THE EFFECTS OF DIETARY SILICON INTAKE

A REVIEW OF THE EFFECTS OF DIETARY SILICON INTAKE ON BONE HOMEOSTASIS AND REGENERATION.

L.F. RODELLA,V. BONAZZA, M. LABANCA, C. LONATI, R. REZZANI

  1. Section of Anatomy and Physiopathology, Department of Clinical and Experimental Sciences, University of Brescia, V.le Europa 11, 25123 Brescia, Italy. Corresponding author:

Rodella Luigi Fabrizio, Section of Anatomy and Physiopathology, Department of Clinical and Experimental Sciences, University of Brescia, V.le Europa 11, 25123 Brescia, Italy. Phone +390303717485 Fax +390303717486 e-mail rodella@med.unibs.it

Abstract: Objective: Increasing evidences suggest that dietary Silicon (Si) intake, is positively correlated with bone homeostasis and regeneration, representing a potential and valid support for the prevention and improvement of bone diseases, like osteoporosis. This review, aims to provide the state of art of the studies performed until today, in order to investigate and clarify the beneficial properties and effects of silicates, on bone metabolism. Methods: We conducted a systematic literature search up to March 2013, using two medical databases (Pubmed and the Cochrane Library), to review the studies about Si consumption and bone metabolism. Results: We found 45 articles, but 38 were specifically focused on Si studies. Conclusion: Results showed a positive relationship between dietary Si intake and bone regeneration.

Key words: Dietary Silicon intake, Ortho-Silicic Acid, Bone regeneration, Osteoporosis, Silica scaffolds.


Introduction

Silicon (Si) is the second most common element in Earth’s crust (28.9%), after Oxygen (45.5%). It represents the major trace element in the human body. In particular, highest Si concentrations are found in fast-growing cells such as hair, nails, bone and skin cells.

The major and most important source of Si, is the diet. Si daily intakes range from about 20mg/day to 50mg/day in Western countries. Higher intakes (104mg/day – 204mg/day), have been reported in China and India, where plant-based foods are the major components of the diet (1). About Si absorption, the main bio-available form, for human and animals, is the Ortho-Silicic Acid (OSA, SiOH4). It is well-known that Si in the form of OSA existing only in liquid, like mineral water and beer (2), but not in foods. Nevertheless, Si is hydrolized to OSA at the gastrointestinal level (3, 4). Among foods, highest Si levels are found in grains, especially oats, barley, white wheat flour and some rice fractions (5). Si is also present in the form of synthetic compounds or silicates, but they are rarely found in the diet.

Received May 15, 2013

Accepted for publication October 15, 2013

As described in detail in the following paragraphs, several studies, performed both in vivo and in vitro, suggest that dietary consumption of Silicon is beneficial to bone health, playing an important role in bone homeostasis and regeneration and thus representing a potential trace element for the treatment and prevention of bone diseases, like osteoporosis (6-8). This pathology is considered a systemic heterogenic skeletal disease, which affects more than 200 million people in the world, characterized by an imbalance in bone turnover, leading to bone loss (osteopenia) and micro-architectural deterioration of bone tissue and increasing the risk of bone fractures. This disease typically occurs in postmenopausal or young women with estrogen deficiency (Type I) and in men and women older than 75 years (Type II). The etiology of osteoporosis is multifactorial and involves genetic, hormonal, exercise related and nutritional factors, but also smoking, alcohol abuse and chronic intake of certain drugs, such as corticosteroids (9, 10).

However, the exact biological role(s) of Silicon in bone health is still not clear, although a number of possible mechanisms have been suggested, including the synthesis of collagen and/or its stabilization, and matrix mineralization. This review aims to provide an overview of this naturally occurring dietary element and the evidences of its potential role in bone health.

