachers beliefs after 1 and 2 years
in the program for teachers of both cohorts, were obtained from a repeated-measures
ANOVA. Equity readiness and content readiness were rated over a four-point Likert scale;
while the other dimensions were rated over a five-point Likert scale. The results of signifi-
cance and effect size correspond to the multivariate results of the Greenhouse-Geisser correc-
tion because the sphericity condition for the ANOVA was not achieved (Leach, Barret, &
Morgan, 2008).
Students science tests were designed by the external evaluators, and the education and
STEM faculty involved in the project, using released test items from various sources. The
external evaluators as well as the STEM and education faculty had an extended experience
of working with American Indian communities and in-service teachers. Test items were
aligned with the content topics targeted by the professional development program and
the competencies associated with research-based science instruction. Issues of language and
contexts suitable to American Indian students were considered in adapting the items. Three
different tests, corresponding to the G34, G56, and G79 grade bands, were designed and
used in the treatment and comparison classrooms. All questions were multiple choice, and the
number of items varied depending on the grade band test, such that Earth Science tests
included 16, 25, and 29 items for G34, G56, and G79, respectively; and the Astronomy,
Weather, and Climate test included 25, 27, and 28 questions for G34, G56, and G79, res-
pectively. Students pre and posttests were administered in their classrooms during September
and April, respectively. Students score sheets were scanned, and scores recorded in spread-
sheets. The reliability of Earth Science and Astronomy, Weather, and Climate tests were
estimated using the Cronbach alpha correlation coefficient. The reliability estimates for the
Earth Science test were: 0.61 pretest, 0.71 posttest for G34; 0.76 pretest, 0.78 posttest for G
56; and for both pre and posttests of G78 Cronbach alpha 0.80. The reliability estimates
for the Weather, Astronomy and Climate test were: 0.63 pretest, 0.70 posttest for G34; 0.60
pretest, 0.72 posttest for G 56; and 0.74 for the pretest and 0.61 for the posttest of G78.
Methods of Analysis. The analyses included in this study are: (i) a repeated measures
ANOVA of the SEC data for two teacher cohorts including treatment and comparison groups;
(ii) a mixed ANOVA of test score gains of the students in the treatment and comparison
teacher groups; and (iii) a multiple regression analysis to explain students science test score
gains with changes in science instruction and beliefs of treatment and comparison teacher
groups. The unit of analysis in this study is the teacher/classroom. The repeated-measures
ANOVA provided results of the variance of teachers practice and beliefs (SEC data) through-
out the time teachers were enrolled in the program. Cohort 1 treatment teachers data corre-
spond to three-time SEC measurements: baseline, after 1 year in the program, and at end ofthe second year. The analyses for comparison teachers of cohort 1 and 2 teachers included
two-time SEC measurements: baseline and at the end of 1 year in the program. The mixed
ANOVA was conducted to assess whether there were differences in students average scores
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in terms of the time of the year of the test administration (pre/post), and of the treatment
condition of the teachers (treatment or comparison). The multiple linear regression analysis
was conducted with the classrooms that have a full set of data including: teachers SEC data
(baselines and subsequent years), and classroom students tests data (pre and postdata).
Even though this approach to the management of missing data, also called a complete-case
analysis, reduces the sample size it leads to unbiased parameter estimates (Howell, 2007).
Thus, the sample size for the regression analysis was smaller than the number of teachers
initially enrolled in the project from 36 teachers down to 27 teachers; constraining the number
of variables that can be used to meaningfully model classroom average students test score
gains.
Findings
This study examines the effects of a professional development program framed by the
premises of culturally relevant pedagogy on teachers science teaching beliefs and practice,
and on students science test score gains on or near American Indian reservations in Montana.
The questions that guided this study are: (1) To what extent does a teacher professional
development program built upon cultural intersection points between school science, science
inquiry teaching, and American Indian cultures facilitate a shift in science teaching? (2) How
do shifts in teaching practices and teachers beliefs contribute to science test score gains of
American Indian students?
