Secondary osteoporosis arises from several medical conditions,
including hyperthyroidism, hyperparathyroidism, diabetes, adrenocortical
overactivity, rheumatoid arthritis, and chronic use of various
medications, particularly corticosteroids. Secondary osteoporosis
is also a consequence of chronic alcohol abuse and smoking
addiction.
Conventional treatment for osteoporosis includes the use of hormones
and prescription drugs. Hormone therapy has recently been shown
to increase the risk of heart attack, stroke, blood clots and
invasive breast cancer. Prescription drugs, particularly bisphosphonates,
are also accompanied by side effects that range from mild gastrointestinal
upset to musculoskeletal pain, heartburn and esophageal irritation.
Additionally, some bisphosphonates have been implicated in
osteonecrosis of the jaw, a disorder involving severe bone
loss due to impaired blood circulation to bone tissues.
As an alternative to conventional drug therapies,
many practitioners recommend intake of extra calcium, supported
by supplemental magnesium, boron, and vitamin D. While each of
these nutrients play a role in supporting normal bone remodeling
in the healthy, they don’t adequately address the underlying
disorder–the disruption of calcium regulatory mechanisms.
In addition to building strong bones, calcium is an essential
nutrient required for a variety of critical metabolic, cellular
and organ functions. Calcium is essential for chemical signaling
within cells, promoting transmission of nerve impulses and
inducing muscle contractions. Calcium also initiates blood
clotting, participates as a cofactor for enzymes and hormones,
and regulates cellular proliferation and maturation.
Due to its importance the body tightly regulates
calcium to maintain levels within a narrow, physiologically safe
range. To accomplish this numerous specialized molecules and
subcellular structures are involved in maintaining optimal calcium
levels. As a consequence, calcium is in constant motion, entering
and exiting cells as it is recycled, redirected, stored and re-released
from countless sites in bones, blood, organ tissues and cellular
fluids.
When the body loses control of calcium metabolism,
numerous problems arise. Calcium dysregulation disrupts endocrine
hormones, and interferes with the interplay between glucose and
calcium ions during the release of insulin. Ongoing research
indicates that calcium dysregulation plays a central role in
the development of Alz-heimer’s disease and contributes
to nerve cell damage, kidney nephrosis, bi-polar disorder, calcification
of arteries, muscular dystrophies, periodontal disease, non-healing
of fractures and tumor cell proliferation.
Despite popular claims to the contrary, calcium supplements offer
very little benefit for preventing fractures in the elderly
according to a major study published in the British Medical
Journal (BMJ) In their report on the RECORD trial, a randomized
study involving more than 5,000 persons over the age of 70,
the researchers failed to find any significant effects from
daily supplements of 1,000 mg calcium and/or 800 i.u. vitamin
D3. The main aim of the study was to examine the incidence
of bone fractures due to osteoporosis, but they also looked
at mortality, frequency of falling and quality of life. The
RECORD study spanned from two to five years.
In an accompanying article in the medical journal Lancet,
Dr. Philip Sambrook (Royal North Shore Hospital, Sydney, Australia)
noted, “The RECORD study, a large randomized trial of participants
with a recent low-trauma fracture, failed to show any benefit
of calcium or vitamin D on fracture. We were a little surprised
by our findings because, based on evidence available, the most
likely finding was that the combination of calcium and vitamin
D would prevent fractures. However, we didn’t find this
to be the case. A better understanding of the underlying processes
at work is needed.”
These findings support the research of Kenneth
McLeod, chair of the bioengineering department at Binghamton
University, England. According to McLeod, calcium supplements
are insufficient for triggering the growth of new bone in osteoporosis
patients. As a leading researcher in the field of tissue development,
healing and adaptation, McLeod’s research highlights the
limits of a dietary approach to osteoporosis.
McLeod argues that it is time to give up fractured
approaches to studying osteoporosis and recognize that the loss
of bone mass is a natural, adaptive response to systemic changes
in the body.
A better approach for avoiding or reversing
the devastating effects of osteoporosis should draw upon our
understanding of what is really going on in the body to allow
better targeting of the mechanisms involved in bone loss. This
is the rationale behind the development of OsteoPhase®.
OsteoPhase
is
a
marine-based
nutritional
supplement
designed
to
support
skeletal
bone
health
and
bone
remodeling
by
restoring
healthy calcium
regulation.
OsteoPhase
was
developed
on
the
basis
of
extensive
research
into
the
biology
of
nacre,
the
lustrous prismatic
layer
of
mollusk
shells
also
known
as Mother
of
Pearl.
This
fascinating
composite
biogenic
material
consists
of
a
matrix
of
proteins,
glycoproteins
and
chitin
that
combine
elasticity with
high
mechanical
strength
similar
to
modern
ceramics
to
reduce
brittleness.
Early studies with nacre aimed to decipher
the mechanisms involved in mineralization and shell formation
in oysters. Research soon revealed that nacre formation closely
mimics the biological processes involved in human bone formation,
including uptake, transport and recruitment of calcium ions.
By 1992 researchers discovered that when implanted
in human bone, nacre promotes the formation of osteoblasts (bone
forming cells) and stimulates formation of new bone tissue (osteogenesis).
Based on this finding, by 1992 nacre from the marine oyster Pinctada
maxima was successfully being used as a biomaterial in oral
surgery.
In 2001 researchers at the Laboratoire
de Physiologie Generale in Paris began experimenting with
a water-soluble matrix (WSM) of nacre obtained from the inner
shell layer of Pinctada maxima. Their research showed that
WSM nacre solution promoted cell proliferation and alkaline
phosphatase (ALP) activity in bone marrow stromal cells, indicating
the formation of new bone.
By 2003 a second group of researchers in Paris
were conducting new tests of water soluble matrix (WSM) on pre-osteoblast
mouse cells. Their study revealed that WSM stimulated osteoblast
differentiation and mineralization in a third of the time normally
required for cells grown in mineralizing media, demonstrating
that the nacre WSM enhanced and sped up the mineralization processes
involved in bone growth.
The breakthrough occurred in 2004 when researchers
from the Institute of Marine Biotechnology in Beijing
finally announced that they had succeeded in identifying and
characterizing the pivotal calcium metabolism regulator involved
in regulating calcium uptake, transport and secretion in oyster
nacre.
Building on their discovery, the Marine Biotechnology
team developed a proprietary process for extracting and purifying
these bioactive agents and blending them with ionic calcium and
traditional herbs. This resulted in a formula that safely supports
calcium regulation and helps reduce bone loss, increase bone
density, and restore balance to bone remodeling mechanisms.
Initial research has shown that this unique
formula, OsteoPhase, supports healthy calcium balance
(homeostasis) by aiding the body in restoring normal bone density
and normalizing (reducing) calcium levels in the blood and soft
tissues. These physiological effects are validated by independent
studies of the herbal ingredients contained in the formula.
OsteoPhase is an advanced nutritional formula consisting
of a proprietary blend of herbal extracts and marine peptides
that have been studied for their role in supporting healthy bone
structure and calcium homeostasis. OsteoPhase has been shown
to significantly reverse bone loss and enhance bone density,
as determined by bone mineral density (BMD) measurements by DEXA
(dual-energy x-ray absorptiometry) and Achilles (ultrasonometer)
scans.
Next Issue: Calcium
Dysregulation and Osteoporosis, Part 2: Clinical
Benefits of OsteoPhase for Glucocorticoid-Induced Osteoporosis
and Avascular Necrosis of the Hip.