Materials and Methods

Two medical databases (Pubmed and the Cochrane Library), were used to analyze the literature. To facilitate the data collection and analysis, the articles were divided into three groups, as described below:

  • In vitro studies, on human and mouse cells;
  • In vivo studies, on osteoporotic patients and animalmodels;
  • In vivo and in vitro Silica based scaffolds studies;

For each categories, we evaluated the effects of Si supplementation on bone regeneration and homeostasis, considering the follow parameters: • Number of animals/patients;

  • Animals/patients health status;
  • Amount of dietary Si intake;
  • Bone mineral density and content;
  • Bone volume, growth and length;
  • Bone markers levels;
  • Number and surface of osteoclasts and osteoblasts;
  • Histological and/or molecular analysis

Results and Discussion

From 1972 to 2013, thirty-eight articles about Si studies were found (Figure1a,b): eleven (29%) about Si studies on animal models, five (13%) about clinical studies on human, five (13%) concerned in vitro Si studies on cell cultures and seventeen (45%) regarded the development of Silica artificial scaffolds, both in vivo and in vitro. All these studies demonstrated the positive effect of dietary Si intake on bone health, suggesting the involvement of this important trace element in the early stages of bone formation. In fact, animal studies showed that supplementing with Silicon reduced the number of osteoclast (bone destroying) cells, partially preventing bone resorption and bone loss. Silicon compounds were also shown in vitro to stimulate the DNA synthesis in osteoblast (bone building) cells. Also human testing, in men and pre-menopausal women, demonstrated that dietary Si intake was positively associated with bone mineral density, reducing the risk of bone fractures.

In vivo Si studies 

We divided in vivo Si studies into animal models and human studies, as described in detail in the following paragraphs.

Animal models

We found eleven articles about Si studies on animal models (Table 1): three (27%) performed on chickens (11-15), one (9%) on turkeys and seven (64%) on rats (Figure 1c). Chickens studies showed that Si deficiency resulted in bone defects, skulls abnormalities, reduction of the osteoblast number and of the bone matrix synthesis. Si effects were investigated both in normal and ovariectomized (OVX) rats. Normal rats studies, (17, 18), showed that the lack of Si in the diet caused a decrease in bone mineral content, supporting the importance of Si in bones mineral composition (especially femur and vertebra). About Si supplementation studies in OVX rats (16), the data reported showed that treatment with Silanol (a soluble organic Si) had beneficial effects on trabecular bone formation and volume, promoting osteoblast growth and enhancing bone matrix formation. Rico and collaborators (19) investigated the effects of dietary Si supplementation in OVX rats. The morphometric and densitometric analysis showed that Si inhibited the loss of bone mass in OVX rats, promoting the longitudinal growth of long bones, such as the femur. In a randomized controlled animal study on aged OVX rats, the Authors (20) showed that treatment with OSA, stabilized with Choline (ch-OSA), had a positive effect on bone turnover, reducing partial femoral bone loss. These data were similar to those obtained from Hott (16) and confirmed the important role played by Si, in bone mineralization. Other studies, have reinforced this hypothesis. One of these was performed in order to test the possible use of water-soluble Si, for the treatment of postmenopausal osteoporosis, using OVX rats as experimental model (7). Osteoporosis is characterized by a decrease in the rate of bone formation and an increase in bone resorption. In this study, the Authors reported an increase in bone formation and a decreased resorption, in Si treated animals, suggesting an augmentation in bone turnover. The positive relationship between Si supplementation and bone metabolism in OVX rats, was also reported by Kim and collegues (21), supporting the finding that Si is an essential trace element, useful in the prevention of osteoporosis and other bone diseases.

However, some negative Si effects were also reported (22), showing that treatment of rats and turkeys with very high Si doses, had deleterious effects in animals, causing a reduction in bone strength and elasticity.


Figure 1

(a) temporal distribution of Si studies between 1972 and 2013 (b) Percentage of Si studies between 1972 and 2013 (c) Si studies on animals (d) Si scaffolds experiments (e) In vitro Si scaffolds studies (f) In vivo Si scaffolds studies

Table 1 Animal studies with Si dietary supplementation

AUTHORS

EXPERIMENTAL PROCEDURE

RESULTS

Carlisle 1972

Chicks fed with Si supplemented diet

growth rate of chicks  fed with diet    supplemented with Si

Carlisle 1975

Chicks fed with a low Si diet

amount of articular cartilage  of tibia and femur bones

Carlisle 1980

Chicks fed with Si enriched diet

normal skull formation

collagen levels

skeletal development

Hott et al. 1993

OVX rats  fed with diet supplemented with

osteoblast surface

 