The teaching practices included in this study correspond to strategies that prompted stu-
dents to: (1) communicate understandings and findings using multiple modalities, (2) analyze
information, (3) perform procedures such as exploratory activities, and hands-on investiga-
tions, and (4) make connections between science and topics relevant to students life and their
community, and between science content and hands-on activities that involves predicting anddesigning new experiments. The teachers beliefs that were included in this study referred to
their readiness to teach science content, and to implement equitable instruction. The findings
reported here attempt to answer these questions.
Shift in Teachers Science Instruction and Beliefs
Results of cohort 1 teachers, including treatment and comparison teachers, are included
in Table 3. Treatment teachers results show a change in content and equity readiness,
analysis of information, and the make connection variables. These variables significantly
followed a linear increment from year to year, and their effect sizes (ffiffiffiffiffih2
p) are large (Cohen,
1988). Comparison teachers significantly increased the use of strategies that prompt studentsto analyze data. This variable had a significant increment in 1 year. The observed low power
of the comparison group results can be attributed to the small sample of comparison teachers
that completed both SECs.
Results for cohort 2 treatment and comparison teachers are based on baseline and after
1-year program SEC data. Treatment teachers changed their beliefs in their ability to implement
equitable instruction and to teach science content knowledge, and practices that require stu-
dents to make connections between science topics, students real-world issues, and hands-on
activities; while comparison teachers showed changes only in practices requiring students to
communicate understandings and findings. Results for cohort 2 teachers are shown in Table 4.
A third repeated-measures ANOVA was conducted for cohort 1 treatment teachers after1 year in the program with the purpose of comparing these results to cohort 2 treatment
teachers and to identify the teachers practices and beliefs that are impacted after 1 year in
the program. The results for both cohorts overlap. The variables that changed over a 1-year
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period were: teachers beliefs in their ability to implement equitable science instruction and
teach science content, and teaching strategies that prompt students to make connections.
In summary, after 1 year in the program treatment teachers felt empowered in their abili-
ty to teach science content and to implement equitable instruction, and they increased the
classroom time students spent making connections between science topics and issues related
to their life and communities, and to hands-on experiences. These results were obtained for
both cohorts. Similarly, during the first 2 years in the program, treatment teachers showed a
Table 4
Teachers practices and beliefs (cohort 2)
Teaching Variable Y0 Mean (SD) Y1 Mean (SD) Sig. (p) Effect Size Power
Treatment teachers (N 27)a
Content readiness 1.67 (0.70) 1.95 (0.40) 0.009 0.48 0.77Equity readiness 1.30 (0.55) 1.54 (0.44) 0.008 0.49 0.79Performing procedures 2.18 (0.68) 2.36 (0.49) 0.111 0.31 0.36Communication 1.79 (0.73) 1.94 (0.65) 0.164 0.27 0.28Analysis of information 2.11 (0.77) 2.36 (0.82) 0.064 0.35 0.46Connections 1.71 (.74) 2.09 (0.65) 0.025 0.42 0.63
Comparison teachers (N 35)a
Content readiness 1.75 (0.65) 1.73 (0.60) 0.750 0.05 0.06Equity readiness 1.60 (0.62) 1.48 (0.63) 0.186 0.22 0.26Procedures 2.07 (0.58) 1.90 (0.53) 0.060 0.31 0.47Communication 1.39 (0.45) 1.57 (0.56) 0.020 0.39 0.67Analysis 1.83 (0.86) 1.70 (0.59) 0.160 0.24 0.28
Connections 1.87 (0.89) 1.77 (0.69) 0.430 0.14 0.12
Y0 and Y1 refer to: baseline and after 1 year in the program, respectively.aN denotes the number of cohort 2 teachers with complete SEC data for both baseline and end-of-first year. This
number might differ from the number of teachers enrolled in the program.
Table 3
Teachers practices and beliefs (cohort 1)
Teaching Variable
Y0 Mean
(SD)
Y1 Mean
(SD)
Y2 Mean
(SD)
Sig.
