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Anticancer activity for targeting telomeric G-quadruplex and antiangiogenesis of a novel Ru(II)-Se complex.
Biological Trace Element Research (2023) 201:5640–5651
https://doi.org/10.1007/s12011-023-03631-1
The Role of Zinc in Bone Tissue Health and Regeneration—a Review
Magda Molenda1 · Joanna Kolmas1
Received: 24 November 2022 / Accepted: 11 March 2023 / Published online: 1 April 2023
© The Author(s) 2023
Abstract
Zinc is a micronutrient of key importance for human health. An increasing number of studies indicate that zinc plays a significant role in bone tissue’s normal development and maintaining homeostasis. Zinc is not only a component of bone tissue
but is also involved in the synthesis of the collagen matrix, mineralization, and bone turnover. It has been demonstrated that
zinc can stimulate runt-related transcription factor 2 (Runx2) and promote the differentiation of osteoblasts. On the other
hand, zinc has been found to inhibit osteoclast-like cell formation and to decrease bone resorption by stimulating osteoclasts’
apoptosis. Moreover, zinc regulates the RANKL/RANK/OPG pathway, thereby facilitating bone remodeling. To date, not all
mechanisms of Zn activity on bone tissue are well understood and documented. The review aimed to present the current state
of research on the role of zinc in bone tissue, its beneficial properties, and its effects on bone regeneration. Since calcium
phosphates as bone substitute materials are increasingly enriched in zinc ions, the paper included an overview of research
on the potential role of such materials in bone filling and regeneration.
Keywords Zinc · Bone tissue · Zinc substitution · Hydroxyapatite · Biomaterials
Introduction
Zinc belongs to the group of the most widespread micronutrients. It is considered the most important trace element
for human health [1, 2]. It performs not only catalytic or
regulatory functions, but also structural ones. In the body of
an adult human weighing 70 kg, zinc is stored in the amount
of 2 to 2.5 g, mainly in compounds with metallothionein [2,
3]. Fifty percent of this element is found in muscles, 30%
in bone tissue, and 20% in other tissues (including testicles,
liver, brain, and plasma) [3–5]. Zinc is considered a lowtoxic element for humans. The American Food and Nutrition
Institute has set the maximum tolerable upper intake level
(UL) of zinc for adults at 40 mg/day [6].
Zinc absorption occurs mainly in the small intestine, with
greater efficiency from liquids (up to approx. 70%) than from
solid foods (approximately 30%) [7]. Depending on its concentration, zinc transport occurs by two mechanisms: passive and facilitated transport, in high and low concentrations,
* Joanna Kolmas
joanna.kolmas@wum.edu.pl
1
Department of Analytical Chemistry and Biomaterials,
Faculty of Pharmacy, Medical University of Warsaw, Ul.
Banacha 1, 02‑097 Warsaw, Poland
13
Vol:.(1234567890)
respectively. Importantly, part of the zinc is secreted into the
intestines along with pancreatic juice and bile. The absorption of zinc with food also depends on the status of zinc in
the body—with its low content, absorption is more efficient
[7]. The maintenance of a relatively constant zinc concentration both in the extra- and intracellular spaces is possible due
to the presence of specific proteins acting as importers and
exporters of this element, regulating the flow of ions into and
out of the cell: transporters from the ZnT family (facilitating
the diffusion of cations, SLC30) and ZIP (ZRT or Irk-like
protein, SLC39) [8]. ZnT proteins reduce the concentration
of zinc in the cytoplasm, either transporting zinc outside the
cell or moving it to extracellular fluids, while ZIP proteins
have the opposite effect—they allow the influx of zinc from
the vessels into the cell. Zinc may be transported from the
intestinal lumen into the enterocytes via a non-specific divalent metal transporter (DMT1) [7, 9, 10].
Zn is a component or activator of approximately 300
enzymes or their isoforms and therefore significantly impacts
the functioning of various human body areas. It is the only
metal that is a constituent of all six classes of enzymes [11].