Silanol 0.1mg/kg day and 1mg/kg/day

bone volume

osteoclast surface and number

bone loss

Seaborn et al., 1994

Effects of Si dietary supplementation on Rats

BMD and bone mineral content

Rico et al.2000

OVX rats fed with diet supplemented  with 

bone loss

 

500 mg of Si

longitudinal growth of long bones (femur)

Bae et al. 2008

OVX rats fed with diet supplemented with

bone mineral density (BMD) of femur and

 

20mg/kg/day of Si

tibia

bone markers formation (ALP,  Osteocalcin) osteoclast surface

Calomme et al. 2006

OVX rats fed with diet enriched with ch-OSA

BMD and bone mineral content (BMC)

bone loss

Seaborn et al. 2002

Rats fed with diet supplemented with  35µg/g of Si

skeletal growth

Ca+, K+ and Na+ concentration in the

femur

 

and tibia

bone mineralization

Kim et al. 2009

OVX Ca-deficient rats fed with diet

BMD of femur and tibia

 

supplemented with Si

bone resorption biomarker CTx

Kayongo et al., 2008

Treatment of rats and turkeys with high Si doses

in bone strength and elasticity.


Human studies

We found five clinical Si studies on human, especially on pre and post-menopausal women (Table 2). First populationbased study on osteoporotic subjects (6), showed that 40 mg of daily intake of Silicon was associated with greater bone mineral density, reducing the risk of bone fractures. Similar observations were found in a subsequent study on postmenopausal women (23). The Authors analyzed the amount of Si adsorbed from foods and its influence on bone density, confirming the relationship between Si consumption and bone health and providing some insights into optimal Si intakes. In the same year, a group of osteoporotic subjects were treated with ch-OSA (24), demonstrating an increase in bone formation markers, especially PINP (pro-collagen type I N-terminal propeptide), a marker of collagen type I synthesis. Moreover, the Authors reported a significant increment in femur bone density. These observations were in agreement with those obtained from Calomme (20), in OVX rats. A subsequent work (8), was carried out in post-menopausal women, with the aim to investigate the absorption of Si from artesian drinking water and its effects on bone health. This study demonstrated that bottled water was a source of easily absorbed dietary Si. No significant effects on bone turnover were observed because of the short-term Si supplementation. In 2012, Mcdonald and collaborators (25), analyzed the association between Si and bone health, in early post-menopausal women, trying to understand if oestrogen (specifically estradiol) could interact with Si and influence bone status. Results indicated an interaction between Si and oestrogen, suggesting that oestrogen status was important for Si metabolism in bone health. However further investigations are needed to corroborate these evidences.

In vitro Si studies

We found five articles about in vitro Si studies (Table 3): one about Si effects in chondrocytes and tybial epiphyses of chick embryos, showing that Si stimulated bone matrix synthesis (14), and two about Si studies on the human MG-63 osteosarcoma cell line. Among these, one work (4) evaluated the in vitro effects of OSA (0-50µM), using the human MG-63

Table 2 Human studies with Si dietary supplementation

AUTHORS

EXPERIMENTAL PROCEDURE

RESULTS

Macdonald et al., 2012

Osteoporosis screening study to analyze the

Si intake is positively correlated with BMD at

 

association between Si and bone health, in early

the spine and significantly at the femur.

 

post-menopausal women.

Interaction between Si and oestrogen

McNaughton et al., 2005

Dietary Si intake in post-menopausal women and effects on bone.

BMD (Bone mineral density)

Jugdaohsingh et al., 2004

Based population study (2847 subjects: 1251 men and 1596 women)

BMD in hip and femoral neck

Spector et al., 2008

Randomized, placebo-controlled trial in  osteopenic

bone formation markers (PINP)

 

female with ch-OSA dietary supplementation

femoral BMD

Li et al., 2010

Study on post-menopausal women,  to investigate

collagen type I levels

 

Si absorption from artesian drinking water and its effects on bone

HOBs metabolic activity and proliferation

 

Table 3

In vitro Silicon studies 

 

AUTHORS

EXPERIMENTAL PROCEDURE

RESULTS

Refitt et al., 2003

MG-63 and HCC1 cell lines treated with OSA

OSA 10-20 µM: collagen levels and

 

(0-50µM)

