Bone Ash
ESTIMATION OF CONTENT OF BONE ASH
PROJECT SUBMITTED BY
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Abstract
This project introduces some knowledge about the basics
involved in finding the constituents of bone. This Project deals with the
principle of qualitative analysis of cation and anion.
Skeletal system plays an integral part of most of the
animals what is that it makes it form an integral part? The solution of this
can be understood more clearly from this project.
Significance of project:
Deals with analysis of bone ash
Provides all basic ideas about concentration of various
salts present
Provides information about ion exchange reaction
This project indeed would be a revolution in the world where
there is increasing worry about problems of bone like osteoporosis and in this
industrial age amount of calcium content in bone is also reducing; this project
would indeed be a very good solution.
Bone
.
Bones are rigid organs that form part of the endoskeleton of
vertebrates. They function to move, support, and protect the various organs of
the body, produce red and white blood cells and store minerals. Bone tissue is
a type of dense connective tissue. Because bones come in a variety of shapes
and have a complex internal and external structure they are lightweight, yet
strong and hard, in addition to fulfilling their many other functions. One of
the types of tissue that makes up bone is the mineralized osseous tissue, also
called bone tissue, that gives it rigidity and a honeycomb-like
three-dimensional internal structure. Other types of tissue found in bones
include marrow, endosteum and periosteum, nerves, blood vessels and cartilage.
There are 206 bones in the adult human body and 270 in an infant
Functions
Bones have eleven main functions:
Mechanical
Protection — Bones can serve to protect internal organs,
such as the skull protecting the brain or the ribsheart and lungs.protecting
the
Shape — Bones provide a frame to keep the body supported.
Movement — Bones, skeletal muscles, tendons, ligaments and
joints function together to generate and transfer forces so that individual
body parts or the whole body can be manipulated in three-dimensional space. The
interaction between bone and muscle is studied in biomechanics.
Sound transduction — Bones are important in the mechanical
aspect of overshadowed hearing.
Blood production — The marrow, located within the medullary
cavity of long bones and interstices of cancellous bone, produces blood cells
in a process called haematopoiesis.
Synthetic
Metabolic
Mineral storage — Bones act as reserves of minerals
important for the body, most notably calciumphosphorus.and
Growth factor storage — Mineralized bone matrix stores
important growth factors such as insulin-like growth factors, transforming
growth factor, bone morphogenetic proteins and others.
Fat Storage — The yellow bone marrow acts as a storage
reserve of fatty acids.
Acid-base balance — Bone buffers the blood against excessive
pH changes by absorbing or releasing alkaline salts.
Detoxification — Bone tissues can also store heavy metals
and other foreign elements, removing them from the blood and reducing their
effects on other tissues. These can later be gradually released for excretion.
Endocrine organ – Bone controls phosphate metabolism by
releasing fibroblast growth factor – 23 (FGF-23), which acts on kidneys to
reduce phosphate re absorption.
Characteristics
The primary tissue of bone, osseous tissue, is a relatively
hard and lightweight composite material, formed mostly of calcium phosphate in
the chemical arrangement termed calcium hydroxylapatite (this is the osseous
tissue that gives bones their rigidity). It has relatively high compressive
strength but poor tensile strength of 104-121 MPa, meaning it resists pushing
forces well, but not pulling forces. While bone is essentially brittle, it does
have a significant degree of elasticity, contributed chiefly by collagen. All
bones consist of living and dead cells embedded in the mineralized organic
matrix that makes up the osseous tissue.
Individual bone structure
Bone is not a uniformly solid material, but rather has some
spaces between its hard elements.
Compact bone or (Cortical bone)
The hard outer layer of bones is composed of compact bone
tissue, so-called due to its minimal gaps and spaces. This tissue gives bones
their smooth, white, and solid appearance, and accounts for 80% of the total
bone mass of an adult skeleton. Compact bone may also be referred to as dense
bone.
Trabecular bone
Filling the interior of the bone is the trabecular bone
tissue (an open cell porousnetwork also called cancellous or spongy bone),
which is composed of a network of rod- and plate-like elements that make the
overall organ lighter and allowing room for blood vessels and marrow.