Studies provide that zinc is associated with the activity of
about 10% of all proteins in the human body [3]. For example, as a component of zinc-dependent enzymes, i.e., DNA
polymerase and thymidine kinase, zinc ensures the proper
�The Role of Zinc in Bone Tissue Health and Regeneration—a Review
synthesis of DNA and proteins. In addition, zinc participates
in the formation of the correct quaternary structure of many
regulatory proteins and hormone receptors, enabling binding
to DNA, RNA, or proteins [3, 12]. It produces the so-called
zinc fingers, in which the chains of amino acids form a domain
(in the shape of a finger) with a centrally located divalent zinc
cation, connecting to cysteine, and histidine residues [13–15].
Zinc belongs to the group of the most effective antioxidants—it protects thiol groups of proteins against oxidation
[16, 17], and in physiological conditions, it induces metallothioneins with an antioxidant capacity 300 times higher
than the ability to capture hydroxyl radicals by glutathione,
the most important antioxidant of the cytosol [17].
What is also very important, zinc prevents the excessive
production of cyclooxygenase-2 (COX-2), controlling the
process of formation of prostaglandins from arachidonic
acid. Excess COX-2 leads to enhanced cell proliferation,
blocking apoptosis, changes in cell adhesion processes and
angiogenesis, and also increases the metastatic capacity of
tumor cells, thus contributing to carcinogenesis [18, 19].
A significant role of zinc is also the direct inhibition
of some apoptotic enzymes, mainly caspases. Zinc can
reduce the level of oxidative stress markers, inhibit the
production of C-reactive protein, and block the adhesion
of molecules on macrophages and monocytes, protecting
the body against inflammatory processes [1, 4].
Therefore, zinc deficiency is one of the major risk factors
(ranked 11th by World Health Organization) for morbidity and mortality in developing regions of the world, most
dangerous in infants and children [20, 21]. The basic effects
of zinc deficiency on the functioning of selected organs are
presented in Table 1.
Zinc and Its Role in Bone Metabolism
Bone tissue is one of the mineralized tissues of the human body.
It consists of about 30 wt.% of proteins (mainly collagen type
I), 60 wt.% of inorganic compounds (mainly bone apatite), and
the rest is water (about 10 wt.%) [44]. Bone tissue is constantly
remodeled through a process of coupled bone turnover: briefly,
osteoclasts (bone-breaking cells) resorb bone tissue and then
osteoblasts fill the resorption sites with new tissue [45].
In addition to calcium and phosphorus, the basic elements
that are components of bone apatite, many other macro- and
micronutrients affect bone health by participating in the processes of formation or resorption, including interaction with
many enzymes involved in them. Zinc belongs to the most
important nutrients involved in the metabolism of bone tissue and the proper functioning of the skeletal system [46].
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Effect of Zinc on Bone Metabolism
The effects of zinc supplementation on bone development
were discovered over 60 years ago. Prasad et al. noticed
decreased levels of zinc in the plasma, erythrocytes, and
hair of young boys with dwarfism, hypogonadism, and
anemia. The conducted research showed that thegrowth
rate of boys with dwarfism was markedly higher in individuals fed with a full-fledged diet supplemented with
zinc than in individuals on the same diet without additional amounts of this micronutrient. It was then discovered that nutritional zinc may play a pivotal role in bone
development and growth [47].
Zinc in bones, as in other tissues, is a component of many
enzymes, but it is also found in the mineral fraction, mainly
in bone apatite [48]. Studies conducted on women with
osteoporotic disease showed that the zinc content in their
bones was lower than in healthy women [49]. Moreover, in
studies of postmenopausal women, it was noted that the zinc
content in the urine could be an effective macronutrient for
bone health (women with osteoporosis excreted over 800 µg
of zinc per 1 g of creatinine [49].
In turn, studies conducted on rats and consisting of the
supply of various doses of zinc (in the form of zinc sulfate,
5–50 mg Zn /kg of body weight) for 3 days showed not only
an increase in the content of zinc in the femur but also DNA,
calcium, collagen, and alkaline phosphatase (ALP) [50].
Zinc cations act as cofactors for ALP as well as for
collagenase, involved in bone tissue metabolism [51].
ALP belongs to the group of metalloenzymes and contains one magnesium ion and two zinc ions in its active
center [52]. Its action is to cleave the phosphate ester
bond in compounds such as pyrophosphate, phosphoethanolamine, and pyridoxal phosphate, thereby releasing
phosphate ions into the bone matrix, and stimulating its
mineralization [52].
