Two-Dimensional Magnesium Phosphate Nanosheets Form Highly Thixotropic Gels That Up-Regulate Bone Formation.

Hydrogels composed of two-dimensional (2D) nanomaterials have become an important alternative to replace traditional inorganic scaffolds for tissue engineering. Here, we describe a novel nanocrystalline material with 2D morphology that was synthesized by tuning the crystallization of the sodium-magnesium-phosphate system. We discovered that the sodium ion can regulate the precipitation of magnesium phosphate by interacting with the crystal's surface causing a preferential crystal growth that results in 2D morphology. The 2D nanomaterial gave rise to a physical hydrogel that presented extreme thixotropy, injectability, biocompatibility, bioresorption, and long-term stability. The nanocrystalline material was characterized in vitro and in vivo and we discovered that it presented unique biological properties. Magnesium phosphate nanosheets accelerated bone healing and osseointegration by enhancing collagen formation, osteoblasts differentiation, and osteoclasts proliferation through up-regulation of COL1A1, RunX2, ALP, OCN, and OPN. In summary, the 2D magnesium phosphate nanosheets could bring a paradigm shift in the field of minimally invasive orthopedic and craniofacial interventions because it is the only material available that can be injected through high gauge needles into bone defects in order to accelerate bone healing and osseointegration.

Electrocatalytic Oxygen Reduction Performance of Silver Nanoparticle Decorated Electrochemically Exfoliated Graphene.

We have developed a potentiostatic double-pulse technique for silver nanoparticle (Ag NP) deposition on graphene (GRn) with superior electronic and ionic conductivity. This approach yielded a two-dimensional electrocatalyst with a homogeneous Ag NP spatial distribution having remarkable performance in the oxygen reduction reaction (ORR). GRn sheets were reproducibly prepared by the electrochemical exfoliation of graphite (GRp) at high yield and purity with a low degree of oxidation. Polystyrenesulfonate added during exfoliation enhanced the stability of the GRn solution by preventing the restacking of the graphene sheets and increased its ionic conductivity. The potentiostatic double-pulse technique is generally used to electrodeposit Pt nanoparticles and remains challenging for silver metal that exhibits nucleation and growth potentials relatively close to each other. We judiciously exploited this narrow margin of potential, and for the first time we report Ag NP electrodeposited onto graphene with the subsequent ability to control both the density and the size of metallic nanoparticles. Considering the high activity along with the lower cost of Ag compared to Pt, these findings are highly relevant to the successful commercialization of fuel cells and other electrochemical energy devices.

Electropolymerized carbonic anhydrase immobilization for carbon dioxide capture.

Biomimetic carbonation carried out with carbonic anhydrase (CA) in CO2-absorbing solutions, such as methyldiethanolamine (MDEA), is one approach that has been developed to accelerate the capture of CO2. However, there are several practical issues, such as high cost and limited enzyme stability, that need to be overcome. In this study, the capacity of CA immobilization on a porous solid support was studied to improve the instability in the tertiary amine solvent. We have shown that a 63% porosity macroporous carbon foam support makes separation and reuse facile and allows for an efficient supply and presentation of CO2 to an aqueous solvent and the enzyme catalytic center. These enzymatic supports conserved 40% of their initial activity after 42 days at 70 °C in an amine solvent, whereas the free enzyme shows no activity after 1 h in the same conditions. In this work, we have overcome the technical barrier associated with the recovery of the biocatalyst after operation, and most of all, these electropolymerized enzymatic supports have shown a remarkable increase of thermal stability in an amine-based CO2 sequestration solvent.

Amorphous multimetal based catalyst for oxygen evolution reaction.

The development of efficient, low-cost water splitting electrocatalysts is needed to store energy by generating sustainable hydrogen from low power clean but intermittent energy sources such as solar and wind. Here, we report a highly sustained low overpotential for oxygen evolution reached by the unique combination of three metals (NiCoV) prepared from a simple low temperature auto-combustion process. The amorphous multimetal oxygen evolving catalyst could be stably coated on a stainless-steel support using a tribochemical particle blasting method to create an oxygen evolution reaction (OER) electrode with a low overpotential of 230 mV at 10 mA cm-2 and a low Tafel slope of 40 mV dec-1. In addition to their low overpotential, this oxygen evolving electrocatalyst preserved performance demonstrating a stability after 10 h at the technologically relevant current density and without any surface morphology alteration. Given the importance of sustainable hydrogen production, the development of this new OER catalyst points the way to removing a key technical bottleneck for the water splitting reaction and could offer a route to cost reduction and lowering hurdles to more widespread adaptation of electrolyser technologies for hydrogen production. Supplementary Information: The online version contains supplementary material available at 10.1007/s43939-024-00087-5.