Trabecular bone accounts for the remaining 20% of total bone mass but has
nearly ten times the surface area of compact bone. If for any reason there is
an alteration in the strain to which the cancellous subjected there is a
rearrangement of the trabeculae. Although adult bone exists in both cancellous
and compact forms, there is no microscopic difference between the two.
Cellular structure
There are several types of cells constituting the bone;
Osteoblasts are mononucleate bone-forming cells that descend
from osteoprogenitor cells. They are located on the surface of osteoid seams
and make a protein mixture known as osteoid, which mineralizes to become bone.
The osteiod seam is a narrow region of newly formed organic matrix, not yet
mineralized, located on the surface of a bone. Osteoid is primarily composed of
Type I collagen. Osteoblasts also manufacture hormones, such as prostaglandins,
to act on the bone itself. They robustly produce alkaline phosphatase, anenzyme
that has a role in the mineralisation of bone, as well as many matrix proteins.
Osteoblasts are the immature bone cells.
Bone lining cells are essentially inactive osteoblasts. They
cover all of the available bone surface and function as a barrier for certain
ions.
Osteocytes originate from osteoblasts that have migrated
into and become trapped and surrounded by bone matrix that they themselves
produce. The spaces they occupy are known as lacunae. Osteocytes have many
processes that reach out to meet osteoblasts and other osteocytes probably for
the purposes of communication. Their functions include to varying degrees:
formation of bone, matrix maintenance and calcium homeostasis. They have also
been shown to act as mechano-sensory receptors — regulating the bone’s response
to stress and mechanical load. They are mature bone cells.
Osteoclasts are the cells responsible for bone resorption
(remodeling of bone to reduce its volume). Osteoclasts are large,
multinucleated cells located on bone surfaces in what are called Howship’s
lacunae or resorption pits. These lacunae, or resorption pits, are left behind
after the breakdown of the bone surface. Because the osteoclasts are derived
from a monocyte stem-cell lineage, they are equipped withphagocytic-like
mechanisms similar to circulating macrophages. Osteoclasts mature and/or
migrate to discrete bone surfaces. Upon arrival, active enzymes, such as
tartrate resistant acid phosphatase, are secreted against the mineral
substrate.
Molecular structure
Matrix
The majority of bone is made of the bone matrix. It has
inorganic and organic parts. Bone is formed by the hardening of this matrix
entrapping the cells. When these cells become entrapped from osteoblasts they
become osteocytes.
Inorganic
The inorganic is mainly crystalline mineral salts and
calcium, which is present in the form of hydroxyapatite. The matrix is
initially laid down as unmineralised osteoid (manufactured by osteoblasts).
Mineralisation involves osteoblasts secreting vesicles containing alkaline
phosphatase. This cleaves the phosphate groups and acts as the foci for calcium
and phosphate deposition. The vesicles then rupture and act as a centre for
crystals to grow on.
Organic
The organic part of matrix is mainly composed of Type I
collagen. This is synthesised intracellularly as tropocollagen and then
exported, forming fibrils. The organic part is also composed of various growth
factors, the functions of which are not fully known. Factors present
includeglycosaminoglycans, osteocalcin, osteonectin, bone sialo protein,
osteopontin and Cell Attachment Factor. One of the main things that distinguishes
the matrix of a bone from that of another cell is that the matrix in bone is
hard.
Woven or lamellar
Two types of bone can be identified microscopically
according to the pattern of collagen forming the osteoid (collagenous support
tissue of type I collagen embedded in glycosaminoglycan gel
1) woven bone characterised by haphazard organisation of
collagen fibers and is mechanically weak, and
2) lamellar bone which has a regular parallel alignment of
collagen into sheets (lamellae) and is mechanically strong.
Woven bone is produced when osteoblasts produce osteoid
rapidly which occurs initially in all fetalbones (but is later replaced by more
resilient lamellar bone). In adults woven bone is created afterfractures or in
Paget’s disease. Woven bone is weaker, with a smaller number of randomly
oriented collagen fibers, but forms quickly; it is for this appearance of the
fibrous matrix that the bone is termedwoven. It is soon replaced by lamellar
bone, which is highly organized in concentric sheets with a much lower
proportion of osteocytes to surrounding tissue. Lamellar bone, which makes its
first appearance in the fetus during the third trimester,[3] is stronger and
filled with many collagen fibers parallel to other fibers in the same layer
(these parallel columns are called osteons). In cross-section, the fibers run
in opposite directions in alternating layers, much like in plywood, assisting
in the bone’s ability to resist torsion forces. After a fracture, woven bone
forms initially and is gradually replaced by lamellar bone during a process
known as “bony substitution.”