OSA 50µM  has  not significant effect

Kim et al., 2013

MC3T3-E1 cells treated with

osteoblastic mineralization activity

 

Sodium Metasilicate (0-100 µM)

bone formation marker ALP

Shie et al., 2011

MG-63 cells treated with Si (0-6 mM)

Si 2 and 4mM: osteoblast                              proliferation

Si 6mM: too high and cell death

Carlisle et al., 1980

Chondrocytes treated with Si

bone matrix synthesis

Zou et al., 2008

Human osteoblast-like cells (HOBs) treated with Si (0-30 µM)

HOBs metabolic activity and

osteosarcoma cell line and an immortalized human early osteoblastic cell line (HCC1), as osteoblast model, showing that physiological concentrations (10-20 µM) of OSA, promoted collagen type I synthesis and stimulated osteoblastic differentiation, both in MG-63 and HCC1 cells. On the contrary, at the highest concentration (50 µM), OSA caused a smaller increase in collagen type I synthesis. Similar results were obtained from Shie and colleagues (26), after the treatment of MG-63 cells with Si 0-6 mM, showing that the highest Si concentration increased cell death. In the other article (27), the Authors analyzed the role of Si, in form of Sodium Metasilicate, on the MC3T3 murine cell line, showing an increase in bone formation and mineralization. An additional study (28) evaluated the effects of silicate ions treatment on human osteoblast cells (HOBs), showing an increase of cellular metabolic activity and proliferation.

In vivo and in vitro artificial Si scaffold studies

The advent of nanotechnology has enabled the development of artificial scaffolds, increasing  interest among the scientific community, due to their potential applications in the biotechnology and nanomedicine fields.

Based on the evidences of Si beneficial properties on bone health, artificial Si scaffolds have been generated, especially during the last years.

We found seventeen papers about Silicon-based scaffolds studies (Table 4a,b,c): ten (58%) were in vitro experiments, three (18%) were in vivo experiments and four (24%) were both in vivo and in vitro studies (Figure 1d). In vitro Si studies, were classified on the basis of the type of cell culture used. Five articles were performed on human cell cultures (hMSCs, MG63, HOBs and SaOS-2 human cell lines), four on mouse cell cultures (MC3T3-E1, rBMSCs, 7F2 murine cell lines) and one on both human and mouse cells (Figure 1e). In the paragraph below, we have described in detail, these studies and their results.

The first in vitro Si scaffold experiment, using human cells, were performed on HOBs (Human primary Osteoblasts), to investigate the Si effects on cell growth and activity (29). Human osteoblasts were seeded on a thin layer of Silica gel and Table 4a

AUTHORS

EXPERIMENTAL PROCEDURE

RESULTS

Anderson et al., 1998

Primary human osteoblasts (HOBs) seeded on a thin layer of Silica gel.

osteoblast mineralization

Wiens and Wang, 2010

Human osteoblasts (SaOS-2) cultivated on biosilica

osteoblast mineralization due to Si  up- 

 

substrates.

regulation of BMP-2 protein (bone morphogenetic protein 2)

Mieszawska et al., 2010

Human mesenchymal stem cells (hMSCs) grown

of hMSCs proliferation and differentiation 

 

on osteoinductive silk-silica composite biomaterials.

into osteogenic precursors

of some osteogenic markers, as the Bone Sialoprotein (BSP) and the Collagen type 1 (Col 1).

Ganesh et al., 2012

Human mesenchymal stem cells (hMSCs) grown on

of hMSCs proliferation and differentiation

 

Si scaffolds

into osteogenic precursors

Pelaez-Vargas et al., 2011

In vitro analysis of osteoblast-like MG63 human

cells seeded on Zirconia (ZrO2) substrates, coated with micropatterned Silica.

osteoblast  adhesion, growth and   proliferation

Huangh et al., 2008

MC3T3-E1 murine cells were seeded and grown on

significant increase in cell growth and

Midha et al., 2013

Si and SiO2  nanofiber coated scaffolds.

proliferation

Duan et al., 2012

rBMSC murine cells were seeded and grown on

in rBMSC cell  adhesion,    proliferation and

 

Si scaffolds. 

osteogenic differentiation.