Low temperature fabrication of spherical brushite granules by cement paste emulsion.

Secondary protonated calcium phosphates such as brushite (CaHPO(4)·2H(2)O) or monetite (CaHPO(4)) have a higher resorption potential in bone defects than sintered ceramics, e.g. tricalcium phosphate or hydroxyapatite. However, processing of these phosphates to monolithic blocks or granules is not possible by sintering due to thermal decomposition of protonated phosphates at higher temperatures. In this study a low temperature technique for the preparation of spherical brushite granules in a cement setting reaction is presented. These granules were synthesized by dispersing a calcium phosphate cement paste composed of ß-tricalcium phosphate and monocalcium phosphate together with a surfactant to an oil/water emulsion. The reaction products were characterized regarding their size distribution, morphology, and phase composition. Clinically relevant granule sizes ranging from 200 µm to 1 mm were obtained, whereas generally smaller granules were received with higher oil viscosity, increasing temperature or higher powder to liquid ratios of the cement paste. The hardened granules were microporous with a specific surface area of 0.7 m(2)/g and consisted of plate-like brushite (>95 % according to XRD) crystals of 0.5-7 µm size. Furthermore it was shown that the granules may be also used for drug delivery applications. This was demonstrated by adsorption of vancomycin from an aqueous solution, where a load of 1.45-1.88 mg drug per g granules and an almost complete release within 2 h was obtained.

Self-assembled calcium pyrophosphate nanostructures for targeted molecular delivery.

Nanostructured, inorganic microspheres have many industrial applications, including catalysis, electronics, and particularly drug delivery, with several advantages over their organic counterparts. However, many current production methods require high energy input, use of harmful chemicals, and extensive processing. Here, the self-assembly of calcium pyrophosphate into nanofibre microspheres is reported. This process takes place at ambient temperature, with no energy input, and only salt water as a by-product. The formation of these materials is examined, as is the formation of nanotubes when the system is agitated, from initial precipitate to crystallisation. A mechanism of formation is proposed, whereby the nanofibre intermediates are formed as the system moves from kinetically favoured spheres to thermodynamically stable plates, with a corresponding increase in aspect ratio. The functionality of the nanofibre microspheres as targeted enteric drug delivery vehicles is then demonstrated in vitro and in vivo, showing that the microspheres can pass through the stomach while protecting the activity of a model protein, then release their payload in intestinal conditions.

Vertical bone augmentation with 3D-synthetic monetite blocks in the rabbit calvaria.

INTRODUCTION: Long-term success of osteointegrated dental implants requires sufficient volume of healthy bone at the recipient sites. However, this is frequently lacking as a result of trauma, tooth loss, or infection. Onlay autografting is amongst the most predictable techniques for craniofacial vertical bone augmentation, however, complications related to donor site morbidity are common and alternatives to onlay autografts are desirable. AIM: To develop and evaluate a new synthetic onlay block for vertical bone augmentation. MATERIAL AND METHODS: Sixteen synthetic monetite monolithic discs-shaped blocks were prepared using a 3D-printing technique. The blocks were computer-designed, and had a diameter of 9.0 mm, a thickness of either 4.0 mm (n = 8) or 3.0 mm (n = 8) and one 0.5-mm wide central hole that enabled their surgical fixation with osteosynthesis screws. The blocks were randomly allocated to each side of the calvaria (right or left) of eight New Zealand rabbits and fixed with screws to achieve vertical bone augmentation. Eight weeks after the surgical intervention, the animals were sacrificed and the calvaria were retrieved for histological analysis. The following parameters were analysed: the interaction between the graft and the original bone surface, the amount of bone ingrowth within the graft and the gain in bone height achieved by the procedure. Wilcoxon t-test was used to evaluate significant differences between the two types of monetite bone block grafts. RESULTS: The blocks were easy to handle and no damage or fracture was registered while being screw-fixated to the calvarial bone. As a result, the surgical procedure was easy and quick. After a healing of 8 weeks, the synthetic blocks were strongly fused to the calvarial bone surface. Upon histological observation, the monetite blocks appeared to be infiltrated by newly formed bone, without histological signs of necrosis, osteolysis or foreign body reaction. Histomorphometry revealed that bone augmentation occurred within and over the monetite block. The 4.0- and 3.0-mm high blocks were filled with newly formed bone with 35% and 41% of their respective volumes. These observations indicated that craniofacial bone augmentations of at least 4 mm could be achieved with synthetic monetite blocks. CONCLUSION: Within the limits of our study, this novel material may be able to eliminate the need for autologous bone transplantation for the augmentation of large vertical bone defects.