Human studies have shown that oral administration of
zinc at a dose of 3060 µmol/kg increased both ALP activity
as well as the DNA content of the diaphyseal tissues [53].
It is worth noting that the DNA content in the bone is
a marker of the number of bone cells: osteoblasts, osteoclasts, and osteocytes [53, 54].
Zinc plays a physiological role in the stimulation of bone
growth in cooperation with IGF-I or TGF-β [53, 55]. It may
partially interact with tyrosine kinase and tyrosine phosphatase, which are involved in the IGF-I signaling mechanism in cells [56, 57]. Receptors for 1,25-dihydroxy vitamin
D3 (calcitriol) have also been shown to have 2 zinc fingers
at the DNA binding site. Zinc availability may therefore
modulate the effects of calcitriol on bone growth and mineralization [58].
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M. Molenda, J. Kolmas
Table 1 Effect of zinc activity and deficiency in selected human organs
Organ
muscles
skin
heart
testes
pancreas
brain
liver
immunity
13
Zn activity
promotes the proliferation and
activation of myoblasts
activates several factors in the
insulin signaling pathway and
the concomitant uptake of
glucose in skeletal muscle cells
prevents UV-induced damage
inhibits the expression of
integrins by keratinocytes
reduces the production of
inflammatory mediators
controls cardiac contractility
balances ROS/RNS
modulates electrical and
mechanical functions
ensuring cardioprotective effect
Zn deficiency
References
[22,25]
reduced growth and
mass of muscles
disturbed skeletal muscle
proteostasis
[26,27]
acrodermatitis
skin lesions
decreased wound healing
congestive heart failure
coronary heart disease
atherosclerosis
arterial hypertension
[28,29]
controls spermatogenesis
regulates sperm motility
affects sperm integrity
modulates fatty acid
composition
stimulate insulin biosynthesis
facilitated demand-dependent
insulin release
impaired
spermatogenesis
reduced testosterone
production
testicular malfunction
affected synthesis,
storage, and secretion of
insulin
[30,32]
modulates synaptic
transmission
inhibits NMDA receptors: Nmethyl-D-aspartate and
GABAA
inhibits glutamate and γaminobutyric acid transporters
activates many enzymes:
ornithine transcarbamylase
(OTC) and glutamate
dehydrogenase (GDH),
superoxide dismutase (SOD)
activates thymuline responsible
for lymphocyte T activity
regulates development and
function o neutrophils and
natural killer cells
neuropsychiatric
disorders
impaired sense of smell
and taste
impaired cognitive
performance
[34-38]
decreased capacity for
regeneration
cirrhosis
hepatic encephalopathy
[39-41]
reduced number of
monocytes and
polymorphonuclear cells
reduced activation of
macrophages by T
helper cells
increased oxidative
stress
decreased activity of
immune systems
frequent inflammation
[42,43]
[33]
�The Role of Zinc in Bone Tissue Health and Regeneration—a Review
Zinc in Bone Formation
Studies provided in vitro on osteoblast cells showed that
zinc plays a significant role in the process of bone tissue
formation [59–61]. Seo et al. showed that zinc treatment of
osteoblastic MC3T3-E1 cells affected their proliferation, collagen synthesis, and bone marker protein ALP activity [59].
In vitro studies have been confirmed in an animal model.
In studies of oral administration of zinc complexed with
beta-Alanyl-L-histidine (beta-alanyl-L-histidine-zinc, AHZ),
prolonged administration of significant doses of AHZ in rats
stimulate the expression of Runx2/Cbfa1 (core binding factor
alpha1), collagen type I, alkaline phosphatase, and osteocalcin
(a non-collagenous protein) in cells [62–66].
Runx2/Cbfa1 is a transcription factor, essential for osteoblast differentiation and bone formation. It was found that
it serves as a regulatory gene to activate osteoblastogenesis. In turn, the expression of Runx2/Cbfa1 is induced
by the activation of BMP-2 signaling. It was established
that zinc may induce the BMP-2 signaling pathway and
therefore affect osteoblast differentiation [67, 68]. Osterix
(osteoblast-specific transcription factor) is also a key regulator of osteogenesis, responsible for preosteoblast differentiation. In addition, Osterix enhances the expression of
ZIP1, so that a series of feedback loops occur that will
induce zinc influx, osteogenic differentiation, and bone
apatite formation [69, 70].