Lehmann et al., 2012

Si scaffolds analysis both on osteoblasts murine

significant increase in cell growth and

 

cells (mOBs)) and on human cells (peripheral blood monocytes)

proliferation

Toskas et al., 2013

Use of the Osteoblastic 7F2 murine cells to evaluate 

The biomaterial promoted cells  attachment

 

cellular compatibility and bioactivity of  an hybrid Si

and proliferation,confirming its

 

scaffold  to bone tissue engineering.

potential use in bone repair and regeneration.

 

Table 4b

In vivo studies with artificial Si scaffolds

 

AUTHORS

EXPERIMENTAL PROCEDURE

RESULTS

Chaudhari et al., 2011

Authors investigated the osteoinductivity of silicate-

Silicate substitution had a significant effect

 

substituted calcium phosphate in six female sheep.

on bone formation.

Coathup et al., 2011

Study performed on New Zealand white rabbits, using

Silica-based bioactive glasses had a significant

 

Silica-based bioactive glasses.

effect on bone formation.

Coathup et al., 2013

Authors evaluated the osteointegration of silicatesubstituted calcium phosphate (SiCaP) bone substitute materials, in an ovine critical-sized femoral condyle defect model.

Significant increase in bone formation

In vitro studies with artificial Si scaffolds

Table 4c

AUTHORS

EXPERIMENTAL PROCEDURE

RESULTS

Beck et al., 2012

Evaluation of Si nanoparticles effects both in

In vivo  bone mineral density

 

vivo in female mice (C57BL6) and in vitro on

In vitro osteoblast activity

 

MC3T3 murine cells

osteoclast number

Lee et al., 2011

Analysis of the effects on bone  of a bioactive

In vivo  bone regeneration

 

material containing Si and other elements, both in

In vitro of cell proliferation and

 

vivo in OVX rats and in vitro on MC3T3 and NIH3T3 murine cells.

differentiation

El-Gendy et al., 2012

Osteogenic differentiation of human pulp stromal

In vivo  of osteogenic gene markers

 

cells on Si bioactive scaffold, both in vivo and in vitro

In vitro of bone tissue formation

Jun et al., 2013

Use of a Silica gel as a coating material to

In vivo  new bone formation

 

incorporate bone morphogenic protein-2 (BMP-2) 

In vitro of osteoblastic  cellular      responses

Both in vivo and in vitro studies with artificial Si scaffolds


subsequently, cell activity, number and differentiation were measured at different times. Results showed an increase in bone mineralization, underlined by the presence of nodules on the Silica surfaces. Similar effects were obtained in a subsequent work (30) which showed a stimulation of mineralizing activity in human osteoblasts (SaOS-2), cultivated on biosilica substrates. According to this study, the use of biosilica scaffolds caused an upregulation of BMP2 (bone morphogenetic protein 2) expression, which promoted osteogenity in vitro. In the same year, Mieszawska and collaborators (31), obtained osteoinductive and biodegradable composite biomaterials for bone regeneration, by combining silk fibroin (a biomaterial extracted from Bombyx mori silkworm cocoons, used for in vivo and in vitro tissue engineering applications) and Silica particles. This type of scaffolds were used as substrate for the growth of human mesenchymal stem cells (hMSCs), showing an increase in hMSCs proliferation and differentiation into osteogenic precursors, confirmed by the up-regulation of some osteogenic markers, as the Bone Sialoprotein (BSP) and the Collagen type I. Similar results were obtained in another study based on the use of hMSCs and Si scaffolds (32). 

MG63 human cells, were used to analyze cell behavior, when seeded on Zirconia (ZrO2) substrates, coated with micropatterned Silica [33]. In vitro analysis, showed that the silica films on ZrO2 were able to induce osteoblastic cell adhesion, spreading and propagation.

As regards in vitro Si scaffolds studies on mouse cell cultures, two were performed on the mouse osteoblastic cell line (MC3T3-E1) (34, 35), one on the rat bone marrow-derived mesenchymal stem cells (rBMSCs) (36) and another on the mouse osteoblastic 7F2 cell line (37).