Three-dimensional mineralization of dense nanofibrillar collagen-bioglass hybrid scaffolds.

Scaffolds for bone tissue engineering must meet a number of requirements such as biocompatibility, osteoconductivity, osteoinductivity, biodegradability, and appropriate biomechanical properties. A combination of type I collagen and 45S5 Bioglass may meet these requirements, however, little has been demonstrated on the effect of Bioglass on the potential of the collagen nanofibrillar three-dimensional mineralization and its influence on the structural and mechanical properties of the scaffolds. In this work, rapidly fabricated dense collagen-Bioglass hybrid scaffolds were assessed for their potential for immediate implantation. Hybrid scaffolds were conditioned, in vitro, in simulated body fluid (SBF) for up to 14 days and assessed in terms of changes in structural, chemical, and mechanical properties. MicroCT and SEM analyses showed a homogeneous distribution of Bioglass particles in the as-made hybrids. Mineralization was detected at day 1 in SBF, while ATR-FTIR microscopy and XRD revealed the presence of hydroxyl-carbonated apatite on the surface and within the two hybrid scaffolds at days 7 and 14. FTIR and SEM confirmed that the triple helical structure and typical banding pattern of fibrillar collagen was maintained as a function of time in SBF. Principal component analysis executed on ATR-FTIR microscopy revealed that the mineralization extent was a function of both Bioglass content and conditioning time in SBF. Tensile mechanical analysis showed an increase in the elastic modulus and a corresponding decrease in strain at ultimate tensile strength (UTS) as imparted by mineralization of scaffolds as a function of time in SBF and Bioglass content. Change in UTS was affected by Bioglass content. These results suggested the achievement of a hybrid matrix potentially suitable for bone tissue engineering.

Effects of Oxygen and Glucose on Bone Marrow Mesenchymal Stem Cell Culture.

This study determines whether the viability of mesenchymal stem cell (MSC) in vitro is most sensitive to oxygen supply, energetic substrate supply, or accumulation of lactate. Mouse unmodified (wild type (WT)) and erythropoietin (EPO) gene-modified MSC is cultured for 7 days in normoxic (21%) and anoxic conditions. WT-MSC is cultured in anoxia for 45 days in high and regular glucose media and both have similar viability when compared to their normoxic controls at 7 days. Protein production of EPO-MSC is unaffected by the absence of oxygen. MSC doubling time and post-anoxic exposure is increased (WT: 32.3-73.3 h; EPO: 27.2-115 h). High glucose leads to a 37% increase in cell viability at 13 days and 17% at 30 days, indicating that MSC anoxic survival is affected by supply of metabolic substrate. However, after 30 days, little difference in viability is found, and at 45 days, complete cell death occurs in both the conditions. This death cannot be attributed to lack of glucose or lactate levels. MSC stemness is retained for both osteogenic and adipogenic differentiations. The absence of oxygen increases the doubling time of MSC but does not affect their viability, protein production, or differentiation capacity.

Osteopontin functions as an opsonin and facilitates phagocytosis by macrophages of hydroxyapatite-coated microspheres: implications for bone wound healing.

Osteopontin (OPN) is a secreted protein abundant in mineralized tissue extracellular matrices and bodily fluids. Previously we have shown that mineralized debris at surgical wound sites in bone and teeth are coated by macrophage-derived OPN and phagocytosed. Here, we have performed opsonophagocytosis assays to determine whether OPN acts as an opsonin and facilitates phagocytosis by macrophages of protein- and hydroxyapatite mineral-coated microspheres. Moreover, we have examined the opsonization effects of monomer OPN versus OPN polymerized (crosslinked) by tissue transglutaminase 2. Murine macrophages J774A.1 were exposed to polystyrene-latex microspheres having different surface chemistries (non-ionic, aldehyde amidine, carboxyl and aliphatic amine) which were coated with either serum albumin, immunoglobulin, monomer OPN or polymer OPN. Similar experiments with the same protein coatings were performed using hydroxyapatite-covered microspheres. Internalization of microspheres by phagocytosis into macrophages was confirmed by co-localization with the (phago)lysosomal markers lysosome-associated membrane protein-1 (Lamp-1) and LysoTracker, and by light microscopy and transmission electron microscopy after serial sectioning of plastic/resin-embedded cells containing microspheres. OPN significantly increased phagocytosis of both microspheres and hydroxyapatite-covered microspheres compared to negative controls (albumin-coated and uncoated microspheres), with phagocytic indices similar to, or greater than, those of the positive control (IgG-coated). The effect of OPN and hydroxyapatite on microsphere phagocytosis was synergistic. Polymer OPN further enhanced the phagocytosis of aliphatic amine and aldehyde amidine microspheres. Taken together, these results indicate that OPN is an effective opsonin able to facilitate particle uptake (including mineralized particles) by macrophages.