Recent studies have indicated another osteogenic activity of zinc ions [63]. It turns out that zinc ions affect the
precipitation and deposition of citrate in bone apatite. It
should be noted that citrates are an integral part of osseous apatite. Citrates may facilitate bone mineralization by
stabilizing the liquid precursors of calcium phosphates
and enhancing their infiltration into the collagen fibrils
[63, 70].
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In the study provided on ovariectomized rats, it was found
that Zn supplementation resulted in a significant increase
in ALP activity as well as osteocalcin content. The results
obtained in this work confirmed that zinc has a definite effect
on osteoblastogenesis, promoting osteoblast differentiation
and proliferation [71]. As far as ALP is generally a marker of
immature osteoblasts, osteocalcin influences the next stages
of osteoblast differentiation [70, 72, 73].
The key role of zinc in bone formation processes has been
confirmed by studies conducted on MC3T3-E1 preosteoblasts in vitro culture using zinc-carbon dot complexes [66].
Bifunctional Zn2+-doped carbon dots, new nanomaterials
were found to have higher osteogenic activity than observed
using undoped carbon dots [66]. In the next step, the experiments were continued in vivo on rat’s calvaria, where Zndoped carbon dots were used as potential osteogenic agents.
For comparison, zinc gluconate was used. The obtained
results have shown a high capability for bone formation,
ALP activation, and long-term stimulation.
It has also been shown that zinc can protect osteoblasts
from oxidative stress-induced apoptosis by triggering a
series of enzyme cascades leading to a decrease in cellular oxidation, inhibition of cytochrome-C release, and a
decrease in the phosphorylation of P38 and JNK, involved
in cell death signaling. This action of zinc may be used in the
prevention of oxidative stress-induced bone diseases such as
osteoporosis [54, 70] (Fig. 1).
Zinc in Bone Resorption
Many years of research on the role of zinc in the metabolism
and growth of bone tissue have shown that it also plays a key
role in inhibiting bone resorption [54, 62, 74–82].
Moonga and Dempster in the experiments conducted
in vitro on isolated rat osteoclasts. The studied cells were
Fig. 1 A scheme for Zn activity
in bone formation
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extremely sensitive to zinc, even at very low concentrations
of zinc ions (10−14 M). Moreover, the effect of a significant
decrease in bone resorption was specific to zinc and was not
observed with other metal ions tested [77].
In a similar experiment, the inhibitory effect of zinc on
bone resorption was investigated. The skulls were removed
from the rats and then cultured in Dulbecco’s modified Eagle
medium for 48 h. The experimental group was treated with
different concentrations of AHZ ( 10−4–10−7 M). In the PTH
control group, prostaglandin E2 and interleukin 1α (bone
resorption factors) significantly reduced the calcium content in the examined bone. Interestingly, this effect was
not observed in the experimental group. Therefore, it was
suggested that zinc may have an inhibitory effect on bone
resorption [76].
In [74] it was found that zinc inhibits PTH-stimulated
osteoclast-like cell formation mediated by Ca2+-dependent
protein kinase C. The zinc compound completely inhibits
PTH or IL-1α-induced increases in glucose consumption
and lactic acid production by bone tissues.
Other studies conducted in an animal model on rats
have shown that animals fed food containing no zinc had
50% more osteoclasts in the femoral epiphyseal plate
compared to the control group. Zn2+ inhibits osteoclastogenesis by decreasing calcineurin phosphatase activity
[79, 81].
Zinc regulates the RANKL/RANK/OPG pathway,
thereby facilitating bone remodeling [62, 77–80]. The
RANKL/RANK/OPG system is a crucial way for communication between osteoblasts and osteoclasts. It comprises three factors: (1) RANK, a receptor activator of
nuclear factor kappa B (NF-κB) expressed on osteoclast precursor cells; (2) RANK ligand (RANKL) found
on the surface of osteoblast; and (3) osteoprotegerin
Fig. 2 A scheme for Zn activity
in bone resorption
13
M. Molenda, J. Kolmas
(OPG) released by osteoblasts. Zinc was found to inhibit
RANKL stimulation as well as signaling pathways associated with it in preosteoclasts [77–80] (see Fig. 2).
Moreover, the available literature contains many references to the inhibitory effect of Zn on TNFα-induced osteoclastogenesis by inhibition of RANKL stimulation in osteoclast precursor cells [80–82].