Seeding the MC3T3-E1 cells on Si and SiO2 nanofiber coated scaffolds, the Authors showed a significant increase in cell growth and proliferation (34, 35). The study on rBMSC cells and Si scaffolds (36), showed an increase in cell attachment, proliferation and differentiation, suggesting that Si might be a promising material for bone regeneration. The mouse osteoblastic 7F2 cell line was used to evaluate the cellular compatibility and bioactivity of an hybrid Si scaffold (produced using Tetraethoxysilane as Si precursor) to bone tissue engineering (37). This biomaterial was proved cytocompatible when seeded with 7F2-cells, promoting attachment and proliferation and confirming its potential use as active biomaterials in bone repair and regeneration. We identify also one article (38) in which Si scaffolds were analyzed both on murine cells (mOB, murine neonatal bone-derived preosteoblasts) and on human cells (peripheral blood monocytes as osteoclast progenitors).

As concern in vivo Si scaffolds studies (Figure 1f), two articles were published in 2011 (39, 40) and one in 2013 (41). The first work [39], investigated the osteoinductivity of silicatesubstituted calcium phosphate in six female sheep, showing a significant effect on bone formation. Similar findings were reported in a subsequent Si scaffold study (40), on rabbits. Two years later, Coathup and collaborators (41), evaluated the osteointegration of silicate-substituted calcium phosphate (SiCaP) bone substitute materials, in an ovine critical-sized femoral condyle defect model, showing a significant increase in bone formation. Four articles (42-45) were about both in vitro (on MC3T3-E1 and NIH3T3 murine cells) and in vivo (in mice and rabbits) Si scaffolds studies.

Conclusion

Based on these studies and their results, we can conclude that Si represents an essential trace element for bone health and homeostasis, leading to anti-aging, regenerating and reinforcing effects, useful in the prevention of bone diseases and in other biomedical applications, as tissue engineering and dentistry. The numerous Si studies performed until today, have contributed to define Si properties and to develop bioactive Silica-based materials, which represent successful solutions to different bone defects and diseases, due to their osteoconductive, osteoproductive and osteoinductive properties. Other advantages of Si scaffolds are the capacity to bond and integrate with living bone, without promoting toxicity or inflammation, the high reactivity and porosity. For these reasons, Si is increasingly considered as an ideal material for grafting, scaffolding, tissue repairing and regeneration.

Competing interest: The Authors declare no conflict of interest.

Generate Disclosure Statement: Dr. Rodella, Dr. Bonazza, Dr. Labanca, Dr. Lonati and Dr. Rezzani have nothing to disclose.

References

  1. Jugdaohsingh R. Silicon and bone health. J Nutr Health Aging 2007;11:99-110
  2. Casey TR, Bamforth CW. Silicon in beer and brewing. J Sci Food Agric 2010;90:784-788
  3. Jugdaohsingh R, Anderson SH, Tucker KL, Elliott H, Kiel DP, Thompson RP, Powell JJ. Dietary silicon intake and absorption. Am J Clin Nutr 2002;75:887-893
  4. Reffitt DM, Ogston N, Jugdaohsingh R, Cheung HF, Evans BA, Thompson RP, Powell JJ, Hampson GN. Orthosilicic acid stimulates collagen type 1 synthesis and osteoblastic differentiation in human osteoblast-like cells in vitro. Bone 2003;32:127135
  5. Robberecht H, Van Cauwenbergh R, Van Vlaslaer V, Hermans N. Dietary silicon intake in Belgium: Sources, availability from foods, and human serum levels. Sci Total Environ 2009;407:4777-4782
  6. Jugdaohsingh R, Tucker KL, Qiao N, Cupples LA, Kiel DP, Powell JJ. Dietary silicon intake is positively associated with bone mineral density in men and premenopausal women of the Framingham Offspring cohort. J Bone Miner Res 2004;19:297-307
  7. Bae YJ, Kim JY, Choi MK, Chung YS, Kim MH. Short-term administration of water-soluble silicon improves mineral density of the femur and tibia in ovariectomized rats. Biol Trace Elem Res 2008;124:157-163
  8. Li Z, Karp H, Zerlin A, Lee TY, Carpenter C, Heber D. Absorption of Silicon from artesian aquifer water and its impact on bone health in postmenopausal women: a 12 week pilot study. Nutr J 2010;9:44
  9. Woo DG, Lee BY, Lim D, Kim HS. Relationship between nutrition factors and osteopenia: Effects of experimental diets on immature bone quality. J Biomech 2009. 42:1102-1107.
  10. Aaseth J, Boivin G, Andersen. Osteoporosis and trace elements: an overview. J Trace Elem Med Biol  2012;26:149-152.
  11. Carlisle EM. Silicon: a possible factor in bone calcification. Science 1970;167:279-

