Potential Benefits and Barriers to Integration

STAGES OF CURRICULUM CHANGE

by Katherin Pilla M.

CLIL Essential concepts

by cristina borda

FAPE Case 7.1 Thomas

by Lorie Blumeyer

Reflective Teaching

by William Marshall

Potential Benefits and Barriers to Integration, by: Sherry Meier, et. al. 1998.

Conclusions

Tools to success!

Strongly believe that YES integration can be done!

Develop assessmens that measure student competency for mastery.

Adequate/Ongoing Staff development to implemet curricula

Quality materials & methods

Educators need to collaborate to achieve common goals (Education Reform)

Develop awarenes of community for education reform to achieve educational change

Develop teachers' better understanding for integration programs

Give the long term support when addressing change

Address preservice knowledge barriers

Share best practices

Lack of Research

CeMaST developed an Integrated Mathematics, Science, and Technology. Students score higher on open-ended,student-constructed response

Ask that schools asses what major outcomes are desired, not just what is easy to measure.

Berlin and Hillen (1994) report positive cognitive outcomes related to participation in the Activities Integrating Mathematics and Science (AIMS) program

Teaching Integrated Mathematics and Science (TIMS) finds that "a consistent dose of hands-on activities can make a real difference in student performance"

Shann's research showed increase appreaciation for science when integrated with math/science program.

Little change is carried out, since there is little research on the benefits of integration.

Discussion Questions:

Do I want preservice teachers to understand how to teach mathematics, science, and language arts as separate subjects in their own right

Does our teacher education program prepare prospective teachers to teach in an integrated setting?

Are we modeling an integrated curriculum for these students by coordinating their teaching efforts across departments?

Do teacher education faculty members work in cross-disciplinary teams as a model for their students?

Do we place our student teachers with cooperating teachers who teach an integrated curriculum, and, if so, how do we find enough of these teachers and schools?

Does the teacher education program need to develop inservice programs for the many teachers already teaching who have never experienced (much less taught) integrated curricula?

Do I want students’ pedagogical content knowledge to be interdisciplinary?

Implementation Issues

Assessment and Curriculum Barriers

Staff development for teachers required in order to be successful

Curriculum materials being produced already by National Science Foundation, Systemic Initiatives in Montana Mathematics and Science, IMaST, Maths in Context, and Sixth Through Eight Mathematics

Key to acceptance of any curriculum comes from accepting all materials supporting this reform.

Programs need to be developed that assess both content areas simultaneously

Assessments should match curricula methods and goals

Tests made to measure one content not multiple

School Structure Barrier

Adoption cycle issues for curriculum programs

Acquisition of materials

Teachers not accustomed to obtaining materials

Purchasing systems inflexible

issues with "tracked" students

Labs poorly equipped to handle "lab oriented science"

Student schedule issues

Lack of planning time

Teacher Belief Barrier

Prior beliefs and concerns about integration

Unaware or unfamiliar with integration methods

Time contraints / weak backgrounds

Teachers unwilling to change

Teacher Knowledge Barrier

Lack of commited administration/ teacher

Most programs designed to be taught by team teaching

Teachers have math anxiety

State certification systems cause difficulty to be certified under different subject areas.

Unknown which group is best prepared

Teachers unprepared in content knowldedge

Content Barrier

Would leave wide gaps in math concepts.

Only what fits into integrated unit is studied

Math involved is not challenging but narrow

theme chosen by teacher is usually not math.

Several problems identified include trivializing content, resulting in deficient skills, teacher knowledge, school structure, and assessment

Literature Supporting Integration

Southwell, 1994

Showing relevance of math allos students to see numerous applications outside classroom.

McBride and Silverman, 1991

Deeper understanding could be achieved through math by quantifying and explaining scientific relationships.

Cite close interrelatedness between math and science

The National Science Education Standards, 1995

"Scientific literacy includes the interdependency of science with other subjects such as mathematics and technology."

Association for the Advancement of Science, 1989

"need for students to be scienctifically and mathematically literate"

Curriculum and Evaluation Standards for School Mathematics identifies that every level of K-12 Standards contains the 4 common process standards.