Zinc—Antibacterial Activity
Zinc, in addition to its physiological role in the human
body, in ionic and nanoparticle forms (particularly in the
form of zinc oxide and zinc sulfide) has significant antibacterial activity. It has been shown to exhibit selective toxicity against both Gram-negative and Gram-positive bacteria,
with negligible effects on human cells [83, 84].
Zinc oxide nanoparticles (ZnO NP) are some of the most
used inorganic materials with bactericidal activity [85]. Due
to their high safety in use, they can be found in disinfectants,
dental materials, cosmetics, and pharmaceutical preparations.
However, it is worth noting that their mechanism of action is
not fully understood. It has been shown that the antibacterial
activity depends on the dose and size of the nanoparticles—
the smaller they are, the greater their toxic effect on microorganisms [86–88]. ZnO and ZnS nanoparticles, under the
influence of pH changes and growth factors, move towards
and then aggregate on bacterial cells or tumor lesions [89].
As a result of direct contact with the bacterial cell wall, the
integrity of the cell membrane is disrupted, the nanoparticles penetrate the cell and release Z
n2+ ions, the formation
of ROS (reactive oxygen species), which induces oxidative
stress in the bacterial cell and result initially in cell growth
inhibition and then cell death [83, 84, 90, 91] (see Fig. 3).
�The Role of Zinc in Bone Tissue Health and Regeneration—a Review
5645
Fig. 3 Mechanism of antibacterial effect of nanoparticles of
zinc compounds
Zinc in Bone Replacement Therapy—Calcium
Phosphate Biomaterials Containing Zinc
Ions
Due to their broad physiological effects, biocompatibility,
biodegradability, and pro-regenerative and antibacterial
properties, recently metallic biomaterials made of zinc or
enriched with zinc (in the form of ions or nanoparticles)
are the subject of research by many researchers [83, 85, 87,
92–134]. Of particular interest are biomaterials based on
bioceramics calcium phosphate and apatite/polymer composites for the treatment of bone defects in orthopedics and
dentistry [100–104, 106–134].
Zinc alloy-based implant materials have gained quite a
lot of popularity due to the appropriate time of gradual and
H2-emission free biodegradation—long enough for local
tissues to regenerate completely [93–95]. Zinc alloys are
characterized by a medium degree of corrosion and good
biocompatibility. Simultaneously, their degradation products—mainly ZnO, Zn(OH)2, Zn3(PO4)2 4H2O, are completely bioresorbable [94]. For example, Ca2+ ions present
in body fluids may react with zinc phosphates and precipitate
calcium phosphates (pure or with an admixture of zinc)—
compounds with a lower solubility in the aqueous environment [93]. These can then detach from the implants together
with the substrate particles and be dissolved or degraded in
the physiological environment.
However, zinc alloys also have their disadvantages,
including low mechanical strength and the need to produce them by age hardening. Therefore, they are used
only as orthopedic fixations (sutures, screws, pins and
plates) [94].
Zinc-containing compounds (in the form of nanoparticles or ions) can be used as a coating for conventional
metallic implants [95]. The released Zn ions can change
the local pH, increasing the alkalinity of the cellular
microenvironment and altering the structure of cell transmembrane proteins, which allows cells to bind more easily to proteins adsorbed on the biomaterial surface and
promotes adhesion—ensuring proper osteointegration
and new bone formation [99]. Using zinc-containing
biomaterials accelerates the healing process [92, 93].
Studies have shown that released Zn ions may induce
macrophage polarization to a pro-healing phenotype,
which facilitates osteogenic differentiation and bone
regeneration [94, 95].
Metallic and ceramic materials as well as organic MOFs
containing zinc have been described in a review article
[85], so the present study focuses on calcium phosphates
enriched in zinc ions for potential applications in bone
replacement therapy.
According to the available literature, various calcium
phosphates with applications in bone replacement therapy are known to have successfully incorporated zinc
ions: tricalcium phosphate in β-crystalline form (β-TCP,
β-Ca3(PO4)2), brushite (dicalcium phosphate dihydrate,
DCPD, CaHPO 4∙2H2O), and monetite (dicalcium phosphate anhydrous, DCPA, C aHPO4), and hydroxyapatite
(HA, Ca10(PO4)6(OH)2) [87, 104, 110, 111].
