EEd 4 – Teaching Science in Elementary Grades PDF

Summary

This document is a course guide for teaching science in elementary grades, covering plants, animals, and matter. The course emphasizes teaching science process skills and different biological concepts. The text also includes questions for pre-assessment.

Full Transcript

BACHELOR OF ELEMENTARY EDUCATION
EEd 4 – Teaching Science in the
Elementary Grades

Elmer A. Irene, Ed.D.

College of Education
 i
1 Teaching Science in Elementary Grades

PREFACE

“Give me a fish and I eat for a day. Teach me to fish and I eat for a
lifetime.” This famous Chinese proverb would definitely inspire an aspiring
educator like you. Truly, it is the role of a teacher to teach students how to
fish, in simple words, it is your key part to teach your students to think. But
how will you teach a child the right way of trawling and grilling a fish if you
cannot even do these by yourself? How will you guide them into a lifetime
learning if you do not know what and how to lead them?
In this course, you will learn the science of teaching and learning
Biology and Chemistry concepts to Elementary students. Here, you should
have a “feel” of what it should be like not just as a teacher but as a learner
as well. When you put yourself on the shoes of being a learner, you realize
the importance of doing the right way of motivating, and not just
instructing. The authors hope that the principle of John Dewey’s learning
by doing and the science of learning will surface in your learning journey.
SO buckle up, sit back and relax, prepare your notebook and pen as
well as your gadget, and enjoy learning!

EAI
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TABLE OF CONTENTS

Page No.
Preface ---------------------------------------------------------------------- i

Table of Contents --------------------------------------------------------- ii

UNIT 1: Plants and Animals and their Habitats --------------------- 1

UNIT 2: Pedagogy in Teaching Biology Topics in Elementary
Grades------------------------------------------------------ ------------------ 19

UNIT 3: MATTER AND ITS RELEVANCE TO HUMANS --------------- 32
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UNIT 1: Plants and Animals and their Habitats
1.0 Intended Learning Outcomes
a. Describe the basic parts and function of plants and animals.
b. Recognize the relevance of science process skills in coming up with scientific
investigations/studies.
c. Execute an activity manifesting the different science process skills.

1.1. Introduction
In this unit, you will not just describe the basic parts and functions of specific concepts
in Biology, but you will also be manifesting to yourself the different science process skills that
your need to teach your students. These skills will be useful in understanding and executing
the lessons you will be learning in this course. Enjoy!
But first, let us have this pre-assessment.
Instruction: Read the following situations below and write in the provided space the
skills that a person must have in order to change the situations with positive outcomes.
Briefly explain why these skills are needed.

1. Julia Bartito was asked by a vendor how many liters of vegetable oil does her mother
requested her to buy. Julia is just 9-year-old and only know basic mathematics.
_________________________________________________________________________________
_________________________________________________________________________________
_________________________________________________________________________________
__________________________________________________________________________.
2. Gerald Andarla was brought by her mother in the City. They were buying groceries in
Lester Lace when her mother asked her to get two cans of large corned beef. He doesn’t know
where to find those cans.
_________________________________________________________________________________
_________________________________________________________________________________
_________________________________________________________________________________
___________________________________________________________________.

1.2 Plants and Animals and their Habitats
1.2.1 Basic and Integrated Science Process Skills

It was stated by Padilla (2018) that one of the most significant and prevalent goals of schooling
is to help our student to think. In order for the schools to achieve this goal, they must share
subjects that will develop the unique skills of the students. These skills include the emphasis
on hypothesizing, manipulating the physical world, and reasoning from data. And one of the
subjects that will advance our students to get these skills is teaching Science.
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Science Process Skills or SAPA (Science - A Process Approach) – are skills that are defined as a set
of broadly transferable abilities, appropriate to many science disciplines and reflective of the
behavior of scientists (Padilla, 2018). These skills are grouped into basic and integrated skills.

What are the Basic Science Process Skills?
(adapted from the online article of Padilla, 2018)

-Observing - using the senses to gather information about an object or event.
Example: Describing a pencil as yellow.

-Inferring - making an "educated guess" about an object or event based on previously gathered
data or information.
Example: Saying that the person who used a pencil made a lot of mistakes because the eraser
was well worn.

-Measuring - using both standard and nonstandard measures or estimates to describe the
dimensions of an object or event.
Example: Using a meter stick to measure the length of a table in centimeters.

-Communicating - using words or graphic symbols to describe an action, object or event.
Example: Describing the change in height of a plant over time in writing or through a graph.

-Classifying - grouping or ordering objects or events into categories based on properties or
criteria.
Example: Placing all rocks having certain grain size or hardness into one group.

-Predicting - stating the outcome of a future event based on a pattern of evidence.
Example: Predicting the height of a plant in two weeks’ time based on a graph of its growth
during the previous four weeks.

What are the Integrated Science Process Skills?
(adapted from the online article of Padilla, 2018)

-Controlling variables - being able to identify variables that can affect an experimental outcome,
keeping most constant while manipulating only the independent variable.
Example: Realizing through past experiences that amount of light and water need to be
controlled when testing to see how the addition of organic matter affects the growth of beans.

-Defining operationally - stating how to measure a variable in an experiment.
Example: Stating that bean growth will be measured in centimeters per week.

-Formulating hypotheses - stating the expected outcome of an experiment. Example: The greater
the amount of organic matter added to the soil, the greater the bean growth.

-Interpreting data - organizing data and drawing conclusions from it. Example: Recording data
from the experiment on bean growth in a data table and forming a conclusion which relates
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trends in the data to variables.

-Experimenting - being able to conduct an experiment, including asking an appropriate
question, stating a hypothesis, identifying and controlling variables, operationally defining
those variables, designing a "fair" experiment, conducting the experiment, and interpreting
the results of the experiment. Example: The entire process of conducting the experiment on
the effect of organic matter on the growth of bean plants.

-Formulating models - creating a mental or physical model of a process or event. Examples: The
model of how the processes of evaporation and condensation interrelate in the water cycle.

After studying several researches, Padilla (2018) found that (1) applying a set of
specific clues for predicting, (2) using activities and pencil and paper simulations to teach
graphing, and (3) using a combination of explaining, practice with objects, discussions and
feedback with observing, are the proven effective teaching strategies in learning the basic
process skills. Padilla (2018) also added that studies that emphasize the Science Curriculum
Improvement Study (SCIS) and SAPA indicate that if teachers will teach these skills,
elementary school students can retain the process skills abilities for forthcoming use instead
of just learning them. Thus, it was concluded that students will be able to learn the basic
skills if they will significantly be included in teaching methods or instruction.

On the other hand, we cannot expect our students to excel in demonstrating integrated
skills especially if they do not have experiences or did not practice these skills. Teachers
cannot assume that their students can master the experimenting skill if they practiced this in
few times. They must be given multiple opportunities to practice and work within different
content areas and contexts, and the teacher must be patient with this (Padilla, 2018).

Padilla (2018) then concluded that teachers need to select curricula which emphasize
science process skills. For us to give our students this opportunity to learn these science
process skills, we need to give them various activities may it be online, offline, or whatever
the trend that will definitely make our students want to learn more until develop these
important skills.
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1.2.2 Parts and Functions of Plants and Animals
1.2.2.1 Basic Parts and Functions of Plant and Animal Cells

You watched in the video the parts and
functions of different organelles found in the
Before you continue animal and plant cells. These are some of the
reading this part of the basic knowledge you need to know before you
lesson, scan the QR code or fully understand the complicated processes
go to the link provided happening in the life of all living organisms
and watch the video. that will lead you to conceptualizing strategies
in teaching Sciences. If you can’t remember
this lesson in your Junior and Senior High
https://www.youtube.com/watch?v=URUJD5NEXC8&f school, maybe try your best to reread and
eature=share
review all your Science notes to make sure you
can follow our lesson.