The importance of particle size and DNA condensation salt for calcium phosphate nanoparticle transfection.

Calcium phosphate has been used for over 30 years to deliver genetic material to mammalian cells. This vector has proven advantages over other transfection species such as viruses and dendrimers in terms of superior biocompatibility and reduced immune response. However, clinical application of calcium phosphate based transfection techniques is hampered by poor understanding of the key factors underlying its action. Despite widespread in vitro use, little attention has been given to the physico-chemical characteristics of the calcium phosphate particles mediating transfection. In this study parameters were optimised to produce calcium phosphate nanoparticles onto which plasmid DNA (pDNA) was adsorbed that were more effective than a commercial dendrimer vector in delivering pDNA to an osteoblastic cell line and compared favourably in a fibroblastic cell line without the need for special culture conditions such as cell cycle synchronization or glycerol shock treatment. Addition of the pDNA after nanoparticle synthesis allowed for characterisation of particle morphology, size, surface charge and composition. We found that the key parameters for effective calcium phosphate nanoparticle transfection were an optimal concentration of calcium and chloride ions and a nanosized non-agglomerated precipitate.

The use of RANKL-coated brushite cement to stimulate bone remodelling.

Calcium phosphate cements were first proposed as synthetic bone substitutes over two decades ago, however, they are characterised by slow chemical or cellular resorption and a slow osteointegration. In contrast, bone autograft has been shown to stimulate osteoclastogenesis and angiogenesis resulting in active bone remodelling and rapid graft incorporation. Therefore, we aimed to develop a biomaterial able to release a key stimulator of the bone remodelling process, cytokine RANKL. Cylinders of brushite cement, hydroxyapatite cement and sodium alginate were loaded with RANKL either by incorporation into the cement or by coating the material with soluble RANKL. To test the biological activity of these formulations, we assessed their effectiveness in inducing osteoclast formation from RAW 264.7 monocytic cell line. Only brushite and hydroxyapatite cements coated with RANKL allowed for retaining sufficient biological activity to induce osteoclast formation. Most efficient was coating 40 mg cylinder of brushite cement with 800 ng RANKL. We have found that RANKL-coated brushite cement exhibits osteoclastogenic activity for at least 1 month at 37 degrees C. Thus, we developed a formulation of brushite cement with RANKL - a synthetic bone graft that is similar to autografts in its ability to actively induce osteoclastogenesis.

Osteoconduction and osteoinduction of low-temperature 3D printed bioceramic implants.

Rapid prototyping is a valuable implant production tool that enables the investigation of individual geometric parameters, such as shape, porosity, pore size and permeability, on the biological performance of synthetic bone graft substitutes. In the present study, we have employed low-temperature direct 3D printing to produce brushite and monetite implants with different geometries. Blocks predominantly consisting of brushite with channels either open or closed to the exterior were implanted on the decorticated lumbar transverse processes of goats for 12 weeks. In addition, similar blocks with closed channel geometry, consisting of either brushite or monetite were implanted intramuscularly. The design of the channels allowed investigation of the effect of macropore geometry (open and closed pores) and osteoinduction on bone formation orthotopically. Intramuscular implantation resulted in bone formation within the channels of both monetite and brushite, indicating osteoinductivity of these resorbable materials. Inside the blocks mounted on the transverse processes, initial channel shape did not seem to significantly influence the final amount of formed bone and osteoinduction was suggested to contribute to bone formation.

Bioactivity of bone resorptive factor loaded on osteoconductive matrices: stability post-dehydration.