Due to their greatest chemical similarity to the mineral
fraction of bone tissue, hydroxyapatite is among the most
interesting. HA is characterized by a high capacity for
ionic substitutions, both cationic and anionic [105, 106].
Calcium cations may be partially replaced by other divalent cations (i.e., strontium, magnesium, manganese ions)
and other valence ones (i.e., sodium, potassium, gallium,
iron ions) [105]. Affinity to substitution depends on the
valency of the introduced cations and their radii: cations
of the same valency and similar ionic radius can replace
calcium cations.
Zinc ions with ionic radii smaller than those of calcium
ions (74 vs 100 pm) can be introduced by partial substitution
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in place of calcium ions or by insertion between two oxygen
atoms in a column of OH groups [104].
Numerous studies on hydroxyapatites have indicated
that the limit of zinc introduction is relatively large and,
depending on the method of synthesis, can range from 20 to
25 mol% [113, 115, 118]. It is worth noting that above this
value, other phases are formed, such as amorphous calcium
phosphate with zinc phosphate (see Fig. 4). Importantly,
the introduction of zinc ions into the structure of HA alters
its physicochemical properties. The crystallite size and the
crystallinity index significantly decreased with an increase
in Zn concentration [108].
Zinc ions inhibit the crystallization process by altering
the lattice parameters of the HA elemental cell, as well as
reducing the thermal stability of the material [117, 127, 130].
It appears that at the maximum amount of zinc in
hydroxyapatite, it is phase homogeneous up to a temperature of about 700 °C, above which it decomposes with the
formation of calcium triphosphate and calcium oxide.
However, such a high concentration of zinc in HA is not
necessary to induce a biological response. An in vitro study
by Thian et al. [114] indicated that ZnHA with a Zn:(Zn + Ca)
ratio of 2.5 mol% had enhanced bioactivity, which is comprised of the ability to form apatite. A significant increase
in the growth of human adipose tissue-derived mesenchymal
stem cells was observed, along with markers of bone cell differentiation. In addition, bacterial activity tests on this material showed a large decrease in the number of viable Staphylococcus aureus bacteria following contact with ZnHA [114].
Fig. 4 XRD patterns of the
samples with Zn fraction over
20 mol. %. a Zn40, b Zn60, c
Zn80, and d Zn100 according to
[108], with permission
13
M. Molenda, J. Kolmas
Zinc present in small amounts in HA is not cytotoxic [128,
133]. HA can enter the cytoplasm through the endosome and
decompose into calcium ions and phosphate ions. Stimulation
of HMSCs by ZnHA increases the activity of the transcription factor CREB (cAMP response element-binding protein).
CREB binds CRE on the promoters of osteogenic genes such
as Id1, bone sialoprotein, and osteocalcin, stimulating their
transcription. CAMP has also been found to increase the
number of hematopoietic stem and progenitor cells (HSPCs).
It is noteworthy that the introduction of zinc ions into
hydroxyapatite increases its solubility and bioactivity. The
studies presented in [112, 118, 123] showed that this has a
beneficial effect on osteoblast proliferation.
In numerous studies of Zn-HA used as metal coatings, its
beneficial characteristics such as bioactivity and lack of cytotoxicity have been demonstrated [99, 110, 115]. For example,
in a study of titanium implants, where zinc oxide was used as
a dopant for HA [99]. Such material had a beneficial effect
on increasing osteoblast proliferation and inhibited osteoclast
growth. Another study focused on coatings formed from various hydroxyapatites containing Zn, Sr, or Mg ions [110, 115].
The study showed that all materials, including Zn-HA, could
improve and accelerate osteointegration. The effect of adding
zinc ions to hydroxyapatite has also been studied in animal
models. Calasans-Maia et al. used Zn-HA containing 5.0 mol%
zinc by introducing it (in powder form or ceramic cylinders)
into rat calvaria and rabbits’ tibia bones [132]. In both models,
it was shown that the addition of zinc had a beneficial effect
on the restoration of bone tissue at the defect site. In contrast,
�The Role of Zinc in Bone Tissue Health and Regeneration—a Review
another study [128] examined the effect of ZnHA in apatite/
alginate microspheres introduced into damaged rat bone tissue.