Connections

Reasoning

Communications

Problem Solving

Potential Benefits and Barriers to Integration

Implementing integrated curricula in schools faces several hurdles. Key challenges include insufficiently equipped labs and rigid student schedules, which hinder proper lab-oriented science education.

STAGES OF CURRICULUM CHANGE

CLIL Essential concepts

FAPE Case 7.1 Thomas

Reflective Teaching

Potential Benefits and Barriers to Integration, by: Sherry Meier, et. al. 1998.

Conclusions

Tools to success!

Strongly believe that YES integration can be done!

Develop assessmens that measure student competency for mastery.

Adequate/Ongoing Staff development to implemet curricula

Quality materials & methods

Educators need to collaborate to achieve common goals (Education Reform)

Develop awarenes of community for education reform to achieve educational change

Develop teachers' better understanding for integration programs

Give the long term support when addressing change

Address preservice knowledge barriers

Share best practices

Lack of Research

CeMaST developed an Integrated Mathematics, Science, and Technology. Students score higher on open-ended,student-constructed response

Ask that schools asses what major outcomes are desired, not just what is easy to measure.

Berlin and Hillen (1994) report positive cognitive outcomes related to participation in the Activities Integrating Mathematics and Science (AIMS) program

Teaching Integrated Mathematics and Science (TIMS) finds that "a consistent dose of hands-on activities can make a real difference in student performance"

Shann's research showed increase appreaciation for science when integrated with math/science program.

Little change is carried out, since there is little research on the benefits of integration.

Discussion Questions:

Do I want preservice teachers to understand how to teach mathematics, science, and language arts as separate subjects in their own right

Does our teacher education program prepare prospective teachers to teach in an integrated setting?

Are we modeling an integrated curriculum for these students by coordinating their teaching efforts across departments?

Do teacher education faculty members work in cross-disciplinary teams as a model for their students?

Do we place our student teachers with cooperating teachers who teach an integrated curriculum, and, if so, how do we find enough of these teachers and schools?

Does the teacher education program need to develop inservice programs for the many teachers already teaching who have never experienced (much less taught) integrated curricula?

Do I want students’ pedagogical content knowledge to be interdisciplinary?

Implementation Issues

Assessment and Curriculum Barriers

Staff development for teachers required in order to be successful

Curriculum materials being produced already by National Science Foundation, Systemic Initiatives in Montana Mathematics and Science, IMaST, Maths in Context, and Sixth Through Eight Mathematics

Key to acceptance of any curriculum comes from accepting all materials supporting this reform.

Programs need to be developed that assess both content areas simultaneously

Assessments should match curricula methods and goals

Tests made to measure one content not multiple

School Structure Barrier

Adoption cycle issues for curriculum programs

Acquisition of materials

issues with "tracked" students

Labs poorly equipped to handle "lab oriented science"

Student schedule issues

Lack of planning time

Teacher Belief Barrier

Prior beliefs and concerns about integration

Unaware or unfamiliar with integration methods

Time contraints / weak backgrounds

Teachers unwilling to change

Teacher Knowledge Barrier

Lack of commited administration/ teacher

Most programs designed to be taught by team teaching

Teachers have math anxiety

State certification systems cause difficulty to be certified under different subject areas.

Unknown which group is best prepared

Teachers unprepared in content knowldedge

Content Barrier

Would leave wide gaps in math concepts.

Only what fits into integrated unit is studied

Math involved is not challenging but narrow

theme chosen by teacher is usually not math.

Several problems identified include trivializing content, resulting in deficient skills, teacher knowledge, school structure, and assessment

Literature Supporting Integration

Southwell, 1994

Showing relevance of math allos students to see numerous applications outside classroom.

McBride and Silverman, 1991

Deeper understanding could be achieved through math by quantifying and explaining scientific relationships.

Cite close interrelatedness between math and science

The National Science Education Standards, 1995

"Scientific literacy includes the interdependency of science with other subjects such as mathematics and technology."

Association for the Advancement of Science, 1989

"need for students to be scienctifically and mathematically literate"

Curriculum and Evaluation Standards for School Mathematics identifies that every level of K-12 Standards contains the 4 common process standards.

Connections

Reasoning