We all know that all life shares common characteristics. One known example and very
significant for us to know, is the existence of cells in all life forms. The Cell is the basic unit of
life. All the Biology books you will ever read will start from teaching us how the cell functions
up to how everything else gets complex. But although it is called the ‘basic’ unit of life, cell in
itself is already complicated (you can say that while watching the video). It has organelles
found in every single one of it and they, too, are as intricate as the cell.
According to the book of (Mader and Windelspecht, 2019), when we observe plants,
animals, and other organisms, it is important to realize that what we are also seeing is a vast
collection of cells that work together in a highly organized, regulated manner and thus conduct
the business of life. The cell is the smallest unit of living matter- but not for the non-living.
Thanks to the collective work of nineteenth-century scientists Robert Brown (1773–1858),
Matthias Schleiden (1804–1881), and Theodor Schwann (1810–1882) who in no other way
helped us and determined that plants and animals are composed of cells. Further work by the
German physician Rudolph Virchow (1821–1902) also helped us with the fact that cells actually
self-reproduce and that “every cell comes from a preexisting cell.” That resolved the curiosity
and facilitated us to understand that various illnesses of the body, such as diabetes and
prostate cancer, are due to cellular malfunction. We can also infer that all life on Earth today
came from cells in ancient times, and that all cells are related in some way. In reality, a
continuity of cells has been present from generation to generation, which means the very first
cell is the ancestor of the cells that do the works inside us.
The work of Schleiden, Schwann, and Virchow helped created the cell theory. It states
that (Mader and Windelspecht, 2019):

1. All organisms are composed of cells.
2. Cells are the basic units of structure and function in organisms.
3. Cells come only from preexisting cells because cells are self-reproducing.

Fundamentally, there are two different types of cells that exist in nature. The Prokaryotic
cells lack a membrane-bound nucleus while Eukaryotic cells possess a nucleus.
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Prokaryotes as a group are one of the most abundant and diverse life-forms on Earth,
and they are present in great numbers in the air, water, and soil, as well as living in and on
other organisms. What distinguishes eukaryotic cells is the presence of a nucleus and internal
membrane-bound compartments, called organelles. Nearly all organelles are surrounded by a
membrane with embedded proteins, many of which are enzymes.
A baseline understanding of cell structure and function will be helpful when you study
the function of specialized cells. Overall, the cell can be seen as a system of interconnected
organelles that work together to metabolize, regulate, and conduct life processes. The
following is a summary of organelles found in the animal and plant cells and their functions
(Campbell et al, 2017):
Nucleus- “headquarter” or the control center of the cell. The nucleus has three
recognizable regions or structures: the nuclear envelope, nucleolus, and chromatin.
Nuclear envelope- double membrane enclosing the nucleus; perforated by
pores; continuous with Endoplasmic Reticulum.
Nucleolus- non-membranous structure involved in production of ribosomes; a
nucleus has one or more nucleoli.
Chromatin- material consisting of DNA and proteins; visible in a dividing cell
as individual condensed chromosomes.

Plasma membrane- membrane enclosing the cell.

Ribosomes- complexes that make proteins; free in cytosol or bound to rough ER or
nuclear envelope.

Golgi apparatus- organelle active in synthesis, modification, sorting, and secretion
of cell products.

Lysosome- digestive organelle where macromolecules are hydrolyzed.

Mitochondrion- organelle where cellular respiration occurs and most ATP is generated.

Peroxisome- organelle with various specialized metabolic functions; produces hydrogen
peroxide as a by-product and then converts it to water.

Microvilli- projections that increase the cell’s surface area.

Cytoskeleton- reinforces cell’s shape; functions in cell movement; components are made
of protein. Includes: microfilaments, intermediate filaments and microtubules.

Centrosome- region where the cell’s microtubules are initiated; contains a pair of
centrioles.

Flagellum- motility structure present in some animal cells, composed of a cluster of
microtubules within an extension of the plasma membrane.

Endoplasmic Reticulum (ER)- network of membranous sacs and tubes; active in
membrane synthesis and other synthetic and metabolic processes; has rough (ribosome-
studded) and smooth regions.
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Cytoplasm- semifluid matrix outside nucleus that contains organelles.

Chloroplast*- carries out photosynthesis, producing sugars.

Cell wall*- outer surface that shapes, supports, and protects cell.

Central vacuole*: large, fluid-filled sac that stores metabolites and helps maintain turgor
pressure.
* only found in plant cells.

Plant Cell Animal Cell
Cell wall is present. No cell wall is present.
Cells connect with plasmodesmata. Cells connects with various junctions.
Cell division involves a cell plate. Cell division involves a cleavage furrow.
No centrioles are present during Centrioles are present during mitosis.
mitosis.
Plastids are present. No plastids are present.
Vacuoles are large. Vacuoles are small or absent.

Table 1.1. Comparison between Animal and Plant Cell. Mader and Windelspecht (2019)

1.2.2.2 Plant and Animal Tissues
PLANT TISSUES
The body of a plant is organized in a similar fashion to the body of an animal. Tissue is
composed of specialized cells that perform a particular function, and an organ is a structure
made up of multiple tissues. In the case of a plant, embryo first begins to develop and its first
cells are called meristem cells. Like animal stem cells, plant meristem cells are undifferentiated
cells that can divide indefinitely and give rise to many types of differentiated cells. As new
cells are produced, they are small and boxlike, with a large nucleus and tiny vacuoles. As these
cells mature, they assume many different shapes and sizes, each related to the cell’s ultimate
function. When a seed germinates and an embryo grows, meristem tissue is present at the tips,
or apices, of the young plant and are called apical meristems. Apical meristems in turn give
rise to three specialized meristems that create the differing plant tissues (Mader and
Windelspecht, 2019).

Mader and Windelspecht (2019)
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The following are the plant tissues presented by Mader and Windelspecht (2019):

Epidermal Tissue
The entire body of both
nonwoody (herbaceous) and young
woody plants contains closely packed
epidermal cells called the epidermis.
The walls of epidermal cells that are
exposed to air are covered with a waxy
cuticle to minimize water loss. The
cuticle also protects against bacteria
and other organisms that might cause
disease. In roots, certain epidermal
cells have long, slender projections
called root hairs. The hairs increase
the surface area of the root for
absorption of water and minerals, as
well as anchoring the plant to various
substrates. On stems, leaves, and
reproductive organs, epidermal cells
produce hairs, called trichomes, that
have two important functions: to
protect the plant from too much sun and
moisture loss and to discourage herbivory
(plant eating). In leaves, the lower Mader and Windelspecht (2019)
epidermis of eudicots and both
surfaces of monocots contain Figure 1.1. The Epidermal Tissue
specialized cells called guard cells.
Guard cells, which are epidermal cells with chloroplasts, surround microscopic pores called
stomata. When the stomata are open, gas exchange and water loss occur.

In plants with wood, the epidermis of the stem is replaced by cork cells. New cork cells
are made by a meristem called cork cambium. This entire cork area of the plant is called the
periderm. As the new cork cells mature, they increase slightly in volume, and their walls
become encrusted with suberin, a lipid material, so that they are waterproof and chemically
inert. The cork cambium overproduces cork in certain areas of the stem surface, causing ridges
and cracks to appear. These features on the surface are called lenticels. Lenticels are the site of
gas exchange between the interior of a stem and the air. Study figure 1.1 to know the structures
of the terms mentioned.
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Ground Tissue
Ground tissue forms the bulk of a flowering plant; it contains parenchyma,
collenchyma, and sclerenchyma cells (see figure 1.2).
Parenchyma cells are the most abundant and correspond best to the typical plant cell.
These are the least specialized of the cell types and are found in all the organs of a plant. They
may contain chloroplasts and carry-on photosynthesis, or they may contain colorless plastids
that store the products of photosynthesis. Parenchyma cells can divide and give rise to more
specialized cells, as when roots develop from stem cuttings placed in water.
Collenchyma cells are like parenchyma cells except they have thicker primary walls.
The thickness is uneven and usually involves the corners of the cell. Collenchyma cells often
form bundles just beneath the epidermis and give flexible support to immature regions of a
plant body. The familiar strands in celery stalks are composed mostly of collenchyma cells.
Sclerenchyma cells have thick secondary cell walls impregnated with lignin, which is a
highly resistant organic substance that makes the walls tough and hard. Most sclerenchyma
cells are dead at maturity; their primary function is to support the mature regions of a plant.
Two types of sclerenchyma cells are fibers and sclereids. Fibers are long and slender and may
be grouped in bundles, which are sometimes commercially important. Hemp fibers can be
used to make rope, and flax fibers can be woven into linen. Flax fibers, however, are not
lignified, which is why linen is soft. Sclereids, which are shorter than fibers and more varied
in shape, are found in seed coats and nutshells. Sclereids, or “stone cells,” are responsible for
the gritty texture of pears and the hardness of nuts and peach pits.