(p)
Effect
Size PowerTreatment teachers (N 31)
a
Content readiness 1.58 (.54) 1.89 (0.60) 2.00 (0.63) 0.003 0.45 0.89Equity readiness 1.27 (0.65) 1.77 (0.65) 1.74 (0.58)
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significant improvement in teaching practices that prompt students to analyze data and to
make connections. Also, they built on their confidence in their ability to teach science content
and to implement equitable approaches in the classroom. No significant changes were found
in treatment teachers implementation of practices that involve exploratory procedures; orpractices prompting students to use various ways of communication. In turn, comparison
teachers change of practice and beliefs did not display a clear trend between cohorts. First
cohort comparison teachers improved the implementation of teaching strategies that prompt
students to communicate their findings using multiple ways of representations. While the
second cohort of comparison teachers reported a change only in teaching strategies that
prompt students to analyze data. Comparison teachers readiness to implement equitable
instruction decreased in the 1-year interval (1.52 0.72 and 1.49 0.59 for baseline and
year 1, respectively, for cohort 1; and 1.60 0.62 and 1.48 0.63 for baseline and year 1,
respectively, for cohort 2). This trend contrasts with treatment teachers results, in which
mean values of the equity readiness variable increased after 1 year in the program
(1.27 0.65 and 1.77 0.65 for baseline and year 1, respectively, for cohort 1; and
1.30 0.55 and 1.54 0.44 for baseline and year 1, respectively, for cohort 2). Similarly,
the mean values of treatment teachers SEC variables are overall higher than the mean values
for comparison teachers.
Another, unintended, result is the decrease in the number of teachers that completed the
SEC survey throughout the years. About 15% of cohort 1 treatment and comparison teachers,
and 27% of cohort 2 treatment teachers did not complete the SEC survey as the years passed.
This trend, common in both cohorts and more prominent for treatment teachers, speaks to
the difficulties of data collection in rural settings in which long commuting distances and
inconsistent access to online communications pose a real obstacle.
Students Test Score Gains
Classroom average scores of student science tests, for treatment and comparison groups,
are presented in Table 5. A mixed ANOVA was conducted to assess whether there were differ-
ences in the average scores in terms of the time of the year of test administration (pre/post),
and of the treatment condition of the teachers (treatment or comparison). Results for the
Earth Science test indicate a significant effect of the time of the year, F(1, 59) 67.99,
p < 0.001, but not of the treatment condition, F(1, 59) 0.00, p 0.99; nor is there
indication of an interaction between the time of the year and the treatment condition,
Table 5
Classroom average students science test scores
Treatment Condition Earth Science Mean (SD) Astronomy, Weather, and Climate Mean (SD)
PretestTreatment 54.40 (13.30) 41.57 (10.48)
N 29 N 29Comparison 54.40 (14.32) 44.39 (10.06)
N 32 N 28Posttest
Treatment 60.70 (14.17) 48.34 (11.45)
N 29 N 29Comparison 60.64 (14.42) 49.30 (10.21)
N 32 N 28
N represents the number of classrooms that have both pre- and post-student science test data.
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F(1, 59) 0.002, p 0.967. Results for the Astronomy, Weather and Climate test indicate a
significant effect for the time of the year, F(1, 55) 67.76, p < 0.001, but not of the treat-
ment condition, F(1, 55) 0.46, p 0.50, nor of the interaction between the time of the
year and the treatment condition, F(1, 55)
1.75, p
0.197. The results for both sciencetests indicate that even though there is a difference in the classroom average scores between
the beginning and end of year tests, unexpectedly, this difference is not associated to the
treatment condition of the teachers.
In order to explore if the increase of the average posttest scores was related to teachers
changes of practices and beliefs, a multiple linear regression analysis between classroom
average test score gains and changes of practices and beliefs was done. The regression model
used the variables that displayed a significant and sustained change as reported by treatment
teachers, including: make connections, equity readiness, content readiness, and analysis
of information. For comparison classrooms, where a sustained change was not found, test
score gains were modeled using multiple regression linear models of combinations of two,
three, and up to four variables out of the six variables included in this study.