28

  1. Carlisle EM. Silicon: an essential element for the chick. Science 1972;178:619-621

13                Carlisle EM.  In vivo requirement for Silicon in articular cartilage and connective tissue formation in the chick. J Nutr 1976;106:478-484

  1. Carlisle EM. A Silicon requirement for normal skull formation in chicks. J Nutr 1980;110:352-359.
  2. Carlisle EM. The nutritional essentiality of Silicon. Nutr Rev 1982;40:193-198
  3. Hott M, de Pollak C, Modrowski D, Marie PJ. Short-term effects of organic Silicon on trabecular bone in mature ovariectomized rats. Calcif Tissue Int 1993;53:174-179
  4. Seaborn CD, Nielsen FH. Effects of germanium and Silicon on bone mineralization. Biol Trace Elem Res 1994;42:151-164
  5. Seaborn CD, Nielsen FH. Dietary Silicon and arginine affect mineral element composition of rat femur and vertebra. Biol Trace Elem Res 2002;89:239-250
  6. Rico H, Gallego-Lago JL, Hernández ER, Villa LF, Sanchez-Atrio A, Seco C, Gérvas JJ. Effect of Silicon supplement on osteopenia induced by ovariectomy in rats. Calcif Tissue Int 2000;66:53-55
  7. Calomme M, Geusens P, Demeester N, Behets GJ, D'Haese P, Sindambiwe JB, Van Hoof V, Vanden Berghe D. Partial prevention of long-term femoral bone loss in aged ovariectomized rats supplemented with choline-stabilized Orthosilicic acid. Calcif Tissue Int 2006;78:227-232.
  8. Kim MH, Bae YJ, Choi MK, Chung YS. Silicon supplementation improves the bone mineral density of calcium-deficient ovariectomized rats by reducing bone resorption. Biol Trace Elem Res 2009;128:239-247
  9. Kayongo-Male H, Julson JL. Effects of high levels of dietary Silicon on bone development of growing rats and turkeys fed semi-purified diets. Biol Trace Elem Res 2008;123:191-201
  10. McNaughton SA, Bolton-Smith C, Mishra GD, Jugdaohsingh R, Powell JJ. Dietary Silicon intake in post-menopausal women. Br J Nutr 2005;94:813-817
  11. Spector TD, Calomme MR, Anderson SH, Clement G, Bevan L, Demeester N, Swaminathan R, Jugdaohsingh R, Berghe DA, Powell JJ. Choline-stabilized Orthosilicic acid supplementation as an adjunct to calcium/vitamin D3 stimulates markers of bone formation in osteopenic females: a randomized, placebo-controlled trial. BMC Musculoskelet Disord 2008;9 :85.
  12. Macdonald HM, Hardcastle AC, Jugdaohsingh R, Fraser WD, Reid DM, Powell JJ. Dietary Silicon interacts with oestrogen to influence bone health: evidence from the Aberdeen Prospective Osteoporosis Screening Study. Bone 2012;50:681-687.
  13. Shie MY, Ding SJ, Chang HC. The role of Silicon in osteoblast-like cell proliferation and apoptosis. Acta Biomater 2011;7:2604-2614.
  14. Kim EJ, Bu SY, Sung MK, Choi MK. Effects of Silicon on Osteoblast Activity and Bone Mineralization of MC3T3-E1 Cells. Biol Trace Elem Res 2013;152:105-112.
  15. Zou S, Ireland D, Brooks RA, Rushton N, Best S. The effects of silicate ions on human osteoblast adhesion, proliferation, and differentiation. J Biomed Mater Res B Appl Biomater 2009;90:123-130
  16. Anderson SI, Downes S, Perry CC, Caballero AM. Evaluation of the osteoblast response to a silica gel in vitro. J Mater Sci Mater Med 1998;9:731-735
  17. Wiens M, Wang X, Schlossmacher U, Lieberwirth I, Glasser G, Ushijima H, Schröder HC, Müller WE. Osteogenic potential of biosilica on human osteoblast-like (SaOS-2) cells. Calcif. Tissue Int 2010;87:513-524
  18. Mieszawska AJ, Fourligas N, Georgakoudi I, Ouhib NM, Belton DJ, Perry CC, Kaplan DL. Osteoinductive silk-silica composite biomaterials for bone regeneration.