These terms are histologic, in that a microscope is
necessary to differentiate between the two.
Types
There are five types of bones in the human body: long,
short, flat, irregular and sesamoid.
Long bones are characterized by a shaft, the diaphysis, that
is much greater in length than width. They are comprised mostly of compact bone
and lesser amounts of marrow, which is located within the medullary cavity, and
spongy bone. Most bones of the limbs, including those of the fingers and toes,
are long bones. The exceptions are those of the wrist, ankleand kneecap.
Short bones are roughly cube-shaped, and have only a thin
layer of compact bone surrounding a spongy interior. The bones of the wrist and
ankle are short bones, as are thesesamoid bones.
Flat bones are thin and generally curved, with two parallel
layers of compact bones sandwiching a layer of spongy bone. Most of the bones
of the skull are flat bones, as is thesternum.
Irregular bones do not fit into the above categories. They
consist of thin layers of compact bone surrounding a spongy interior. As
implied by the name, their shapes are irregular and complicated. The bones of
the spinehips are irregular bones.and
Sesamoid bones are bones embedded in tendons. Since they act
to hold the tendon further away from the joint, the angle of the tendon is
increased and thus the leverage of the muscle is increased. Examples of
sesamoid bones are the patella and the pisiform.Compared to woven bone ,
lamellar bone formation takes place more slowly. The orderly deposition of
collagen fibers restricts the formation of osteoid to about 1 to 2 ยตm per day.
Lamellar bone requires a relatively flat surface to lay the
collagen fibers in parallel or concentric layers.
Formation
The formation of bone during the fetal stage of development
occurs by two processes: Intramembranous ossification and endochondral
ossification.
Intramembranous ossification
Intramembranous ossification mainly occurs during formation
of the flat bones of the skull; the bone is formed from mesenchyme tissue. The
steps in intramembranous ossification are:
Development of ossification center
Calcification
Formation of trabeculae
Development of periosteum
Endochondral ossification
Endochondral ossification, on the other hand, occurs in long
bones, such as limbs; the bone is formed from cartilage. The steps in
endochondral ossification are:
Development of cartilage model
Growth of cartilage model
Development of the primary ossification center
Development of the secondary ossification center
Formation of articular cartilage and epiphyseal plate
Endochondral ossification begins with points in the
cartilage called “primary ossification centers.” They mostly appear during
fetal development, though a few short bones begin their primary ossification
after birth. They are responsible for the formation of the diaphyses of long
bones, short bones and certain parts of irregular bones. Secondary ossification
occurs after birth, and forms the epiphyses of long bones and the extremities
of irregular and flat bones. The diaphysis and both epiphyses of a long bone
are separated by a growing zone of cartilage (the epiphyseal plate). When the
child reaches skeletal maturity (18 to 25 years of age), all of the cartilage
is replaced by bone, fusing the diaphysis and both epiphyses together
(epiphyseal closure).
Bone marrow
Bone marrow can be found in almost any bone that holds
cancellous tissue. In newborns, all such bones are filled exclusively with red
marrow, but as the child ages it is mostly replaced by yellow, or fatty marrow.
In adults, red marrow is mostly found in the marrow bones of the femur, the
ribs, the vertebrae and pelvic bones.
Remodeling
Remodeling or bone turnover is the process of resorption
followed by replacement of bone with little change in shape and occurs
throughout a person’s life. Osteoblasts and osteoclasts, coupled together via
paracrine cell signalling, are referred to as bone remodeling units.
Purpose
The purpose of remodeling is to regulate calcium
homeostasis, repair micro-damaged bones (from everyday stress) but also to
shape and sculpture the skeleton during growth.
Calcium balance
The process of bone resorption by the osteoclasts releases
stored calcium into the systemic circulation and is an important process in
regulating calcium balance. As bone formation actively fixes circulating
calcium in its mineral form, removing it from the bloodstream, resorption
actively unfixes it thereby increasing circulating calcium levels. These
processes occur in tandem at site-specific locations.