Classroom average student test score gains for Astronomy, Weather, and Climate of treat-
ment teachers were best predicted by a linear regression model that combined the changes in
make connections and equity readiness variables. This model explains 36.7% of the vari-
ance of average test score gains (adjusted R); the correlation coefficient is 0.645, and the
model is significant at p 0.002 level. The parameters of this model are shown in Table 6.
It is important to note that both variables of the modelthe changes in teachers beliefs
about their ability to implement equitable instruction, and students making connectionsare
linearly independent, as shown by the colinearity tolerance (close to 1.00). In contrast, no
combination of variables produced a significant model (p 0.05) when linear regression
models were used to predict comparison classrooms average score gains of the Astronomy,
Weather, and Climate student test. In addition, quadratic and cubic relationships between
dependent and independent variables were explored, but no significant relationships were
found. Similar multiple regression linear models were applied to the Earth Science classroom
average test score gains but no combination of variables produced a significant model for
both treatment and comparison groups. It is important to note that students score gains on
the Astronomy, Weather, and Climate test were modeled with the changes in practices of
teachers that had been 2 years in the program. In contrast, the Earth Science score gains
were modeled with changes in practices of teachers that spent 1 year in the program. Thus,
although teachers significantly improved some of their practices and self-confidence after
1 year in the program, these changes are not enough to explain students test score gains.
Discussion
The findings related to the impact of the professional development on teachers practice
provide evidence that the shifts in science teaching incorporated the ideas of equitable and
reform-based instruction. Teachers also increased their confidence in the ability to teach
Table 6
Regression linear model of treatment average score gains
Linear Model Standardized Coefficient Significance (p) Collinearity Tolerance
Making connection 0.583 0.001 0.963Equity readiness 0.409 0.017
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science content and to implement equitable teaching approaches. ANOVA results of the SEC
data show that after 1 year in the program, treatment teachers increased the use of teaching
strategies that prompt students to make connections between science and topics relevant to
their life and community, and to hands-on experiences that involves predicting and designingnew experiments. According to the results of the ANOVA for a 2-year span, treatment teach-
ers showed a consistent pattern of changes in these beliefs and practices, while comparison
teachers rendered a random-like change in teaching practices.
The findings for the treatment teachers are closely aligned with the foci of the profession-
al development program aiming to integrate American Indian culture of the local communi-
ties, science content, and reform-based pedagogy through identifying cultural points of
intersection. These findings are in agreement with the claim about the effectiveness of science
teaching when it occurs in a hybrid space resulting from the incorporation of everyday
discourses in science teaching and learning (Barton et al., 2008; Seiler, 2011), or when teach-
ers tap into students funds of knowledge (Barton & Tan, 2009). Similarly, in a context of
professional development, Chinn (2007) found that programs focused on eliciting Native
knowledge in relation to science significantly increased participants appreciation of Native
culture and its importance to effectively teach science. Additionally, Johnson (2011) found
that professional development models grounded on the premises of improving the educational
experiences of diverse students, effective science teaching, and culturally congruent instruc-
tion enable participant teachers to shift their practice towards a culturally relevant pedagogy.
So, what is the novel contribution of cultural points of intersections? Points of intersection
between science knowledge, community culture, and science teaching suggest that the effec-
tiveness of a hybrid space can be expanded to the practiceknowledge cycle of a communitys
culture. Matching cultural practices with core concepts in science promotes the construction
of hybrid content. In other words, cultural points of intersection suggest that school
science would not only be shaped by the school culture and paradigms of science teaching
and learning, but also by the cultural practices of the communities in which teaching is taking
place.
The impact of the professional development program on students science test score
gains can be explained by the increment of teachers implementation of equitable instruction,
which prompted students to make connections between science topics, issues relevant to
their lives, and hands-on experiments. This result, only corresponding to treatment class-
rooms, fully supports the premises of instructional congruence (Lee, 2002, 2003, 2004; Lee
& Fradd, 1998) about the importance of developing congruence not only between students
cultural expectations and classroom interactional norms but also between academic disci-plines and students linguistic and cultural experiences (Lee, Hart, Cuevas, & Enders, 2004,
p.4). Both variables of the model - the changes in teachers beliefs about their ability to
implement equitable instruction, and students making connectionsare linearly independent
indicating that both aspects of the instruction are necessary to contribute to students test
score gains.