Mader and Windelspecht (2019)

Figure 1.2. The Ground Tissue

Vascular Tissue
There are two types of vascular tissue. Xylem transports water and minerals from the
roots to the leaves, and phloem transports sucrose and other organic compounds, usually from
the leaves to the roots. Both xylem and phloem are considered complex tissues, because they
are composed of two or more kinds of cells. In the roots, the vascular tissue is located in the
vascular cylinder; in the stem, it forms vascular bundles; and in the leaves, it is found in leaf
veins.
Xylem contains two types of conducting cells: tracheids and vessel elements, which
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are modified sclerenchyma cells. Both types of conducting cells are hollow and dead, but the
vessel elements are larger, may have perforation plates in their end walls, and are arranged to
form a continuous vessel for water and mineral transport.
The elongated tracheids, with tapered ends, form a less obvious means of transport,
but water can move across the end walls and side walls, because there are pits, or depressions,
where the secondary wall does not form. In addition to vessel elements and tracheids, xylem
can contain sclerenchyma fibers that lend additional support as well as parenchyma cells that
store various substances. Vascular rays, which are flat ribbons or sheets of parenchyma cells
located between rows of tracheids, conduct water and minerals across the width of a plant.
The conducting cells of phloem are specialized parenchyma cells called sieve-tube
members, arranged to form a continuous sieve tube. Sieve-tube members contain cytoplasm
but no nuclei. The term sieve refers to a cluster of pores in the end walls, which is known as a
sieve plate. Each sieve-tube member has a companion cell, which contains a nucleus. The two
are connected by numerous plasmodesmata, and the nucleus of the companion cell may
control and maintain the life of both cells. The companion cells are also believed to be involved
in the transport function of phloem. Sclerenchyma fibers also lend support to phloem.

ANIMAL TISSUES
According to what Charles Darwin (1909) noted on his book “Origin of Species”, while
the planet Earth has cycled year after year around the sun, “endless forms most beautiful and most
wonderful” have appeared and will keep on appearing. This statement only shows that there
are variety of animals in the world that were discovered and will be discovered in several
times.
But despite that diversity, as stated by Mader and Windelspecht (2019), animals have an
unbroken thread of unity, provided by evolution from a common ancestor. At the biosphere
level, animals are heterotrophic consumers that require a constant supply of food, ultimately
supplied by the autotrophs at the base of the food chain. At the organismal level, organs are
composed of tissues, and each type of tissue has cells that perform specific functions. Let us
take a brief discussions of the tissues found in the animals (Mader and Windelspecht, 2019):

Epithelial Tissue
Epithelial tissue, also called epithelium, consists of tightly packed cells that form a
continuous layer. Epithelial tissue covers surfaces and lines body cavities. Usually, it has a
protective function, but it can also be modified to carry out secretion, absorption, excretion,
and filtration. Epithelial cells may be connected to one another by three types of junctions
composed of proteins. Regions where proteins join them together are called tight junctions.
Epithelial tissues are often exposed to the environment on one side, but on the other side
they are attached to a basement membrane. The basement membrane is simply a thin layer of
various types of proteins that anchors the epithelium to the extracellular matrix, which is often
a type of connective tissue.
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There are five (5) types of epithelial tissue:
1. Simple epithelia have only a single layer of cells and are classified according to cell type:
a. Squamous epithelium- is composed of flattened cells, lines blood vessels and the air
sacs of lungs.
b. Cuboidal epithelium- contains cube-shaped cells and is found lining the kidney
tubules and various glands.
c. Columnar epithelium- has cells resembling rectangular pillars or columns, with
nuclei usually located near the bottom of each cell.
2. Stratified epithelia have layers of cells piled one on top of the other. Only the bottom layer
touches the basement membrane.
3. Glandular Epithelia is when an epithelium secretes a product. A gland can be a single
epithelial cell, as in the case of mucus-secreting goblet cells within the columnar epithelium
lining the digestive tract, or a gland can contain many cells.
a. Exocrine glands- secrete their product into ducts.
b. Endocrine glands- have no duct, and secrete hormones internally, so they are
transported by the bloodstream.

Connective Tissue
Connective tissue is the most abundant and widely distributed tissue in complex
animals. It is quite diverse in structure and function; even so, all types have three components:
specialized cells, ground substance, and protein fibers.
The ground substance is a noncellular material that separates the cells and varies in
consistency from solid to semifluid to fluid. The fibers are of three possible types. White
collagen fibers contain collagen, a protein that gives them flexibility and strength. Reticular
fibers are very thin collagen fibers that are highly branched and form delicate supporting
networks. Yellow elastic fibers contain elastin, a protein that is not as strong as collagen but is
more elastic. The ground substance plus the fibers together are referred to as the connective
tissue matrix. Connective tissue is classified into three major categories:
1. Fibrous Connective Tissue- both loose fibrous and dense fibrous connective tissues have
cells called fibroblasts, located some distance from one another and separated by a jellylike
matrix containing white collagen fibers and yellow elastic fibers.

a. Loose fibrous connective tissue:
o has space between components.
o occurs beneath skin and most epithelial layers.
o functions in support and binds organs.

b. Adipose connective tissue:
o cells are filled with fat.
o occurs beneath skin, around heart and other organs.
o functions in insulation, stores fat.
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c. Dense fibrous connective tissue
o has collagenous fibers closely packed.
o in dermis of skin, tendons, ligaments.
o functions in support.
2. Supportive Connective Tissue- provide structure, shape, protection, and leverage for
movement. Cartilage and bone are the two main supportive connective tissues.
a. Cartilage. The cells lie in small chambers called lacunae, separated by a matrix that
is solid yet flexible. Unfortunately, because this tissue lacks a direct blood supply, it
heals very slowly. There are three types of cartilage, distinguished by the type of fiber
in the matrix.
o Hyaline cartilage- the most common type of cartilage, contains only very fine
collagen fibers. The matrix has a white, translucent appearance. It is found in
the nose and at the ends of the long bones and the ribs, and it forms rings in
the walls of respiratory passages. The fetal skeleton also is made of this type of
cartilage.
o Elastic cartilage- has more elastic fibers than hyaline cartilage. For this reason,
it is more flexible and is found, for example, in the framework of the outer ear.
o Fibrocartilage has a matrix containing strong collagen fibers. Fibrocartilage is
found in structures that withstand tension and pressure, such as the pads
between the vertebrae in the backbone and the wedges in the knee joint.
b. Bone. Of all the connective tissues, bone is the most rigid. It consists of an extremely
hard matrix of inorganic salts, notably calcium salts, deposited around protein fibers,
especially collagen fibers. The inorganic salts give bones rigidity, and the protein
fibers provide elasticity and strength, much as steel rods do in reinforced concrete.
o Compact bone makes up the shaft of a long bone. It consists of cylindrical
structural units called osteons.
o Spongy bone contains numerous bony bars and plates, separated by irregular
spaces. Although lighter than compact bone, spongy bone is still designed for
strength, just as braces are used for support in buildings.
3. Fluid Connective Tissues- (blood) which consists of formed elements and plasma, is a fluid
connective tissue located in blood vessels. Formed elements in the blood consist of the many
kinds of blood cells and the platelets. Blood transports nutrients and oxygen to interstitial fluid
and removes carbon dioxide and other wastes. It helps distribute heat and plays a role in fluid,
ion, and pH balance.
o Red Blood Cells- Contains a red color pigment called hemoglobin which helps
in transportation of oxygen.
o White Blood Cells- These cells help to fight against infections.
o Platelets- helps in clotting of blood.
o Lymph- It helps in the transportation of substances.
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Muscular Tissue
Muscular (contractile) tissue is composed of cells called muscle fibers. Muscle fibers contain
actin filaments and myosin filaments, whose interaction accounts for movement. The muscles
are also important in the generation of body heat. There are three distinct types of muscle
tissue:
1. Skeletal muscle- also called voluntary muscle is attached by tendons to the bones of the
skeleton, and when it contracts, body parts move. Contraction of skeletal muscle is under
voluntary control and occurs faster than in the other muscle types. Skeletal muscle fibers are
cylindrical and quite long—sometimes they run the length of the muscle.
2. Smooth (visceral) muscle- is so named because the cells lack striations. The spindle-shaped
cells, each with a single nucleus, form layers in which the thick middle portion of one cell is
opposite the thin ends of adjacent cells. Smooth muscle is not under voluntary control and
therefore is said to be involuntary. Smooth muscle, found in the walls of viscera (intestine,
stomach, and other internal organs) and blood vessels, contracts more slowly than skeletal
muscle but can remain contracted for a longer time. When the smooth muscle of the intestine
contracts, food moves along its lumen (central cavity). When the smooth muscle of the blood
vessels contracts, blood vessels constrict, helping raise blood pressure.
3. Cardiac muscle- is found only in the walls of the heart. Its contraction pumps blood and
accounts for the heartbeat. Cardiac muscle combines features of both smooth muscle and
skeletal muscle. Like skeletal muscle, it has striations, but the contraction of the heart is
involuntary for the most part. Cardiac muscle cells also differ from skeletal muscle cells in that
they usually have a single, centrally placed nucleus. The cells are branched and seemingly
fused one with the other, and the heart appears to be composed of one large, interconnecting
mass of muscle cells.