Repair
Repeated stress, such as weight-bearing exercise or bone
healing, results in the bone thickening at the points of maximum stress
(Wolff’s law). It has been hypothesized that this is a result of bone’s
piezoelectric properties, which cause bone to generate small electrical
potentials under stress.[4]
Paracrine cell signalling
The action of osteoblasts and osteoclasts are controlled by
a number of chemical factors which either promote or inhibit the activity of
the bone remodelling cells, controlling the rate at which bone is made,
destroyed or changed in shape. The cells also use paracrine signalling to
control the activity of each other.
Osteoblast stimulation
Osteoblasts can be stimulated to increase bone mass through
increased secretion of osteoid and by inhibiting the ability of osteoclasts to
break down osseous tissue.
Bone building through increased secretion of osteoid is
stimulated by the secretion of growth hormone by the pituitary, thyroid hormone
and the sex hormones (estrogens and androgens). These hormones also promote
increased secretion of osteoprotegerin.[5] Osteoblasts can also be induced to
secrete a number of cytokines that promote reabsorbtion of bone by stimulating
osteoclast activity and differentiation from progenitor cells. Vitamin D,
parathyroid hormone and stimulation from osteocytes induce osteoblasts to
increase secretion of RANK-ligand and interleukin 6, which cytokines then
stimulate increased reabsorbtion of bone by osteoclasts. These same compounds
also increase secretion ofmacrophage colony-stimulating factor by osteoblasts,
which promotes the differentiation of progenitor cells into osteoclasts, and
decrease secretion of osteoprotegerin.
Osteoclast inhibition
The rate at which osteoclasts resorb bone is inhibited by
calcitonin and osteoprotegerin. Calcitonin is produced by parafollicular cells
in thethyroid gland, and can bind to receptors on osteoclasts to directly
inhibit osteoclast activity. Osteoprotegerin is secreted by osteoblasts and is
able to bind RANK-L, inhibiting osteoclast stimulation.
Experimental Analysis
Materials Required PARTICULARS QUANTITY
Rib Bone 2 Pieces
Beaker 150 ml
Test Tube 7 nos
Evaporating Dish 1 no
Ring Stand 1 no
Bunsen Burner 1 no
Test Tube Holder 2 nos
Filter Paper -
PH Paper -
Dil. Nitric Acid 200 ml
1% Ammonium Hydroxide 100
ml
1% Silver Nitrate 25
ml
1% Ammonium Chloride 50
ml
Acetic Acid 100
ml
1% Potassium Thiocyanate 25
ml
Distilled Water As
Reqd
Report of Project
EXPERIMENT OBSERVATION
A strip of bone was burnt in evaporating dish Yellowish white precipitate was obtained
2 gms of bone as was weighed
To it dilute nitric acid was added On adding Nitric acid the ash sparingly dissolved
It was diluted with water and the ash was completely
dissolved
The above solution was filtered and the residue (left on the
filter paper) was discarded
Ammonium hydroxide was added to the filtrate (left on the
beaker) The pH was made to 8.6
Whitish brown precipitate of Magnesium ammonium phosphate
was obtained
The solution was made basic. The basicity was checked with
the help of pH paper
The solution was filtered and the residue was isolated
The filtrate was separated into two test tubes White precipitate of Silver chloride was
obtained
Silver nitrate was added to one of the test tubes White residue of calcium
To the other test tube ammonium chloride and ammonium
carbonate was added simultaneously and boiled Carbonate
was obtained
To the solution left, dilute HCL was added followed by
Potassium thiocyanate Red colour
solution marking the presence of Iron was obtained
Result
Extrapolation from the above observations
Constituents of bone ash identified were:
I. Calcium
II. Phosphate
III. Chloride
IV. Magnesium
V. Iron
Apart from this Calcium and Phosphate which is found maximum
in bone was estimated from the precipitate got. This was done by weighing the
precipitate
Weight of Calcium carbonate:-
1.7 g
Weight of Mg (NH4) PO4 :-
1.1 g
Weight of Ca in 2g of sample:-
0.68 g
Weight of Phosphorous:-
0.24 g
% of Ca:-
34%
% of Phosphorous:-
12%
Disorders
There are many disorders of the skeleton. One of the more
prominent is osteoporosis.
