Paper-Based Quantification of Male Fertility Potential.

BACKGROUND: More than 70 million couples worldwide are affected by infertility, with male-factor infertility accounting for about half of the cases. Semen analysis is critical for determining male fertility potential, but conventional testing is costly and complex. Here, we demonstrate a paper-based microfluidic approach to quantify male fertility potential, simultaneously measuring 3 critical semen parameters in 10 min: live and motile sperm concentrations and sperm motility. METHODS: The device measures the colorimetric change of yellow tetrazolium dye to purple formazan by the diaphorase flavoprotein enzyme present in metabolically active human sperm to quantify live and motile sperm concentration. Sperm motility was determined as the ratio of motile to live sperm. We assessed the performance of the device by use of clinical semen samples, in parallel with standard clinical approaches. RESULTS: Detection limits of 8.46 and 15.18 million/mL were achieved for live and motile sperm concentrations, respectively. The live and motile sperm concentrations and motility values from our device correlated with those of the standard clinical approaches (R(2) ≥ 0.84). In all cases, our device provided 100% agreement in terms of clinical outcome. The device was also robust and could tolerate conditions of high absolute humidity (22.8 g/m(3)) up to 16 weeks when packaged with desiccant. CONCLUSIONS: Our device outperforms existing commercial paper-based assays by quantitatively measuring live and motile sperm concentrations and motility, in only 10 min. This approach is applicable to current clinical practices as well as self-diagnostic applications.

Effect of chitosan incorporation and scaffold geometry on chondrocyte function in dense collagen type I hydrogels.

Tissue engineering approaches for articular cartilage (AC) repair using collagen type I (Coll)-based hydrogels are limited by their low collagen fibril density (CFD; <0.5 wt%) and their poor capacity to support chondrocyte differentiation. Chitosan (CTS) is a well-characterized polysaccharide that mimics the glycosaminoglycans (GAGs) present in native AC extracellular matrix and exhibits chondroprotective properties. Here dense Coll/CTS hydrogel discs (16 mm diameter, 140-250 µm thickness) with CFD (∼6 wt%) approaching that of AC were developed to investigate the effect of CTS content on the growth and differentiation of three-dimensionally seeded RCJ3.1C5.18 chondroprogenitor cells. Compared to dense Coll alone, cells seeded within Coll/CTS showed increased viability and metabolic activity, as well as a decrease in cell-mediated gel contraction. Immunohistochemistry for collagen type II, in combination with Safranin O staining and GAG quantification, indicated greater chondroprogenitor differentiation within Coll/CTS, compared to cells seeded within Coll alone. The complex interplay between scaffold geometry, microstructure, composition, mechanical properties and cell function was further evaluated by rolling dense planar sheets to prepare cylindrically shaped constructs having clinically relevant diameters (3-5 mm diameter, 9 mm height). The compressive modulus of the cylindrically shaped constructs decreased significantly after 7 days in culture, and remained unchanged up to 21 days for each scaffold composition. Unlike Coll, cells seeded within Coll/CTS showed greater viability along the entire radial extent of the cylindrical rolls and increased GAG production at each time point. While GAG content decreased over time and reduced cell viability was observed within the core region of all cylindrical rolls, the incorporation of CTS diminished both these effects. In summary, these findings provide insight into the challenges involved when scaling up scaffolds designed and optimised in vitro for tissue repair.

Osteoid-mimicking dense collagen/chitosan hybrid gels.

Bone extracellular matrix (ECM) is a 3D network, composed of collagen type I and a number of other macromolecules, including glycosaminoglycans (GAGs), which stimulate signaling pathways that regulate osteoblast growth and differentiation. To model the ECM of bone for tissue regenerative approaches, dense collagen/chitosan (Coll/CTS) hybrid hydrogels were developed using different proportions of CTS to mimic GAG components of the ECM. MC3T3-E1 mouse calvaria preosteoblasts were seeded within plastically compressed Coll/CTS hydrogels with solid content approaching that of native bone osteoid. Dense, cellular Coll/CTS hybrids were maintained for up to 8 weeks under either basal or osteogenic conditions. Higher CTS content significantly increased gel resistance to collagenase degradation. The incorporation of CTS to collagen gels decreased the apparent tensile modulus from 1.82 to 0.33 MPa. In contrast, the compressive modulus of Coll/CTS hybrids increased in direct proportion to CTS content exhibiting an increase from 23.50 to 55.25 kPa. CTS incorporation also led to an increase in scaffold resistance to cell-induced contraction. MC3T3-E1 viability, proliferation, and matrix remodeling capability (via matrix metalloproteinase expression) were maintained. Alkaline phosphatase activity was increased up to two-fold, and quantification of phosphate mineral deposition was significantly increased with CTS incorporation. Thus, dense Coll/CTS scaffolds provide osteoid-like models for the study of osteoblast differentiation and bone tissue engineering.

Osteopontin and wound healing in bone.