Nervous Tissue
Nervous tissue contains nerve cells called neurons and supporting cells called neuroglia. An
average human body has about 1 trillion neurons. The nervous system conveys signals termed
nerve impulses throughout the body.
1. Neuron is a specialized cell that has three parts: dendrites, a cell body, and an axon. A
dendrite is a process that conducts signals toward the cell body. The cell body contains the
major portion of the cytoplasm and the nucleus of the neuron. An axon is a process that
typically conducts nerve impulses away from the cell body. Long axons are covered by myelin,
a white, fatty substance. The term fiber is used here to refer to an axon along with its myelin
sheath, if it has one. Outside the brain and spinal cord, fibers bound by connective tissue form
nerves.
2. Neuroglia outnumber neurons as much as ten to one, and they make up approximately half
the volume of the organ. Although the primary function of neuroglia is to support and nourish
neurons, recent research has shown that some neuroglia directly contributes to brain function.
Several types of neuroglia are found in the brain: microglia, astrocytes, and oligodendrocytes.
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1.2.2.3 Organs and Organ Systems of Animals
As discussed by Mader and Windelspecht (2019), an organ is composed of two or more
types of tissues working together to perform a particular function. For example, a kidney is an
organ that contains a variety of epithelial and connective tissues, and these tissues are
specialized for the function of eliminating waste products from the blood. In most animals,
individual organs function as part of an organ system. An organ system contains many
different organs that cooperate to carry out a general process, such as the digestion of food.
Similar types of organ systems are found in most invertebrates, as well as in all vertebrate
animals. These organ systems carry out the life processes that all of these animals, including
humans, must carry out.
Below is the summary of the contributions of each organ system to the human body
(Longenbaker, 2017):
o Integumentary System—external support and protection of body; helps maintain
body temperature.
o Skeletal System—internal support and protection; body movement; production
of blood cells.
o Muscular System—body movement; production of heat that maintains body
temperature.
o Nervous System—regulatory center for control of all body systems; learning and
memory.
o Endocrine System—Secretion of hormones for chemical regulation of all body
systems.
o Cardiovascular System—transport of nutrients to body cells and transport of
wastes away from cells.
o Lymphatic System—drainage of tissue fluid; purifies tissue fluid and keeps it
free of pathogens.
o Respiratory System—rids the blood of carbon dioxide and supplies the blood
with oxygen; helps maintain the pH of the blood.
o Digestive System—breakdown of food and absorption of nutrients into blood.
o Urinary System—maintenance of volume and chemical composition of blood.
o Reproductive System—Production of sperm and egg; transfer of sperm to female
system where development occurs.

INDEPENDENT LEARNING. As you can observe in the above list, there are numbers of organ systems which
work together for a living organism to function well. Each of these organ systems have many different organs that
cooperate to carry out a general process.

For you independent learning, look for references, as many as you can, or one reference if you want (whichever is
convenient to you) and study the different organs of all the organ systems. Remember that questions on your
summative tests will include this part, so you have to do your best to familiarize the organs of the organ systems.
 1| Teaching Science in Elementary Grades 14

1.2.2.4 The Shoot System and Root System

The body of a plant consists of a root system and a
shoot system. The shoot system contains the stem and
leaves, two types of plant vegetative organs. Axillary
buds can develop into branches of stems or flowers, the
reproductive structures of a plant. The root system is
connected to the shoot system by vascular tissue
(brown) that extends from the roots to the leaves
(Mader and Windelspecht, 2019).
The shoot system of a plant is composed of the
stem, the branches, and the leaves. A stem supports the
leaves in a way that exposes each one to as much
sunlight as possible. In addition, the stem transports
materials between roots and leaves and produces new
tissue. At the end of a stem, a terminal bud contains an
apical meristem and produces new leaves and other
tissues during the initial primary growth of a plant (see
fig. 1.3). Lateral (side) branches grow from a lateral
bud located at the angle where a leaf joins a stem. A
node occurs where a leaf or leaves are attached to the
stem, and an internode is the region between nodes.
Vascular tissue transports water and minerals
from the roots through the stem to the leaves and
transports the products of photosynthesis, usually in Mader and Windelspecht (2019)
the opposite direction.
The root system simply consists of the roots. Figure 1.3. Organization of a Plant body
The root tip also contains an apical meristem and
results in primary growth downward.
Ultimately, the three vegetative organs—the root, the stem, and the leaf—perform
functions that allow a plant to live and grow.

LET’C CHECK YOUR PROGRESS!
To understand more
the difference Briefly answer the following questions below.
between the shoot
and the root system.
Scan this QR code. 1. Describe how the plant body is organized?
____________________________________________________________
____________________________________________________________
____________________________________________________________

2. List the three vegetative organs in a plant, and state their major
functions.
____________________________________________________________
____________________________________________________________
___________________________________________________________
 1| Teaching Science in Elementary Grades 15

ASSESSMENT
Quiz No. 1. Label the parts of the plant and animal shown below and describe the function of
each part in the table that follows.
Plant Animal

Plant
Part Function
 1| Teaching Science in Elementary Grades 16

Animal
Part Function

Quiz No. 2 Research two scientific investigations/studies about the plant and animal cell.
Write the title of the study and summarize the results and discussions. List all the science
process skills you think were used and how each of these skills contributed in the conduct
of each study.

___________________________________________
(Title of the study)
Summary:
____________________________________________________________________________
__________________________________________________________________________________
__________________________________________________________________________________
__________________________________________________________________________________
__________________________________________________________________________________
__________________________________________________________________________________
__________________________________________________________________________________
__________________________________________________________________________________
______________________________________________________.

List of Science Process Skills and their contribution: (Give at least three skills)
__________________-_______________________________________________________________.
__________________-_______________________________________________________________.
__________________-_______________________________________________________________.
 1| Teaching Science in Elementary Grades 17

___________________________________________
(Title of the study)
Summary:
____________________________________________________________________________
__________________________________________________________________________________
__________________________________________________________________________________
__________________________________________________________________________________
__________________________________________________________________________________
__________________________________________________________________________________
__________________________________________________________________________________
__________________________________________________________________________________
______________________________________________________.

List of Science Process Skills and their contribution: (Give at least three skills)
__________________-_______________________________________________________________.
__________________-_______________________________________________________________.
__________________-_______________________________________________________________.

Class Participation 1. Demonstrate through a Tiktok video how will you execute a specific
activity manifesting the different science process skills. (Non-tiktok users may only send a
short video.)

1.3 References

Darwin, C. (1909). The origin of species. New York: PF Collier & son.

Longenbaker, Susannah N. (2017) Mader’s Understanding Human Anatomy & Physiology,
Ninth Edition. McGraw Hill Education.

Mader, Sylvia S. and Windelspecht (2019). BIOLOGY 13th Edition: McGrew-Hill Education.
2 Penn Plaza, New York, NY 10121.

Nuclues Medical Media. (2015). Biology: Cell Structure [Video].
https://www.youtube.com/watch?v=URUJD5NEXC8&feature=share

Smith, Gorrzynski *(2013). General, Organic & Biological Chemistry: McGrew-Hill
International Edition.

1.4 Acknowledgment

The images, tables, figures and information contained in this module were taken from
the references cited above.
 1

2 | Teaching Science in Elementary Grades 19

UNIT 2: Pedagogy in Teaching Biology Topics in Elementary Grades

2.0 Intended Learning Outcomes
a. Describe the basic parts and function of plants and animals.
b. Recognize the relevance of science process skills in coming up with scientific inves-
tigations/studies.
c. Execute an activity manifesting the different science process skills.

2.1. Introduction
Considering the Enhanced Basic Education curriculum, teaching should follow a
spiral progression of concepts which means learners should encounter formal education
from most basic to the most complex as they engage in the learning process (Department
of Education, 2013). Take note, in the K-12 curriculum, teaching Biology or Physics or
Chemistry alone is no longer the trend. All these branches are being taught in the same
school year. However, in this lesson, we will focus on how you should deliver Biology
topics among learners in the secondary level.