Osteoporosis
Osteoporosis is a disease of bone, leading to an increased
risk of fracture. In osteoporosis, the bone mineral density (BMD) is reduced,
bone microarchitecture is disrupted, and the amount and variety of
non-collagenous proteins in bone is altered. Osteoporosis is defined by the
World Health Organization (WHO) in women as a bone mineral density 2.5 standard
deviations below peak bone mass (20-year-old sex-matched healthy person
average) as measured by DXA; the term “established osteoporosis” includes the
presence of a fragility fracture.[6] Osteoporosis is most common in women after
the menopause, when it is called postmenopausal osteoporosis, but may develop
in men and premenopausal women in the presence of particular hormonal disorders
and other chronic diseases or as a result of smoking and medications,
specifically glucocorticoids, when the disease is called steroid- or
glucocorticoid-induced osteoporosis (SIOP or GIOP).
Osteoporosis can be prevented with lifestyle advice and medication,
and preventing falls in people with known or suspected osteoporosis is an
established way to prevent fractures. Osteoporosis can be treated with
bisphosphonates and various other medical treatments.
Other
Other disorders of bone include:
Bone fracture
Osteomyelitis
Osteosarcoma
Osteogenesis imperfecta
Osteochondritis Dissecans
Bone Metastases
Neurofibromatosis type I
Osteology
The study of bones and teeth is referred to as osteology. It
is frequently used in anthropology, archeology and forensic science for a
variety of tasks. This can include determining the nutritional, health, age or
injury status of the individual the bones were taken from. Preparing fleshed
bones for these types of studies can involve maceration – boiling fleshed bones
to remove large particles, then hand-cleaning.
Typically anthropologists and archeologists study bone tools
made by Homo sapiens and Homo neanderthalensis. Bones can serve a number of
uses such as projectile points or artistic pigments, and can be made from endoskeletal
or external bones such as antler or tusk.
Alternatives to bony endoskeletons
There are several evolutionary alternatives to mammillary
bone; though they have some similar functions, they are not completely
functionally analogous to bone.
Exoskeletons offer support, protection and levers for
movement similar to endoskeletal bone. Different types of exoskeletons include
shells,carapaces (consisting of calcium compounds or silica) and chitinous
exoskeletons.
A true endoskeleton (that is, protective tissue derived from
mesoderm) is also present in Echinoderms. Poriferaspicules and a spongin fiber
network.(sponges) possess simple endoskeletons that consist of calcareous or
siliceous
Exposed bone
Bone penetrating the skin and being exposed to the outside
can be both a natural process in some animals, and due to injury:
A deer’s antlers are composed of bone.
Instead of teeth, the extinct predatory fish Dunkleosteus
had sharp edges of hard exposed bone along its jaws.
A compound fracture occurs when the edges of a broken bone
puncture the skin.
Though not strictly speaking exposed, a bird’s beak is
primarily bone covered in a layer of keratin over a vascular layer containing
blood vessels and nerve endings.
Terminology
Several terms are used to refer to features and components
of bones throughout the body:Bone feature Definition
articular process A projection that
contacts an adjacent bone.
articulation The region where
adjacent bones contact each other — a joint.
canal A long,
tunnel-like foramen, usually a passage for notable nerves or blood vessels.
condyle A large, rounded
articular process.
crest A prominent
ridge.
Eminence
A relatively small
projection or bump.
epicondyle A projection near to a condyle
but not part of the joint.
facet A small, flattened
articular surface.
foramen An opening through a
bone.
fossa A broad, shallow
depressed area.
fovea A small pit on the head of a bone.
Labyrinth A cavity within a bone.
line A long, thin
projection, often with a rough surface. Also known as a ridge.
malleolus One of two specific
protuberances of bones in the ankle.
meatus A short canal.
process A relatively large
projection or prominent bump.(gen.)
ramus An arm-like branch off
the body of a bone.
sinus A cavity within a cranial
bone.
spine A relatively long, thin
projection or bump.
suture Articulation
between cranial bones.
trochanter One of two
specific tuberosities located on the femur.
tubercle A
projection or bump with a roughened surface, generally smaller than a
tuberosity.
tuberosity A
projection or bump with a roughened surface.
Bibliography
Biology Investigations
- Otto, Towle,
Crider
Concise Inorganic Chemistry
- J.D.Lee
Wikipedia
NCERT Biology and chemistry Textbook
The Journal of Biological Chemistry
- Anon
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