Technical note: Examining the use of ethylenediaminetetraacetic acid for humic extraction of ancient bone

We examined the efficacy of ethylenediaminetetraacetic acid (EDTA) for removing humic contaminants from collagen extracted from ancient bone. Humic contaminants must be removed to obtain reliable stable isotope values from ancient bone collagen, given that humic acids have consistently lower δ¹³C values than collagen. The purpose of our research was to examine if EDTA treatment could effectively remove humic contaminants from bone collagen and thus serve as an alternative to the commonly implemented sodium hydroxide (NaOH) treatment, which may be associated with large collagen losses in poorly preserved samples. We compared the isotopic and elemental composition of ancient samples treated with EDTA alone, samples demineralized in hydrochloric acid (HCl) and rinsed in EDTA, samples treated with HCl alone, and samples demineralized in HCl and rinsed with NaOH. The samples used in the analyses were selected because they presented evidence of substantial humic contamination. We found that NaOH was the most effective agent for reducing humic contaminants as evidenced by the samples treated with this agent having higher δ¹³C values and lower C:N ratios relative to other treatments. The results from samples treated with EDTA suggest that this chemical cannot effectively remove humic contaminants given that these samples had significantly higher C:N ratios and lower δ¹³C and δ¹⁵N values relative to the HCl/NaOH treatment. Our results demonstrate that when performing stable isotope analysis of ancient bone collagen suspected to be contaminated with humic acids, NaOH is the most effective chemical agent to remove humic contaminants, while EDTA cannot perform this task.     

Multinuclear magnetic resonance studies of collagen molecular structure and dynamics

We have measured the percentages of cis and trans Gly-Pro and X-Hyp peptide bonds in thermally unfolded type I collagen. ¹³C-nmr solution spectra show that 16% of the Gly-Pro and 8% of the X-Hyp bonds are cis in unfolded chick calvaria collagen. These results support the hypothesis that cis–trans isomerization is that rate-limiting step in the propagation of the collagen triple helix. We have used multinuclear solid-state nmr to study the molecular dynamics of the collagen backbone in tendon, demineralized bone, and intact bone as a function of temperature, hydration, and pH. These studies show that collagen backbone motions are characterized by a broad distribution of correlation times, τ, covering the range from 10^?4 to 10^?9 s. In the case of nonmineralized collagen, the root-mean-square fluctuations in azimuthal angle, γ_rms, range from ca. 10° when τ ～ 10^?9 s to ca. 30° when τ < 10^?4 s; in the case of bone collagen, γ_rms values are about half as large as those found in nonmineralized collagen. Backbone motions are negligible at temperatures below ?25°C. This is also the case at 22°C when demineralized bone collagen is lyophilized. In contrast, flexibility of hydrated demineralized bone collagen greatly increases as pH is lowered from 7 to 2. The more limited flexibility observed at neutral pH is a consequence of the intermolecular interactions that contribute to fibril organization and strength. However, the fibrils retain significant flexibility at physiological pH, enabling them to distribute stress and dissipate mechanical energy.     

Heat resistance of allograft tissue

Lyophilized allograft musculoskeletal tissue is generally intended to be stored at “ambient” or “room” temperature, and usually is kept in climate controlled indoor storage areas. However, there is a question of what temperature extremes tissue may see, especially during transportation, in that these extremes may exceed even the limits of “ambient” conditions. Temperatures may become quite hot, but only for a few hours and only during daytime. Damage from high temperatures, if it occurs, is expected to be evident by damage to the collagen component of bone, soft tissue, and demineralized bone, as well as to the growth factors contained in demineralized bone. If damage is significant, then temperature monitoring requirements for lyophilized allograft tissue might be necessary. To answer this question, a literature review was carried out to look at the short-term temperature resistance of collagen and demineralized bone. Both collagen and the growth factors in demineralized bone show remarkable short term tolerance to elevated temperatures in the dry state, and it was concluded that temperature excursions of 50°C or less, lasting for a few days or less, would not cause any significant deterioration. This means that temperature monitoring also should not be required.     