To make students’ learning more authentic, they should be taught in a way that
Science, citizenship, and sustainable development are tackled at the same time. This may
tell us that our teaching should be guiding principles to inform action (Howe et al., 2017).
Going out of the classroom is one of the most obvious learning activities that would
involve students in learning outdoor while they’re using multisensory faculties such as in
an activity called “earthwalks” which requires both kinesthetic and emotional levels of the
students.
You may introduce sustainable development by presenting the following text from Earth
Charter (www.earthcharter.org):

Earth, our home, is alive with a unique community of life. The forces of nature make existence
a damaging and uncertain adventure, but Earth has provided the conditions essential to life’s
evolution The resilience of the community of life and the well-being of human depend upon
reserving a healthy biosphere with all its ecological systems, a rich variety of plants and
animals, fertile soil, pure waters, and clean air. The global environment with its finite
resources is a common concern of all peoples. The protection of Earth’s vitality, diversity, and
beauty is a sacred trusts.

From the above Earth Charter, there are four principles as follows:
1. Respect Earth and life in all its diversity;
2. Care for the community of life with understanding, compassion and love.
3. Build democratic societies that are just, participatory, sustainable and peaceful;
4. Secure Earth’s bounty and beauty for present and future generation.
Thus, we should teach our students in a way that helps them understand and appreciate
the beauty and complexity of living things and their habitats.
 2

2 | The Teaching of Science 20

2.1.1 Teaching in Biology through Cross-curricular Opportunities & Use of Appropriate
Instructional Materials (IMs)

In as far as Biology is concerned, at first what you may do is let students grasp under-
standing of the key concepts in Biology and later engage them in activities which help
them elaborate and apply their knowledge about those concepts.

Some examples include the following (Howe et al., 2017):

1. Students can apply their knowledge about living and non-living things if you will ask
them to collect and classify these things, the possible way they can;
2. Students can compare and contrast seasonal change if they will be allowed to share
their own understanding about their own experience in a winter or summer;
3. Students may be asked to illustrate a food chain and they should give emphasis on
arrow direction indicating matter ad energy flow from producers to consumers. They
may also refer humans as part of the food chain being the consumers;
4. Students may apply their knowledge and would acquire better understanding of
microorganisms if they will share their own observation on a spoiled food and relate
spoilage to the growth of microbes. Aside from this, they may also share what their
parents tell them when they are asked to practice good personal hygiene;
5. Students may grasp an understanding of adaptation and evolution if they will be asked
of the following:

a. Where do plants and animals live?
b. Why do they live there?
c. What kind of living things can thrive in a certain habitat? Why?
6. We may ask students to look at plants available in the market or go to a garden or farm
or have a classroom display of plants. In this way, they may have exploration of the
structure plants and from there, we may integrate the key concepts on seed
development, photosynthesis and plant growth;

7. We may be able to teach well our students about the levels of biological organization by
asking them to describe their own body structure and let them explain their own
observation on the functions of these body structures;

8. Growth and reproduction can be understood by our students by asking them the
following questions:

a. What makes you grow?
b. Have you changed since you were born?
c. What changes do you observe among people as they age?
9. We can help our students to have better understanding of the application of the key
concepts of biology if we would introduce them medicine and other related industries.
 3

2 | The Teaching of Science 21

According to the research Igiri and Effiong (2015), the use of IMs aid teachers to
make teaching biology real and permanent and the proper presentation of good IMs the
way teachers employ them in the instruction enhance the understanding of the subject
matter being taught.
Table 2. Some IMs used in Teaching Biology
IMs Description When to use/importance
Is a replica of something** Models are used so students may form concepts in their
minds about the subject matter at hand**
They are used to provide students with nonverbal ways
Models* A simplified representation of a to express understanding; when consistently used,
more complex system *** models give students practice and confidence in
speaking to explain their observations***

Are ideal visual aids because they are reality which are
Objects** It is the thing itself or a realia used whenever possible to obtain so students can have
direct contact with them during laboratory or study**

A sample or part of an Excellent visual aids used to present a sample of part of
Specimens**
object**** the whole object**
A visit to a museum can be done when we want our
students have first hand observation of cultural heritage
A place where objects are and other symbolic objects to expand students’ world
Museum**
exhibited***** knowledge and when we want to teach critical thinking,
empathy, and disposition among our students*******

A graphic representation show-
These are best used in class when students need to focus
ing information in a simple way
Charts* only on the most important infographics and make
which often use lines and
interpretations.
curves.******
Are photographs or tools that
They are used to display projects, develop research or a
Posters*** enable visualization in the
particular perspective for class to consider******
classroom******
A representation on a flat
This is used in biology class when students need to spot
Maps*** surface of the whole or part of
specific places or need to be guided during a field trip
an area*****
Is a spherical or rounded repre- Just like maps, globe can be used by students when they
Globe*** sentation of the earth, a celestial need to spot places or look into the globe lines while
body or heavens***** studying them
Are real specimen of a
Preserved particular organism that is Ideally, they can be used during laboratory activity that
specimen* preserved using formalin or required dissection
alcohol
An instrument that produces
This is basically used when students need to observe
Microscope* enlarged images of small
specimens that cannot be seen by unaided eye
objects or specimen********
Sources: *Olangunju (2000); **Heiss (1938);***Igiri and Effiong (2015);****Bryce et al(2015);
*****Cambridge dictionary (n.d.); ******Manarin (2016); *******Shulman (2013);
********Shreiber (2020)
 4

2 | The Teaching of Science 22

Table 2. Some IMs used in Teaching Biology (cont.)

IMs Description When to use

A set of tools and apparatuses used for growth
of desired organisms, usually microbes; the set Can be used when students need to
Culture includes test tubes, petri dish, growth culture microorganisms for study in
equipment* mediums (both and liquid), inoculation loops, their laboratory activities or research
pipettes and tips, incubators, autoclaves, undertaking
laminar flow hoods and microscope**

Used to exemplify scientific concepts
Are representation of situations or processes thereby allowing students to explore
by means of something analogous. They may the nature of things***
Simulations*
be computer simulations to represent the real Also helps improve students’ learning
world*** by trying ideas, changing variables
and run hypothetical experiments****

Sources: *Olangunju (2000); **labcompare (2020); ***Fleming (2018);****Baybe (1989)

CLASS PARTICIPATION
DIRECTIONS: Choose one from the application activities below. Your option should
complement the available learning resources you have. Please use a
SCRATCH PAPER for your task accomplishment.

A. Choose appropriate learning opportunities and IMs that will match your topic
discussion based on your option under ‘Let’s Do This’ activity in page 35. You
may select as many as you want. Explain their congruency by writing at most 5
sentences for each.

B. Interview 2 Junior or Senior High school students in you neighborhood. Ask them
if they are familiar with the IMs presented in this lesson and when and how their
science teachers employ these IMs in their class. Explain how well their teachers
know when to employ these IMs. Limit your answer in 10 sentences.
 5

2 | The Teaching of Science 23

LET’S HAVE AN ASSESSMENT…

MULTIPLE CHOICE: Choose the best answer and write your answer on a scratch paper.
There may be items with more than 1 correct answer. (Graded as short quiz)

1. Teacher C wants the students to have a first hand experience of the realia to make
learning authentic. Which of the following IMs should be used?
a. Models b. Simulations c. Specimens d. Objects
2. The anticipation of the teacher is to let students compare and contrast seasonal changes.
What is the most appropriate IMs to be used if having outdoor activity is impossible?
a. Museum b. Simulations c. Charts d. Maps and Globe
3. Which among the following supports best cross-curricular opportunities as applied in
teaching biology concepts?
a. Teachers of the same field will be having a symposium where students can listen
to a speaker who will talk about their own field of specialization
b. Students may be given the opportunity to work with students coming from
different programs and design a collaborative work to be implemented later.
c. Teacher L is a PE teacher currently working with a MAPEH teacher to plan for the
best opening salvo that their students will perform in the coming charter day.
d. A group of student-researchers are tasked to deal with the achievement levels of
student-respondents in their program.
4. Simulations are used to exemplify scientific concepts thereby allowing students to
explore the nature of things.
a. True b. False c. Sometimes true d. Wrong
5. Teacher A want her students to observe minute things and will ask them to illustrate their
observation during the laboratory reporting session. Which of the following is the most
appropriate IMs to be used?
a. Microbiology equipment c. Microscope
b. Preserved specimens of microbe d. Microscope and specimens

SCORING GUIDE:

Each correct option is 2 points
 6

2 | The Teaching of Science 24

2.1.2 Working Scientifically

Perhaps the easiest way to let students work scientifically is to engage them in
practical activities. For instance, if the subject matter is the needs of life, students may be
provided with opportunities to learn the needs of life: air (oxygen), water, and habitat,
learners may have encounter with pets, visit a zoo and ask people who look after them.
However, teachers need to ask consent from the parents of there students (Howe et al.,
2017).