Remarkably, of the six variables included in this study, only the two variables that
directly relate to the notion of cultural intersection points significantly predict the increase of
student science tests scores. One of the variables refers to teachers confidence in implement-
ing strategies that explicitly address cultural points of intersection; while the other variable
refers to what students do in class in order to bridge their worldview and school sciencecultures through cultural intersection points. This relationship is absent in comparison groups,
in which teachers neither increased their belief about their ability to effectively implement
equitable instructional strategies, nor gains were found in relation to strategies that
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prompt students to make connections between science and topics relevant to their life and
community.
The constructs of culturally congruent instruction and cultural points of intersection
emerged from the realization of the critical role of students cultural background and priorknowledge in knowledge construction (Driver, Leach, Millar, & Scott, 1996). Cultural con-
gruence stresses shared ways of communication, through common languages and cultural
backgrounds between teachers and students. However, culturally congruent ways of knowing
and communicating are sometimes incompatible with the nature of science as represented by
science education standards (Lee & Fradd, 1998, p. 18). Cultural points of intersection stress
the common conceptual grounds between cultural practices (e.g., the ones derived from em-
pirical and technological knowledge) and science core ideas (e.g., the ones obtained from
abstract or model-based knowledge), such that incompatibilities between students cultural
background and science are greatly reduced. For example, the analysis of the way a tipi is
built will be conducive to the concepts of force and Newtons First Law of Motion. Cultural
points of intersection do not emphasize the adaptation of scientific habits of mind to students
cultural frame, but digs into both frames to find common constructs. This view of science
instruction emerged from the fundamental view that cultures of practice and school science
contribute to learners knowledge construction. Indeed, by eliciting the science concept in
the light of a cultural practice, the culture of science and the cultural practice contribute to
the school science Discourse. This approach dissipates the dichotomy imposed by an educa-
tion based on a hegemonic culture and contributes to equitable normative scientific practices
of the classroom; such practices expand the notion of science literacy and positively impact
non-mainstream students (Carlone et al., 2011).
Conclusions
This research shows the effectiveness of a professional development program that focuses
on cultural points of intersection for the enhancement of teachers science teaching in non-
mainstream students classrooms. After 2 years in the program teachers steadily and signifi-
cantly increased their confidence in the ability to teach science content and to reach non-
mainstream students; they also increased the classroom instruction time allocated to practices
that require students to make connections between science content and topics relevant to their
life, communities, and real-world hands-on experiences. We also showed that teaching strate-
gies and curriculum that explicitly address cultural points of intersection between school
science and students worldviews substantially contribute to students science test score gains.In this regard, teaching through cultural points of intersection constitutes an instructional
strategy that addresses culturally responsive models paradigm.
Globalization entails the re-distribution of ideas, goods, people, and practices; it urges
people to define their cultural identity in order to partake in the globalized exchange. People
bring to and take from a large pool of cultural elements to re-create their own. The notion of
cultural points of intersection mirrors this cultural exchange through conceptual juxtaposition.
This study, that prompts to connect different cultural zones, contributes meeting the chal-
lenges of globalization.
A next step in considering cultural points of intersection as a viable equitable instruction-
al strategy is to address this construct in classrooms with multiple diverse cultures. The find-ings presented here emerged from science instruction in bi-cultural (mainstream and
American Indian) or mono-cultural (American Indian) classrooms; thus, the door is open to
further explore the implementation of cultural points of intersection.
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We are grateful to Regina Sievert and Tim Olson of Salish Kootenai Community
College; Elisabeth Swanson of Montana State University; Judith Devine, Education
Northwest Lab; Gail Whiteman Runs Him, Crow Tribe; and to all participant teachers,
that certainly have been a source of inspiration. Also, we want to express our gratitude
to the reviewers and editors of the manuscript for their insightful suggestions. This
research has been possible with an NSF-MSP grant # DUE-0634587.
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