Methods for demonstration of enzyme activity in muscle fibres at the muscle/bone interface in demineralized tissue

Summary A method for demonstration of activity for ATPase and various oxidative enzymes (succinic dehydrogenase, -glycerophosphate dehydrogenase, and lactic dehydrogenase) in muscle/bone sections of fixed and demineralized tissue has been developed. It was found that it is possible to preserve considerable amounts of the above mentioned enzymes in the muscle fibres at the muscle/bone interfaces. The best results were obtained after 20 min fixation, and 2–3 weeks of storage in MgNa₂EDTA containing media. As the same technique previously has been used to describe patterns of resorption and deposition with the aid of a mapping of presence of phosphomonoesterases on bone surfaces, the method may be used to study possible biochemical interactions between bone and muscle tissue at the muscle/bone interface.     

Items from the Literature

Thinnest practical slices of bones or teeth are suspended at 4 C in a 10% solution of EDTA in 0.1 M tris buffer brought to pH 6.95 with KOH pellets. The solution is stirred moderately and continuously with a magnetic stirrer until specimens are demineralized. Unwashed specimens, taken directly from the demineralizing fluid, are frozen on a block of CO₂ ice, mounted on a tissue carrier and sectioned at 6 μ in a cryostat. Histochemical stains conducted on sections stored in a slide holder enclosed in a plastic bag in a refrigerator for as long as 2 wk were successful. Quantitative studies on the preservation of succinic dehydrogenase showed nearly all of it present in specimens demineralized for 2 days, and approximately 50% remaining in specimens demineralized for 7 days. Qualitative studies with other dehydrogenases indicate that several may be similarly affected.     

Tissue-engineered bone formation with cryopreserved human bone marrow mesenchymal stem cells

Bone marrow mesenchymal stem cells (MSCs) have become the main cell source for bone tissue engineering. It has been reported that cryopreserved human MSCs can maintain their potential for proliferation and osteogenic differentiation in vitro. There are, however, no reports on osteogenesis with cryopreserved human MSCs in vivo. The aim of this study was to determine whether cryopreservation had an effect on the proliferation capability and osteogenic differentiation of human MSCs on scaffolds in vitro and in vivo. MSCs were isolated from human bone marrow, cultured in vitro until passage 2, and then frozen and stored at −196 °C in liquid nitrogen with 10% Me₂SO as cryoprotectant for 24 h. The cryopreserved MSCs were then thawed rapidly, seeded onto partially demineralized bone matrix (pDBM) scaffolds and cultured in osteogenic media containing 10 mM sodium β-glycerophosphate, 50 μM l-ascorbic acid, and 10 nM dexamethasone. Non-cryopreserved MSCs seeded onto the pDBM scaffolds were used as control groups. Scanning electronic microscopy (SEM) observation, DNA content assays, and measurements of alkaline phosphatase (ALP) activity and osteocalcin (OCN) content were applied, and the results showed that the proliferation potential and osteogenic differentiation of MSCs on pDBM in vitro were not affected by cryopreservation. After 2 weeks of subculture, the MSCs/pDBM composites were subcutaneously implanted into the athymic mice. The constructs were harvested at 4 and 8 weeks postimplantation, and histological examination showed tissue-engineered bone formation in the pDBM pores in both groups. Based on these results, it can be concluded that cryopreservation allows human MSCs to be available for potential therapeutic use to tissue-engineer bone.     

Autoradiographic localization of technetium-99 methylene diphosphonate in growth sites of young mice

Conflicting reports about the localization of ^99mTc-MDP in bone and cartilage are found in the literature. Possible binding sites include hydroxyapatite and non-osteoid matrix such as immature collagen. The present study used autoradiographs of demineralized and non-demineralized growth sites in young mice to demonstrate localization of ⁹⁹Tc-MDP, and consequently ^99mTc-MDP, in mineralizing cartilage and bone. Uptake of the isotope was seen in mineralizing bone and cartilage, associated with the mineral in contrast to the organic phase. The results indicate that bone seeking radiopharmaceutical uptake (BSRU) may detect alterations in the rate of mineralized phase in growth sites and thus has the potential to disclose skeletal growth disorders.     