Students may also be given chances to learn how to use survey tools to apply some
techniques as shown in the following table.
Table 3. Ideas for Ecosystem Surveys

Type of
Example of Activities Outcomes Learning Outcomes
Survey
Descriptive Make an annotated  A collection of sketches that Students will find out about the
sketch of the ecosys- can be made into a book for different kinds of living things in
tem including plants, students to compare the environment, identify
animals soils etc. similarities & differences between
Note the ‘good’ and  A list of like & dislikes local environments and ways in
‘bad’ aspects of the about the environment from which these affect the living
environment the students’ perspective things found there.

Spatial Use simple mapping  A scale plan & cross section
techniques to make a of the ecosystem
Students will identify similarities
plan & cross-section of
 A wall display of the plan or & differences between local envi-
the ecosystem on
cross section e.g. ‘our pond’ ronments and ways in which
which the position of
showing above and below these affect the living things
the different types of
ground and water level found there.
living things can be
plotted
Physical Use of scales or meas-  A list of abiotic factors of the
uring devices, includ- ecosystem. Notes about how
ing data-loggers, to wet or dry the soil was in
record the factors and different areas. Graphs or Students can analyze the abiotic
gradients of the physi- contour maps showing key factors in the local environment
cal environment such measurements
as wind, temperature,
light, and sound levels
Numerical Use of sampling tech-  A pyramid of numbers
niques to estimate the showing different popula- Students will identify similarities
populations of differ- tions of living things & differences in the local environ-
ent species. Use metre- ment
 A food chain showing the
square quadrat, repeat
relationship between living Students will learn the feeding
and multiply until
things found in the habitat relationships in a habitat
estimated population
is found
 7

2 | The Teaching of Science 25

Table 3. Ideas for Ecosystem Surveys (cont.)
Type of
Example of Activities Outcomes Learning Outcomes
Survey
Temporal Study a plant and how it  A ‘tree diary’ from wet to
changes over time dry season. A set of photo- Students will learn about
Study an ecosystem over graphs & captions showing the seasonal changes and
time, making a record of its changes in the environment how it affects the
appearance, the weather, & populations during a populations
and living things to be seen school year

Managerial Interview adults how the Students will learn to
ecosystem is cared for and  A fact-like presentation
discuss & consult with
managed. Find out what dossier that can be present-
different members of the
information exists about the ed to the school administra-
school community. They
ecosystem that would be tors or parent-teacher
will learn to work in
useful to help maintain & association about a local
groups, to democratically
improve the biodiversity of environment & what needs
agree priorities for
to be done to improve it.
the ecosystem change.
Source: Howe et al. (2017)

Students may also conduct other activities requiring scientific inquiries and research skills where they
can apply the integrated science process skills often regarded as ‘scientific method’.

 Formulating Hypothesis. Stating the proposed
solutions to a problem or expected outcomes for
experiments.
 Identifying Variables Stating the changeable
factors that can affect an experiment. It is im-
portant to change only the variable being tested
and keep the rest constant.
independent variable: a factor that is
manipulated in an experiment
dependent variable: a factor that is test-
ed/measured to determine its response
controlled variable: a factor that is kept
constant in an experiment
 Defining Variables Operationally. Explaining
how to measure a variable in an experiment.
 Describing Relationships between Variables.
Explaining relationships between the inde- Source: Lancour (2009)
pendent and dependent variables.
 Analyzing Investigations and their Data. Inter-
 Experimenting. Carrying out an experiment by preting data, identifying errors, evaluating the hy-
carefully following directions of the procedure pothesis, formulating conclusions, and recom-
so the results can be verified by repeating the mending further testing where necessary.
procedure several times.
 Understanding Cause-Effect Relationships.
 Acquiring Data. Collecting qualitative and Providing reasons on what caused to what happen
quantitative data as observations and measure- and why.
ments.
 Formulating Models. Recognizing patterns in data
 Organizing Data in Tables and Graph. Mak- and making comparisons to familiar objects or
ing appropriate data tables and graphs for data ideas.
 8

2 | The Teaching of Science 26

CLASS PARTICIPATION

DIRECTIONS: Analyze each statement and determine if it is TRUE or FALSE.
Explain your answer in 2 sentences for each item.

1. In a managerial survey, students will be able to work with different members of
the school community and discuss things democratically.
__________________________________________________________________________
__________________________________________________________________________
__________________________________________________________________________
___________________________________________.
2. Students may conduct temporal activities to learn about seasonal changes in a lo-
cal environment.
__________________________________________________________________________
__________________________________________________________________________
__________________________________________________________________________
__________________________________________.
3. Students may observe working scientifically by performing science integrated
process skills all the time.
__________________________________________________________________________
__________________________________________________________________________
__________________________________________________________________________
__________________________________________.
4. Correct identification of variable greatly affects the entire scientific investigation
of a particular subject matter or study.
__________________________________________________________________________
__________________________________________________________________________
__________________________________________________________________________
__________________________________________.
5. Physical survey is appropriate when simple mapping technique can be applied to
a scientific activity at hand.
__________________________________________________________________________
__________________________________________________________________________
__________________________________________________________________________
__________________________________________.
SCORING GUIDE:

Each correct answer is 1 point plus 2 points for a concise and error free
grammar and spelling explanation.
 9

2 | The Teaching of Science 27

2.1.3 Classroom Management and Assessment of Learning

In as much as we would like our students to learn best when having outdoor
activities, we also need to ensure to reduce the risk because while we know that working
outside is rewarding, there are unpredictable circumstances (Howe et al., 2017). We need
to consider the ‘adult-to-child ratio’ which should be 1:6 if the class is outside the school
premises. You may also want to have an ocular visit to the site to have a risk assessment
and seek advice from the supervisor, and adults should be oriented about the possible
risks and how to control them (Howe et al., 2017). If it is impossible to continue with the
outdoor activities, perhaps simulations and videos would be an alternative and continue
the learning process.
Table 4. Risk Assessment when Working Outdoor

Hazard Action to reduce risk

Sharp items/syringes You have to check the general condition of the site. Use disposable gloves for
in leaf, litter/ collecting from the ground. In the event of a cut, inform parents as soon as
undergrowth possible.

Students must be reminded about the appropriate behavior.

Falling into pond Adult to control access to pond unless students are deemed responsible and
capable of dealing with an accident. Consult doctor immediately in the events of
student swallowing pond water.

Allergic reaction to
found material/ Ensure data on students’ known allergies is collected and checked and prescribed
animal (most likely medication is available. Students at risk could use gloves and keep specimens in
manifest hives/rash or plastic bags.
breathing difficulty)

Cuts caused by garden Demonstrate to students how to use tools properly. Clean tools afterwards.
tools In the events of a cut, inform parents as soon as possible.
Insist that students should wear long trousers and closed shoes in areas likely
have ticks.

Tick bites In the event of a bite inform parents as soon as possible. It is advisable to remove
the tick with tweezers or tick puller. Lyme disease is a potential further risk. You
should consult a doctor and told about the bite if the students begins to feel
Source: Howe et al. (2017)
unwell in the coming days.

In addition, teachers also need to address concerns while teaching sensitive issues be-
cause Biology topics also deal with issues like sex and illegal drugs. Teachers should en-
sure the practice of implementing policies when teaching these sensitive issues. This im-
plies that parents should be informed about what is happening in the classroom. There
should be an emphasis that sex has a clear moral position, seen in the context of a stable
relationship and marriage (Howe et al., 2017).
 10

2 | The Teaching of Science 28

Furthermore, when you want your students conduct activities that involve laboratories, it
is apparent that timing and preparation of resources is important. Therefore, whenever you
plan for related activities, you have to plan how and when to access the resources, or think if
they are really accessible to you (Howe et al, 2017). Have a trial to check if the materials and
other tools are properly functioning and if there are no damages which may cause hazard to
students. Generally, if you will be having a laboratory activities, you have to conform with
the policies and guidelines for the use of the laboratory apparatuses and the use of the
laboratory facility itself. Consult technician and laboratory in-charge who can guide you
along the conduct of the said activities.