Since calcium phosphate cements were proposed two decades ago, extensive research has been realized to develop and improve their properties. They have proved their efficiency as bone graft substitutes and their ability to incorporate and release drugs. However, to date, all 'resorbable' osteoconductive synthetic biomaterials are in fact simply soluble. In order to investigate a synthetic material capable of inducing osteoclast remodelling post-implantation, a formulation of calcium phosphate cement loaded with a pro-resorptive cytokine (RANKL) was studied. Many prior release studies on calcium phosphates did not confirm that the matrix had no detrimental effect on the molecule to be released during storage prior to use or that bioactivity was maintained during storage. In this report, the stability of our protein was tested after loading onto the cement, and various regimens to improve stability were compared. The presence of trehalose was shown to stabilize the bioactivity of RANKL adsorbed to brushite cement. The reduction of both moisture and oxygen in the storage vessel improved osteoclastogenic potential of the matrix compared with that stored in ambient atmosphere and temperature. No loss in activity was observed over the study period for the loaded matrix stored in dry nitrogen.

Modeling vancomycin release kinetics from microporous calcium phosphate ceramics comparing static and dynamic immersion conditions.

The release kinetics of vancomycin from calcium phosphate dihydrate (brushite) matrices and polymer/brushite composites were compared using different fluid replacement regimes, a regular replacement (static conditions) and a continuous flow technique (dynamic conditions). The use of a constantly refreshed flowing resulted in a faster drug release due to a constantly high diffusion gradient between drug loaded matrix and the eluting medium. Drug release was modeled using the Weibull, Peppas and Higuchi equations. The results showed that drug liberation was diffusion controlled for the ceramics matrices, whereas ceramics/polymer composites led to a mixed diffusion and degradation controlled release mechanism. The continuous flow technique was for these materials responsible for a faster release due to an accelerated polymer degradation rate compared with the regular fluid replacement technique.

Characterization of chlorhexidine-releasing, fast-setting, brushite bone cements.

The effect of antibacterial chlorhexidine diacetate powder (CHX) on the setting kinetics of a brushite-forming beta-tricalcium phosphate/monocalcium phosphate monohydrate (beta-TCP/MCPM) cement was monitored using attenuated total reflection Fourier transform infrared spectroscopy. The final composition of the set cement with up to 12 wt.% CHX content before and after submersion in water for 24h, the kinetics of chlorhexidine release and the total sample mass change in water over four weeks was monitored using Raman mapping, UV spectroscopy and gravimetry, respectively. Below 9 wt.%, CHX content had no significant effect on brushite formation rate at 37 degrees C, but at 12 wt.% the half-life of the reaction decreased by one-third. Raman mapping confirmed that brushite was the main inorganic component of the set cements irrespective of CHX content, both before and after submersion in water. The CHX could be detected largely as discrete solid particles but could also be observed partially dispersed throughout the pores of the set cement. The percentage of CHX release was found to follow Fick's law of diffusion, being independent of its initial concentration, proportional to the square root of time and, with 1mm thick specimens, 60% was released at 24h. Total set cement mass loss rate was not significantly affected by CHX content. On average, cements exhibited a loss of 7 wt.% assigned largely to surface phosphate particle loss within the initial 8h followed by 0.36 wt.% per day.

Brushite-collagen composites for bone regeneration.

Brushite-based biomaterials are of special interest in bone regeneration due to their biocompatibility and biodegradability; on the other hand, collagen is a well-known osteoconductive biomaterial. In the present study a new brushite-collagen composite biomaterial is reported. This new biomaterial was prepared by combining citric acid/collagen type I solutions with a brushite cement powder. The obtained biomaterial was a cement paste, with improved handling properties. The effect of collagen on the setting reaction of brushite cement was studied, and was found to speed up the cement setting reaction. The cement paste set into a hard ceramic material within 18.5+/-2.1min and had compressive strength similar to that of spongeous bone (48.9+/-5.9MPa in dry conditions and 12.7+/-1.5MPa in humid conditions). The combination of collagen with citric acid revealed an interesting synergistic effect on the compressive strength of the composite material. Moreover, this new biomaterial had excellent cohesion properties (ninefold better than brushite cement), and high cellular adhesion capacity (threefold higher than brushite cement). The composite biomaterial described in this study combines good handling properties, compressive strength, cohesion and cell adhesion capacity, along with the osteoconductive and biodegradable properties inherent in brushite and in collagen-based biomaterials.

Influence of calcium phosphate crystal assemblies on the proliferation and osteogenic gene expression of rat bone marrow stromal cells.