An overview on bone protein extract as the new generation of demineralized bone matrix

Bone protein extract is regarded as the new generation of demineralized bone matrix. The aim of this paper is to describe and characterize the properties of demineralized bone matrix and its new generation product in addition to its application in animal and human studies. Bone protein extract has features of osteoconductivity, osteoinductivity and osteogenicity, which originate from its unique and precise processing. It has exhibited powerful bone formation capacity both in animal experiments and in clinical trials by providing an optimal microenvironment for osteogenesis. Furthermore, not only does it have excellent biocompatibility, it also has good compatibility with other implant materials, helping it bridge the host and implanted materials. Bone protein extract could be a promising alternative for demineralized bone matrix as a bone graft substitute.     

Bone morphogenetic protein excipients: comparative observations on poloxamer

Clinicians await the availability of synthetic bioimplants that will replace the need for autogeneic bone grafts in bone reconstructive surgery. For more than a decade, researchers have evaluated delivery vehicles for the tissue morphogen bone morphogenetic protein. The object of this investigation was to measure induced bone development when bone morphogenetic protein was delivered by human tendon collagen, human demineralized bone matrix, hydroxyapatite, a composite of human tendon collagen and human demineralized bone matrix (tendon collagen + demineralized bone matrix), Poloxamer 407, and a composite of human demineralized bone matrix and Poloxamer 407. Sixty-three adult male Swiss Webster mice (Harlan Sprague-Dawley, Indianapolis, Ind.) received 126 implants. The animals were divided into seven groups of nine animals, depending on carrier (six carriers plus the positive control group) used. Each animal received a bone morphogenetic protein-enhanced carrier in one hindquarter muscle mass, with the contralateral leg being implanted with the carrier alone. Implants were evaluated by quantitative radiomorphometry validated by histologic methods. Radiographically, no significant differences were identified among any of the implants evaluated (p > 0.05). Histomorphometric analysis demonstrated that Poloxamer 407 was significantly (p < 0.05) better at delivering bone morphogenetic protein than the other carriers involved in this investigation. The new bone developed in a tubular or spherical shape. Interaction of endogenous and exogenous delivery systems seems to be essential for optimal transmission of bone morphogenetic protein. The importance of the excipient to deliver bone morphogenetic protein and develop a bone morphogenetic protein concentration gradient has been emphasized by other investigators and confirmed by our research on poloxamer. With further research on the physicochemical mechanisms of localization and transmission of bone morphogenetic protein, it may be possible to avoid hazardous operations with autogeneic bone.     

Validation of Bone Conversion in Osteoconductive and Osteoinductive Bone Substitutes

Bone reconstruction can be performed with an autogeneic graft from various donor regions. Osteoconductive and osteoinductive bone substitutes originate from substances of diverse chemical and morphological types and can have a synthetic or a biological derivation. Alongside autogeneic bone transplants and allogenic and xenogeneic bone implants, alloplastic bone replacements of synthetic or semi-synthetic origin are being used for defect reconstruction. In an animal model in rabbits five bone substitutes and one autogeneic graft were surgically incorporated into identical bone defects (10times 10 mm in size) in six anatomically defined regions of the skull. With scintigraphic and histological methods, the metabolic dynamics of the bone is examined as it reacts to the transplantation of autogeneic bone or to implanted bone replacement material. The different autogeneic, xenogeneic and alloplastic bone replacement materials can be differentiated according to the functional quality of the new tissue and the dynamics of the bone conversion thus induced. In the comparison of mineralized, osteoconductive bone subsitutes (TCP, HA, calcium carbonate ceramics) with demineralized, osteoinductive implants (DBM new, DBM old) and autogeneic bone grafts, the bone inducing matrices show the largest quantity of new bone formation, making possible a volume-constant reconstruction. This revised version was published online in July 2006 with corrections to the Cover Date.     