When it comes to assessment, always remember to consider the type of assessment at
hand. Recall that assessment of learning is employed after teaching when you want to have
a summative assessment to know how well each student completed the learning tasks and
activities to evaluate their achievement. On the other hand, assessment for learning is an
ongoing assessment done to monitor students’ performance and modify and have a remedy
for their learning difficulties then have a timely, specific feedback and make adjustments for
their learning. Meanwhile, assessment as learning tells us that we, teachers, should help our
students tap their metacognition and help them become lifelong learners. Thus, we should
provide them opportunities for peer and self-assessment so they will learn to make sense of
information, relate it to their prior knowledge and use it for new learning. In this way,
students would develop the spirit of ownership and efficacy when they use feedback to make
adjustments, improvement and changes to what they understand (Alberta.ca n.d.).

To assess students’ prior knowledge, you may have ‘elicit’ activities at first where you can
assess whether students have understanding or misconception of a concept in biology. From
there, you may start developing learning activities that would help them understand better
or correct their misconception (Howe et al., 2017). Other assessment strategies are presented
below:

Observation
 Observation of students’ performance is an integral part of assessment. In doing so, you
need to have anecdotal records because your observations can be forgotten. In this way,
you will have a record of continuous progress and achievement of your students.
Interviews
 To assess students’ understanding, you may conduct an interview that maybe formal or
informal. In this way, you are giving the students the chance to model and explain their
understanding at the same time, when you pose science-related questions, you are able to
focus on individual students skills and attitudes.
Group/Peer Assessment
 This gives students the opportunity to assess how well they work in group and reflect on
one another’s work according to a clearly established criteria.
 11

2 | The Teaching of Science 29

Self-assessment
 This would encourage students to assess their own work. In this way, they will apply
known criteria and expectations to their own work and reflect on results to determine their
own progress towards a learning outcome.

Performance assessment/Student Demonstration
 You can assess students knowledge, skill development, and thinking process when you
ask them to have a performance task such as demonstration. In this task, remember to use
a scoring rubric to fairly evaluate the students’ performance.

Science Journal entries
 This type of formative assessment will help you assess students learning through their
preferred pictures, labeled drawings, and words thus, allowing you to measure students’
depth of understanding.

Rubrics/Checklist
 These are used as tools to check specific process, information, and products provided by
the students. They will help you describe the qualities of students’ work at various levels
of proficiency for each criterion. You may develop tools like this in collaboration with the
students.

Visual Displays
 This gives students the opportunity process information and produce a knowledge frame-
work. Completed poster, concept map, diagram, model, etc., are products with which
teachers can determine what students are thinking.

Laboratory report
 This allows you to measure students’ ability to observe, record, and interpret experimental
results and further helps you to determine how well students understand the content.

Pencil-and-Paper Tasks
 Written tasks such as multiple choice questions, completion of a drawing or labeled
diagram, problem solving, or long-answer questions, are discrete assessment tools which
should be both restricted and extended.

Research Repot/Presentation
 This allows students to achieve the learning outcomes in individual ways. You should also
remember that assessment should be built into the project at every stage, from planning to
researching, to presenting finished product.
 12

2 | The Teaching of Science 30

ASSESSMENT

DIRECTIONS: Choose one or two scenario(s) below and write an essay with
3– 6 sentences to elaborate the idea in that item. (Graded as quiz)

1. Parents A, B and C are asking teacher M about the route and schedule of an
incoming fieldtrip of their children. Teacher M has provided them the
programme for the said events.
2. While preparing for the performance task to be held next week, the students of
teacher C have raised their concern on the set of criteria which will be used to
evaluate their performance.
3. Because Teachers Y and Z want their students to learn better about water cycle,
they decided to ask from PAGASA the weather forecast in the next coming
weeks.
4. Even before their laboratory class, the students of Teacher X are already oriented
about the policies and guidelines on the use of their laboratory equipment and
facility.
5. So students are aware of how they will be assessed and what parameters will be
used in assessing them, their teacher has provided them a set of rubrics and
grading system for all the anticipated assessment tasks.

SCORING GUIDE:

Each correct option is 2 points plus 3 points for a concise and error-free gram-
mar and spelling explanation.

2.3 References

Anderman, E. M. (n. d.). The Challenges of Teaching and Learning about Science in the 21st Century:
Exploring the Abilities and Constraints of Adolescent Learners. The Ohio State University,
165A Ramseyer Hall, 29 West Woodruff Avenue, Columbus, OH 43210.
Britannica Encyclopedia(2020). Lynn Margulis. Britannica Encyclopedia. https://www.britannica.com/
biography/Lynn-Margulis
Bybee (1989). Teaching High School Biology: Materials and Strategies. NCBI. httsp://
www.ncbi.nlm.nih.gov/books/NBK218805/
Campbell, Neil A. et al. (2014). BIOLOGY 10th Edition. South Asia Pte Ltd., Pearson Educ.
Campo et al. (2013). Science Learner’s Module. 1253 G. Araneta Ave., Quezon City, Philippines:
Vibal Publishing House, Inc.
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Fleming, A. (2020). Simulations for Science Education. http://ettec.ctlt.ubc.ca/510wiki/index.php?
title=Simulation_for_Science_Education&oldid=64027
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2 | The Teaching of Science 31

Igiri, C. E. and Effiong, O. E. (2015). Impact of IMs in Teaching and Learning of Biiology in
Snior Secondary Schools in Yakurr LG A. International Letters of Social Humanistic
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sumptions in Post-Secondary Science. Education Science 8 (12). doi:10.3390
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Gomez, M. A. (2018). Students’ Motivation toward Science Learning and Achievement in Bi-
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Milton Park, Abingdon, Oxon OX14 4RN, New York. NY 10017.
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www.labcompare.com/Clinical-Diagnostics/5140-Microbiology-Equipment/
Mader, Sylvia S. and Windelspicht (2019). BIOLOGY 13th Edition. 2 Penn Plaza, New York,
NY 10121: McGrew-Hill Education.
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Molino-Magtolis, J. B. (2013). The Use of Model Making in Teaching Human Organ Sys-
tems. JPAIR Multidisciplinary Research Vol. 11, ISSN 2244-0445. doi: http://
dx.doi.org/10.7719/jpair.v11i1.197
National Geographic Society (2019). Biodiversity. Resource Library Encyclopedia Entry.
https://www.nationageographic.org/encyclopedia/biodiversity/
Pearson Education, Inc. (2008). Central Dogma of Molecular Biology. Pearson Benjamin Cum-
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2.4 Acknowledgment
The images, tables, figures and information contained in this module were taken
from the references cited above.
 3 | The Teaching Science in the Primary Grades 1

UNIT 3: MATTER AND ITS RELEVANCE TO HUMANS

3.0 Intended Learning Outcomes:
a. Describe the role of water in sustaining life on earth;
b. Illustrate the elements that play vital role in one’s life; and
c. Share one’s daily experience on the necessity of water.

3.1 Introduction
You know that when you are thirsty, you need water or other liquid that could satisfy
your thirst. The question is, do you know why does your body need water? A plant also
needs water for it to grow. You water the plants in your backyard because you know they
will grow when you do so. Where do you sprinkle the water, on the plants’ leaves or in the
soil where the roots are found? If you know where it should be poured, you are helping the
plant then. Our lesson about water will help you explore and understand how a non-living
matter contributes to the sustainability of life on Earth.

3.2 Matter and Its Relevance to Humans
3.2.1 Properties of Water that Support Life
Activity:
A. Stand up and ready yourself to jog or jump in place until you sweat. Record the time
it took for you to sweat. While doing so, observe any change in your body
temperature or wait for the sweat to come out of your skin pores. Fan yourself after
doing the activity. Write your observation on the spaces provided below. Explain
what you feel while you were fanning yourself. Limit your explanation in 2-5
sentences.
B. Recall the days when you are cold. What do you notice on your body temperature?
What happens to your skin or hair shafts? Do you know any explanation on this?
Synthesize 3-5 sentences to answer the questions and write it on the spaces provided
below.