Biomaterials 2010;31:8902-8910

  1. Ganesh N, Jayakumar R, Koyakutty M, Mony U, Nair SV. Embedded silica nanoparticles in poly(caprolactone) nanofibrous scaffolds enhanced osteogenic potential for bone tissue engineering. Tissue Eng Part A 2012;18:1867-1881
  2. Pelaez-Vargas A, Gallego-Perez D, Magallanes-Perdomo M, Fernandes MH, Hansford DJ, De Aza AH, Pena P, Monteiro FJ. Isotropic micropatterned silica coatings on zirconia induce guided cell growth for dental implants. Dent Mater 2011;27:581-589
  3. Huang Z, Daniels RH, Enzerink RJ, Hardev V, Sahi V, Goodman SB. Effect of nanofiber-coated surfaces on the proliferation and differentiation of osteoprogenitors in vitro. Tissue Eng Part A 2008;14:1853-1859
  4. Midha S, van den Bergh W, Kim TB, Lee PD, Jones JR, Mitchell CA. Bioactive Glass Foam Scaffolds are Remodelled by Osteoclasts and Support the Formation of Mineralized Matrix and Vascular Networks In Vitro. Adv Health Mater 2013;2:490499
  5. Duan W, Ning C, Tang T. Cytocompatibility and osteogenic activity of a novel calcium phosphate silicate bioceramic: Silicocarnotite. J Biomed Mater Res A 2012;
  6. Toskas G, Cherif C, Hund RD, Laourine E, Mahltig B, Fahmi A, Heinemann C, Hanke T. Chitosan(PEO)/silica hybrid nanofibers as a potential biomaterial for bone regeneration. Carbohydr Polym 2013;94:713-722
  7. Lehmann G, Cacciotti I, Palmero P, Montanaro L, Bianco A, Campagnolo L, Camaioni A. Differentiation of osteoblast and osteoclast precursors on pure and Silicon-substituted synthesized hydroxyapatites. Biomed Mater 2012;7:055001
  8. Chaudhari A, Braem A, Vleugels J, Martens JA, Naert I, Cardoso MV, Duyck J. Bone tissue response to porous and functionalized titanium and silica based coatings. PLoS One 2011;6: e24186
  9. Coathup MJ, Samizadeh S, Fang YS, Buckland T, Hing KA, Blunn GW. The osteoinductivity of silicate-substituted calcium phosphate. J Bone Joint Surg Am 2011;93:2219-2226
  10. Coathup MJ, Cai Q, Campion C, Buckland T, Blunn GW. The effect of particle size on the osteointegration of injectable silicate-substituted calcium phosphate bone substitute materials. J Biomed Mater Res B Appl Biomater, 2013
  11. Beck GR Jr, Ha SW, Camalier CE, Yamaguchi M, Li Y, Lee JK, Weitzmann MN. Bioactive silica-based nanoparticles stimulate bone-forming osteoblasts, suppress bone-resorbing osteoclasts, and enhance bone mineral density in vivo. Nanomedicine 2012;8:793-803
  12. El-Gendy R, Yang XB, Newby PJ, Boccaccini AR, Kirkham J. Osteogenic differentiation of human dental pulp stromal cells on 45S5 Bioglass® based scaffolds in vitro and in vivo. Tissue Eng Part A 2013;19:707-715
  13. Jun SH, Lee EJ, Jang TS, Kim HE, Jang JH, Koh YH. Bone morphogenic protein-2 (BMP-2) loaded hybrid coating on porous hydroxyapatite scaffolds for bone tissue engineering. J Mater Sci Mater Med 2013;24:773-782
  14. Lee C, Cheong M, Hsiao W, Liu H, Tsai C, Wang M, Wu C, Chang K, Lam G, Deng
  15. Use of iQPR-HO for bone regeneration and its potential in the improvement of osteoporosis. BMC Musculoskelet Disord 2011;12:227

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