Culture and differentiation of osteoblasts on coral scaffold from human bone marrow mesenchymal stem cells

In this paper we describe an approach that aims to provide fundamental information towards a scientific, biomechanical basis for the use of natural coral scaffolds to initiate mesenchymal stem cells into osteogenic differentiation for transplant purposes. Biomaterial, such as corals, is an osteoconductive material that can be used to home human derived stem cells for clinical regenerative purposes. In bone transplantation, the use of biomaterials may be a solution to bypass two main critical obstacles, the shortage of donor sites for autografts and the risk of rejection with allograft procedures. Bone regeneration is often needed for multiple clinical purposes for instance, in aesthetic reconstruction and regenerative procedures. Coral graft Porites lutea has been used by our team for a decade in clinical applications on over a thousand patients with different bone pathologies including spinal stenosis and mandibular reconstruction. It is well accepted that human bone marrow (hBM) is an exceptional source of mesenchymal stem cells (MSCs), which may differentiate into different cell phenotypes such as osteoblasts, chondrocytes, adipocytes, myocytes, cardiomyocytes and neurons. Isolated MSCs from human bone marrow were induced into osteoblasts using an osteogenic medium enriched with two specific growth factors, FGF9 and vitamin D2. Part of the cultured MSCs were directly transferred and seeded onto coral scaffolds (Porites Lutea) and induced to differentiate into osteoblasts and part were cultured in flasks for osteocell culture. The data support the concept that hBM is a reliable source of MSCs which may be easily differentiated into osteoblasts and seeded into coral as an optimal device for clinical application. Within this project we have also discussed the biological nature of MSCs, their potential application for clinical transplantation and the prospect of their use in gene therapy.     

Osteoconductivity and osteoinductivity of NanoFUSE® DBM

Bone graft substitutes have become an essential component in a number of orthopedic applications. Autologous bone has long been the gold standard for bone void fillers. However, the limited supply and morbidity associated with using autologous graft material has led to the development of many different bone graft substitutes. Allogeneic demineralized bone matrix (DBM) has been used extensively to supplement autograft bone because of its inherent osteoconductive and osteoinductive properties. Synthetic and natural bone graft substitutes that do not contain growth factors are considered to be osteoconductive only. Bioactive glass has been shown to facilitate graft containment at the operative site as well as activate cellular osteogenesis. In the present study, we present the results of a comprehensive in vitro and in vivo characterization of a combination of allogeneic human bone and bioactive glass bone void filler, NanoFUSE^® DBM. NanoFUSE^® DBM is shown to be biocompatible in a number of different assays and has been cleared by the FDA for use in bone filling indications. Data are presented showing the ability of the material to support cell attachment and proliferation on the material thereby demonstrating the osteoconductive nature of the material. NanoFUSE^® DBM was also shown to be osteoinductive in the mouse thigh muscle model. These data demonstrate that the DBM and bioactive glass combination, NanoFUSE^® DBM, could be an effective bone graft substitute.     

Growth of Euglena gracilis on whey

Summary To extend the use of industrial wastes, we have studied the growth of Euglena cells on demineralized whey powder, an industrial dairy waste from cheese making. The demineralized whey powder was solubilized (15 g/l) in 0.04 N HCl and autoclaved for two hours at 120°C. The solution was then brought to pH 3.5 with NH₄OH and tested for its ability to support Euglena growth. In the dark, cell densities of 4.5 to 5.5×10⁶ cells/ml were obtained when vitamin B₁₂, thiamine and minerals were added to the hydrolyzed whey solution. Although growth of Euglena is possible on whey, the industrial application may be limited due to the need to hydrolyze the whey and to the low utilization of carbon (20%) as the glucose, but not the galactose, released during hydrolysis is used.     