Water is a molecule that supports life (Campbell et al, 2014). A molecule is made up
of two or more atoms which are kept together by a covalent bond. This means that the atoms
in this molecule are sharing electrons in order to compose water. The atoms are hydrogen
and oxygen; there are 2 hydrogen atoms and 1 oxygen atom making a molecular formula
H₂O. What makes water very essential to life? The answer lies on its properties. These

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properties of water permit life to thrive on earth, on the crust and beneath the water. These
properties are dependent on the chemical bonding present in the water molecule. The
illustration below will help you comprehend the chemical bonding.
Figure 1. Hydrogen Bonds between Waters Molecules.
The bonding shows that oppositely charged electrons are
attracted to each other. Notice the V-shaped structure of the
water molecule. This is due to unequal sharing of the electrons
between Hydrogen (partial positive charge, δ+) and Oxygen
(partial negative charge, δ-) making the bond a polar covalent
bond. The result of this is hydrogen bonding among the water molecules.

3.2.2 Emergent Properties of Water

As mentioned earlier, the properties of water are dependent on the boding present in it.
The properties include cohesion, high specific heat, water density and water as a universal
solvent (Campbell et al, 2014).

Figure 2. Cohesion
Cohesion is a phenomenon that kept the
hydrogen bonds together (Campbell et al,
2014). This property together with adhesion (the
way water molecules cling on another surface,
this time on the cell wall of the water-conducting
vascular tissue of a plant) help water molecules
fight the pull of gravity while these molecules are climbing the vascular tissues of plant in
order to reach even the highest part of which that needs water. This is very important in
order for plant to transport water as it is a raw material needed in photosynthesis necessary
for the plant to process its own food. The figure below illustrates the process. Another
noticeable occurrence in the environment where cohesion acts on it is the capability of an
organism to walk on water. Due to cohesion, surface tension in water is possible. As a result,
animals like water glider and raft spider can walk on water.
The figure above shows how water molecules hold each other through cohesion at the
same time fight the pull of gravity through adhesion and be transported from the plant’s
roots to each part of it which needs water for its survival.

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 3 | The Teaching Science in the Primary Grades 3

Specific heat is the amount of heat needed to be absorbed or lost for 1 g of a substance
to change its temperature by 1°C (Campbell et al, 2014). Water has a relatively high specific
heat compared any other liquids. Specific heat of water is 1 calorie per gram and per degree
Celsius, abbreviated as 1 cal/g ∙ °C. On the other hand, ethyl alcohol like the type of alcohol
in alcoholic beverages, has a specific heat of 0.6 cal/g ∙ °C; that is, only 0.6 cal is required to
raise the temperature of 1 g of ethyl alcohol by 1°C (Campbell et al, 2014). Due to this high
specific heat of water, this molecule can resist the change in its temperature especially when
it absorbs or releases heat. This property makes it possible for this molecule to moderate air
temperature (Campbell et al, 2014). Examples of events are provided for you to better
understand the concepts.
A. In a smaller scale explanation, this can be observed when you boil water. It takes time
for you to boil it since you still need to wait until the water reaches its boiling point,
100°C. When it boils, you see smoke coming out from the kettle which is due to
breakage of hydrogen bonds. Another instance is when you sweat. Recall the activity
you did before this lesson. First and foremost, you sweat because of the heat generated
by your body while and after the task. The thermostat of your body raises the pressure
of your body by vasoconstriction which results to the rise of its temperature and that
results to production of sweat in the sweat glands. Even before the sweat comes out
of your skin pores, the sweat absorbed the heat in your body. Notably, to evaporate 1
g of water at 25°C, about 580 calorie of heat is needed (Campbell et al, 2014). This
means that for every 1g of sweat to evaporate from your skin pores, the temperature
that your body needs to generate is 25°C. As it happens, the heat goes with the vapor
resulting to the cooling effect that you feel after sweating. This is known as
evaporative cooling. This is important for your body because it serves as a mechanism
to prevent overheating.

B. In a larger scale, a large body of water absorbs a huge amount of heat from the sun during
day time. But the water heats more slowly because the water molecules can resist an
immediate change of its temperature. Thus, the air it releases is cool. On the other hand,
the land warms faster than the body of water. As a result, the air it releases in the
atmosphere is warm. However, during at night time, the land cools faster than water.
This time, the air being released by land is cool. At night, while the water cools down,
the heat which was absorbed during the day, is slowly being released into the air. This
is why air released from the sea is warm at night time (Pearson Education, Inc., 2014).
You may notice this when you standby along the shore during the night. You would feel
that the air from the sea is warm. This scenario is the so-called sea breeze and land breeze.
This capability of water moderates air temperature along coastal areas. In lakes, it helps

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 3 | The Teaching Science in the Primary Grades 4

such body of water to stabilize the temperature and help the organisms to survive
despite fluctuation of the temperature (Campbell et al, 2014).

Figure 3. Sea Breeze and Land Breeze
The figure illustrates that there is warm
air from the body of water that is blown
to the shore during the night.
Meanwhile, the air coming from the
land is cooler

Recall the activity you had in the previous page. The ice cubes were floating, right?
Perhaps what you thought was ice must be lighter compared the water. If that’s what you
thought about, you were correct! This tells you that water in solid form is less dense than in
liquid form.
Water density is another property of water that will help you further explain your
observation. This event happens, again, due to hydrogen bonding. Once the temperature of
water is above 4°C, water molecules are expanding while it warms. In contrast, the molecules
contract while it cools. Once the temperature drops from 4°C to 0°C, water starts to move
slowly and eventually freezes. If the temperature is 0°C, there happens the locking of the
molecules by forming a crystalline lattice (see Figure 4) forming a solid matter, ice. This
makes water less dense when solid and denser when liquid (Campbell et al, 2014).

This property of water plays a vital role in organisms living in water ecosystems to
thrive even if the atmospheric temperature drops up to the point that the water solidifies. It
is very amazing to know the although there is solidification of surface water, the entire body
of water will never solidify because when the surface water is in solid state it only floats
while it releases heat into the liquid portion of water in order to maintain its solid phase. This
is because for water to form hydrogen bond, just like when crystalline lattice forms, heat
must be released. Therefore, the ice releases heat in order to keep the hydrogen bonds.
Noteworthy, when the ice absorbs enough amount of heat, the ice melts because the crystals
collapse turning again the water into liquid form. Moreover, it is important that ice floats
since it contributes to the sustainability of life particularly in the aquatic ecosystem.

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 3 | The Teaching Science in the Primary Grades 5

Figure 4. Comparison of Behavior of Water Molecules when
Solid and Liquid in Form

The figure illustrates that there is formation of crystalline lattice
when water solidifies making the hydrogen bonds stable.
Meanwhile, since water is in liquid form, the water molecules
are irregular in shape and constantly forming and breaking
hydrogen bonds.

Still related to the chemical bonding present in water, another property of this liquid
matter is due to its versatility which is directly related to its polarity making it possible to be
a universal solvent. It can dissolve many substances like salt, metabolites, proteins and
nucleic acids (Mader, and Windelspecht 2012). A dissolving agent is termed as a solvent
while a material that is being dissolved is the solute (Campbell et al, 2014). Every time you
make a coffee during your break, you are making a solution—a mixture of a solute and
solvent. In this case, the warm water is your solvent while the 3-in-1 coffee powder is the
solute.
How relevant is this property to the existence of life on earth? First and foremost, there
is life because of its building blocks. Building blocks are usually non-living in nature such as
nucleotides like thymine, cytosine, adenine and guanine (building blocks of DNA), glucose
(building block of carbohydrates), phosphate, together with a pentose sugar, which serve as
the backbone of DNA and many other macromolecules. These are chemical structures that
sustain life.
Noteworthy, these biologically important chemical structures can be dissolved in
water. However, not all substances can be dissolved by water. Substances can either be
hydrophobic or hydrophilic. Those that are hydrophilic have affinity to water thus can be
dissolved although other substances can be hydrophilic without dissolving (Campbell et al,
2014). On the other hand, those that are hydrophobic cannot be dissolved in water or they
just repel with the presence of water. The different reactions of hydrophilic and hydrophobic
substances to water contribute to the formation of macromolecules in a way they can support
life.
The following are examples:
A. The phospholipid bilayer in the Cell membrane. Because its tail is composed of lipids,
which is nonpolar to water, it faces another tail hiding the water environment.
Meanwhile, the head that is made up of phosphorous and carbon, facing the outer

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environment with the water. This natural structure of the phospholipid by layer,
which became possible because of water, protects the cell of the organism since it has
become semipermeable. This means that it does not easily allow substances to go out
or get inside the cell, protecting the cell especially from substances or microorganisms
that can be detrimental to the organism. Thus, contributing to its overall protection.

B.