Bone wound healing after surgical drilling/cutting initially involves a typical inflammatory response with a leukocyte-rich cell infiltrate whose professional phagocytes (neutrophils and macrophages) clear the wound site of various bacterial (if present), particulate, and insoluble components arising from the original wounding event. As part of this process, in a surgical model of bone repair in rats, osteopontin (OPN) secreted by macrophages - with its known mineral-binding properties arising from abundant calcium-binding phosphorylations and overall net negative charge - binds to the newly exposed mineralized surfaces of particulate bone debris and the osseous wound margins created by the drilling, as shown by high-resolution immunogold labeling and transmission electron microscopy. For bone debris powder, OPN serves as an opsonin for clearance by macrophage phagocytosis, as demonstrated in vitro by phagocytosis assays using cultured J774.A1 murine macrophages and OPN-coated microbeads. Macrophage-secreted OPN binding to the bone wound margins contributes to cement line (plane) formation with subsequent OPN additions to the cement line coming from osteoblast lineage cells arriving at this site to effect bone repair upon further osteoblast differentiation, and extracellular matrix deposition and mineralization. Such interfacial OPN is thought to contribute to the cell adhesion, cell signaling, and matrix mineralization events required to effectively integrate the new bone into the preexisting bone at the margins of the drill site.

An in vitro assessment of a cell-containing collagenous extracellular matrix-like scaffold for bone tissue engineering.

Extracellular matrix (ECM) consists of a complex mixture of macromolecules such as collagens, proteoglycans, glycoproteins, and elastic fibers. ECM is essential to preserving tissue architecture, signaling to cells, and regulating calcification in mineralized tissues. Osteoblasts in culture secrete and assemble an extensive ECM rich in type I collagen, and other noncollagenous proteins that can be mineralized. Three-dimensional matrix models can be used in vitro to most appropriately resemble the geometry and biochemistry of natural ECMs. In the present study, MC3T3-E1 mouse calvarial preosteoblasts were cultured within a dense three-dimensional collagenous ECM-like scaffold produced through the method of plastic compression. Plastic compression rapidly produces scaffolds of collagen density approaching native tissue levels with enhanced biomechanical properties while maintaining the viability of resident cells. The proliferation, morphology, and gene expression of seeded MC3T3s, as well as collagen production and matrix mineralization, were investigated for up to 7 weeks in culture. Soluble collagen secretion ranged in concentration from 5 to 30 microg/mL over a 24-h period, concomitant with a steady rate of collagen mRNA expression. Expression of osteogenic markers such as tissue-nonspecific alkaline phosphatase (Alpl), bone sialoprotein (Bsp), and osteopontin (Opn) examined by biochemical assay and reverse transcription-polymerase chain reaction demonstrated cell differentiation. Pericellular voids of ECM around cells, together with evidence of MMP13 mRNA expression, suggested matrix remodeling. Ultrastructural analyses, X-ray microanalysis, micro-computed tomography, as well as Fourier-transform infrared and imaging all confirmed the formation of a calcium-phosphate mineral phase within the fibrillar collagen matrix. In conclusion, preosteoblastic MC3T3 cells seeded within an ECM-like dense collagen scaffold secrete matrix proteins and induce scaffold mineralization in a manner potentially appropriate for bone tissue engineering uses.

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.

Calcium oxalate crystals in fetal bovine serum: implications for cell culture, phagocytosis and biomineralization studies in vitro.

Cell culture methods and models are key investigative tools for cell and molecular biology studies. Fetal bovine serum (FBS) is commonly used as an additive during cell culture since its constituents promote cell survival, proliferation and differentiation. Here we report that commercially available FBS from different major suppliers consistently contain precipitated, calcium oxalate crystals-either in the monohydrate (COM) or dihydrate (COD) form. Mineral structure and phase identification of the crystals were determined by X-ray diffraction, chemical composition by energy-dispersive X-ray microanalysis, and imaging and measurement of crystal growth steps by atomic force microscopy-all identified and confirmed crystallographic parameters for COM and COD. Proteins binding to the crystals were identified by immunoblotting, revealing the presence of osteopontin and fetuin-A (alpha(2)HS-glycoprotein)--known regulators of crystal growth found in serum. Macrophage cell cultures exposed to calcium oxalate crystals showed internalization of the crystals by phagocytosis in a process that induced disruption of cell-cell adhesion, release of reactive oxygen species and membrane damage, events that may be linked to the release of inflammatory cytokines by these cells into the culture media. In conclusion, calcium oxalate crystals found in commercially available FBS are toxic to cells, and their presence may confound results from in vitro studies where, amongst others, phagocytosis, biomineralization, renal cell and molecular biology, and drug and biomaterial testing are being examined.

Low density lipoprotein receptor-related protein is a calreticulin coreceptor that signals focal adhesion disassembly.

Thrombospondin (TSP) signals focal adhesion disassembly (the intermediate adhesive state) through interactions with cell surface calreticulin (CRT). TSP or a peptide (hep I) of the active site induces focal adhesion disassembly through binding to CRT, which activates phosphoinositide 3-kinase (PI3K) and extracellular signal-related kinase (ERK) through Galphai2 proteins. Because CRT is not a transmembrane protein, it is likely that CRT signals as part of a coreceptor complex. We now show that low density lipoprotein receptor-related protein (LRP) mediates focal adhesion disassembly initiated by TSP binding to CRT. LRP antagonists (antibodies, receptor-associated protein) block hep I/TSP-induced focal adhesion disassembly. LRP is necessary for TSP/hep I signaling because TSP/hep I is unable to stimulate focal adhesion disassembly or ERK or PI3K signaling in fibroblasts deficient in LRP. LRP is important in TSP-CRT signaling, as shown by the ability of hep I to stimulate association of Galphai2 with LRP. The isolated proteins LRP and CRT interact, and LRP and CRT are associated with hep I in molecular complexes extracted from cells. These data establish a mechanism of cell surface CRT signaling through its coreceptor, LRP, and suggest a novel function for LRP in regulating cell adhesion.