In vivo studies indicated that: a high accumulation of calcium
and zinc in the defect played a key role in inhibiting osteoconduction and thus impaired bone repair.
In the available literature, studies can also be found on
other non-apatite calcium phosphates containing zinc ions.
Such include zinc-containing calcium phosphate. β-TCP, like
hydroxyapatite, has long been used in medicine as a bone
substitute biomaterial. Due to its significantly better solubility, it is often combined with HA to improve the bioactivity
of the implanted material.
The first studies on the enrichment of β-TCP with zinc
ions date back to the 1990s. Bigi et al. [123] obtained
zinc-containing TCPs up to 20 mol% at high temperatures
(> 1000 °C). Zinc ions, as those having a smaller ionic radius
than calcium ions, substitute in their place while affecting
changes in the lattice parameters of the TCP elemental cell.
Zinc was found to affect the morphology and mechanical
properties of β-TCP by increasing its bulk density. In a study
on mouse osteoblasts, Zn-βTCP was shown to stimulate their
activity and ALP [125].
In vivo studies of Zn-βTCP-containing materials conducted by Kawamura et al. consistently showed that zinc
ions contained even in lesser amounts (5.0 mol%) in calcium
phosphate improved rabbit bone tissue regeneration as early
as 4 weeks after implantation [124]. On the other hand, the
paper [111] presents a study on a canine model indicating
an increase in osteoinduction under the influence of zinc
ions contained in Zn-βTCP. The good solubility of Zn-βTCP
could be used to reveal the antibacterial properties of zinc
ions in a shorter period than with Zn-HA. Interestingly, few
such studies have been conducted to date.
A calcium phosphate material containing zinc ions is also dicalcium phosphate dihydrate. There is not much work in the available
literature exploring its properties and potential applications.
In the work of Laskus-Zakrzewska et al. [104], ZnDCPD containing different amounts of zinc (ranging from
5 to 20 mol%) were obtained by a standard wet method
and their physicochemical properties were investigated in
detail. It was found that higher concentrations of zinc ions
resulted in the formation of an additional crystalline phase—
αZn3(PO4)2, hopeite. At the same time, it was shown that
all materials were non-toxic to mouse fibroblasts, which is
promising for further research into their potential use, e.g.,
for the production of docking cement.
An interesting study was presented by Zhao et al. [121].
In this study, they demonstrated the strong antibacterial
effect of Zn-DCPD-containing coatings. Simultaneously,
they pointed out the anti-corrosive properties of such a coating on an Mg implant.
The presented examples of zinc-containing calcium phosphate materials do not exhaust all possible applications. It is
5647
worth mentioning composite materials that replace bone tissue, as well as multifunctional biomaterials that are additionally used as carriers for drugs delivered directly to the bone,
where the released zinc ions then act to support the regeneration
process.
Conclusions
The aforementioned studies have indicated that zinc plays a
pivotal role in bone remodeling, regeneration, and homeostasis. In vitro and in vivo studies have shown that zinc exhibits
multidirectional effects: on the one hand, by promoting osteoblast proliferation and differentiation and protecting osteoblasts
from oxidative stress-induced apoptosis; on the other hand, by
inhibiting osteoclastogenesis and affecting osteoclast apoptosis. Thanks to its pro-regenerative properties as well as the
antibacterial activity, it has been possible to use it in bone substitutes and implant biomaterials with successful results. Based
on the presented results, zinc incorporated into various calcium
phosphates (hydroxyapatite, β-TCP, brushite, or monetite) may
act as a beneficial agent in bone repair.
Certainly, many aspects are not yet known: the optimal
amount of zinc introduced into calcium phosphate, the degradation time of calcium phosphate modified in this way, or
its long-term biological properties. Nevertheless, the results
of the research conducted so far are promising and indicate
a potential improvement in the regenerative properties of
calcium-phosphate materials.
Author Contribution M.M. and J.K. wrote the main manuscript text;
M.M. prepared the figures; J.K. was a supervisor and gave the idea for
the manuscript.
Funding This work was supported by the Medical University of
Warsaw.
Data Availability All data and other relevant information are available
from the corresponding author upon reasonable request.
Declarations
Competing Interests The authors declare no competing interests.
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long
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need to obtain permission directly from the copyright holder. To view a
copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
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