Differential protein synthesis during differentiation (spherulation) of Physarum polycephalum: Lack of synthesis of glucose-6-phosphate dehydrogenase

Summary In the neutral lipid fraction of Hydrogenomonas eutrapha strain H 16, two esters of phthalic acid were found and separated by column chromatography.By totally labelling chemolithotrophically growing bacteria with ¹⁴CO₂ it was demonstrated that these phthalic acid esters are not genuine bacterial products but of exogenous origin.It is supposed that these esters which are used as plasticizers for various plastics originate from such materials used in the preparation and storage of demineralized water.     

Potential induction of osteogenesis by systemic administration of bovine bone proteins.

This study shows, apparently for the first time, that the administration of bone derived proteins (putative bone growth factors) obtained from bovine demineralized maxillaries has a direct effect on osteogenesis, affecting significantly some markers of bone formation such as lactate dehydrogenase activity and serum osteocalcin. Also, collagen deposition and bone protein turnover were markedly increased by the treatment, which may have important biological and clinical applications.     

Methods for demonstration of enzyme activity in muscle fibres at the muscle/bone interface in demineralized tissue

A method for demonstration of activity for ATPase and various oxidative enzymes (succinic dehydrogenase, alpha-glycerophosphate dehydrogenase, and lactic dehydrogenase) in muscle/bone sections of fixed and demineralized tissue has been developed. It was found that it is possible to preserve considerable amounts of the above mentioned enzymes in the muscle fibres at the muscle/bone interfaces. The best results were obtained after 20 min fixation, and 2-3 weeks of storage in MgNa2EDTA containing media. As the same technique previously has been used to describe patterns of resorption and deposition with the aid of a mapping of presence of phosphomonoesterases on bone surfaces, the method may be used to study possible biochemical interactions between bone and muscle tissue at the muscle/bone interface.     

Comparative characterization of mesenchymal stem cells from eGFP transgenic and non-transgenic mice

Background  

Adipose derived- and bone marrow-derived murine mesenchymal stem cells (mMSCs) may be used to study stem cell properties in an in vivo setting for the purposes of evaluating therapeutic strategies that may have clinical applications in the future. If these cells are to be used for transplantation, the question arises of how to track the administered cells. One solution to this problem is to transplant cells with an easily identifiable genetic marker such as enhanced green fluorescent protein (eGFP). This protein is fluorescent and therefore does not require a chemical substrate for identification and can be visualized in living cells. This study seeks to characterize and compare adipose derived- and bone marrow-derived stem cells from C57Bl/6 mice and eGFP transgenic C57Bl/6 mice.     

Mandibular biomechanics of Crocuta crocuta,Canis lupus,and the late Miocene Dinocrocuta gigantea (Carnivora,Mammalia)

The relative simplicity of the mandible and its functional integration with the upper dentition in carnivorans makes it an ideal subject for functional morphological studies. To compare the mandibular biomechanics of two convergently evolved bone‐cracking ecomorphologies, we used finite element modelling to analyse mandibular corpus stress. The bone‐cracking spotted hyena Crocuta crocuta was used as a living analogue to the late Miocene percrocutid Dinocrocuta gigantea, using the grey wolf Canis lupus as a molar bone‐crushing outgroup. Mandibular stress values during p3, p4, and m1 tooth biting are found to be lowest in Cr. crocuta, and elevated in both Ca. lupus and D. gigantea. However, the stress‐dissipation patterns of the pre‐m1 corpus are similar between Cr. crocuta and D. gigantea. Lastly, D. gigantea has a relatively weaker corpus at the post‐m1 position than either Cr. crocuta or Ca. lupus. These findings suggest that even though stress patterns are similar amongst the bone‐cracking ecomorphs, the extinct D. gigantea had a weaker mandibular structure when performing a comparable bone‐cracking task as in Cr. crocuta because of its slender post‐m1 corpus. Ontogeny could potentially play an important role in strengthening the post‐m1 corpus by growth in the dorsoventral axis, and continuous increase in biting performance through adulthood in living Cr. crocuta suggests the possibility of a relatively more delayed development to full bone‐cracking capability in D. gigantea. © 2009 The Linnean Society of London, Zoological Journal of the Linnean Society, 2010, 158 , 683–696.