Calcium phosphates (CaPs) have been investigated as substrates to promote bone formation both in vitro and in vivo. The aim of this study was to examine the proliferation and differentiation of rat bone marrow stromal cells (BMSCs) cultured on three-dimensional (3D) octacalcium phosphate (OCP) crystal assemblies. The cytotoxicity of OCP crystal assemblies was evaluated by measuring the lactate dehydrogenase (LDH) release from BMSCs during 10h of incubation with OCP crystal assemblies. The proliferation of BMSCs on OCP crystal assemblies in medium with or without osteogenic supplements was also investigated using the MTT assay with tissue culture treated plastic (TP) as the control. The tissues formed by BMSCs cultured on OCP crystal assemblies for 24 days were examined following staining with haematoxylin and eosin (H&E), alkaline phosphatase (ALP) and Van Gieson's techniques. The influence of OCP crystal assemblies on mRNA expression of alpha chain of collagen type I (Coll-Ia), ALP and osteocalcin (OC), osteonectin (ON), osteopontin (OP), lumican, Cbfa1, EST317 and EST350 by the BMSCs were also investigated using semi-quantitative RT-PCR. Although OCP crystals were relatively cytotoxic compared with TP, proliferation of BMSCs occurred when seeded onto OCP crystal assemblies. BMSCs cultured on OCP demonstrated similar proliferation rates as found on the control and no significant difference (P<0.05) in the number of cells cultured in medium supplemented with or without osteogenic additives on TP and OCP. The deposition of collagen and ALP were detected in tissue synthesised by BMSCs cultured on OCP crystals assemblies. OCP crystal assemblies down-regulated basal bone ECM proteins, including Coll-Ia, ON and lumican, in the first week of culture, whilst up-regulation of the same genes was observed after 24 days of culture. The observed down-regulation of Cbfa1 on OCP substrates was consistent with the negative effect of OCP crystal assemblies on the genes encoding bone ECM proteins. The up-regulation of OC mRNA expression by OCP crystal assemblies could be related to the requirement for synthesis of more OC proteins to control the concentration of calcium ions in culture medium.

Antimicrobial properties of nanocrystalline tetracalcium phosphate cements.

The antimicrobial properties of cements prepared from mechanically activated tetracalcium phosphate (maTTCP) were tested with the agar diffusion test using Streptococcus salivarius, Staphylococcus epidermidis, and a clinically isolated plaque mixture. All maTTCP cements showed a significantly higher antimicrobial potency as revealed by inhibition zones of approximately 3-5 mm width, compared with a commercial Ca(OH)(2)//salicylate cement which only produced small inhibition zones around the cement specimens of 1.5 mm or less. This behavior was explained by the formation of amorphous Ca(OH)(2) during setting of maTTCP cements, which is thought to have a higher solubility and may release more OH(-) ions than conventional Ca(OH)(2)//salicylate cements. In fact, the pH value in the agar gel around the specimens was higher in the case of maTTCP cements (7.8-8.7) compared with the Ca(OH)(2)//salicylate control (7.0-8.0). The maTTCP cements did not affect the photoactivation of resin-based composites, and their antimicrobial activity is making them interesting candidates for the use as pulp-capping agents, endodontic sealers, or cavity liners in dentistry.

Mimicking oxygen delivery and waste removal functions of blood.

In addition to immunological and wound healing cell and platelet delivery, ion stasis and nutrient supply, blood delivers oxygen to cells and tissues and removes metabolic wastes. For decades researchers have been trying to develop approaches that mimic these two immediately vital functions of blood. Oxygen is crucial for the long-term survival of tissues and cells in vertebrates. Hypoxia (oxygen deficiency) and even at times anoxia (absence of oxygen) can occur during organ preservation, organ and cell transplantation, wound healing, in tumors and engineering of tissues. Different approaches have been developed to deliver oxygen to tissues and cells, including hyperbaric oxygen therapy (HBOT), normobaric hyperoxia therapy (NBOT), using biochemical reactions and electrolysis, employing liquids with high oxygen solubility, administering hemoglobin, myoglobin and red blood cells (RBCs), introducing oxygen-generating agents, using oxygen-carrying microparticles, persufflation, and peritoneal oxygenation. Metabolic waste accumulation is another issue in biological systems when blood flow is insufficient. Metabolic wastes change the microenvironment of cells and tissues, influence the metabolic activities of cells, and ultimately cause cell death. This review examines advances in blood mimicking systems in the field of biomedical engineering in terms of oxygen delivery and metabolic waste removal.