Vitrification of porcine articular cartilage

The limited availability of fresh osteochondral allograft tissues necessitates the use of banking for long-term storage. A vitrification solution containing a 55% cryoprotectant formulation, VS55, previously studied using rabbit articular cartilage, was evaluated using porcine articular cartilage. Specimens ranging from 2 to 6 mm in thickness were obtained from 6 mm distal femoral cartilage cores and cryopreserved by vitrification or freezing. The results of post-rewarming viability assessments employing alamarBlue demonstrated a large decrease (p < 0.001) in viability in all three sizes of cartilage specimen vitrified with VS55. This is in marked contrast with prior experience with full thickness, 0.6 mm rabbit cartilage. Microscopic examination following cryosubstitution confirmed ice formation in the chondrocytes of porcine cartilage vitrified using VS55. Experiments using a more concentrated vitrification formulation (83%), VS83, showed a significant treatment benefit for larger segments of articular cartilage. Differences between the VS55 and the VS83 treatment groups were significant at p < 0.001 for 2 mm and 4 mm plugs, and at p < 0.01 for full thickness, 6 mm plugs. The percentage viability in fresh controls, compared to VS55 and VS83, was 24.7% and 80.7% in the 2 mm size group, 18.2% and 55.5% in the 4 mm size group, and 5.2% and 43.6% in the 6 mm group, respectively. The results of this study continue to indicate that vitrification is superior to conventional cryopreservation with low concentrations of dimethyl sulfoxide by freezing for cartilage. The vitrification technology presented here may, with further process development, enable the long-term storage and transportation of living cartilage for repair of human articular surfaces.     

Biological applications of second harmonic imaging

Second Harmonic Generation (SHG) microscopy dates back to 1974, but effective biological use of the technique has a history of barely 10 years. It is now widely used to image collagen in many different applications, and is becoming useful for imaging myosin and some polysaccharides. A separate line on research has focussed on SHG dyes, which can provide high-speed indication of membrane potential and are now in use in neurobiology. This review looks at the progress to date in these different fields.     

Cryopreservation of cartilage cell and tissue for biobanking

Preservation of cell and tissue samples from endangered species is a part of biodiversity conservation strategy. Therefore, setting up proper cell and tissue cryopreservation methods is very important as these tissue samples and cells could be used to reintroduce the lost genes into the breeding pool by nuclear transfer. In this study, we investigated the effect of vitrification and slow freezing on cartilage cell and tissue viability for biobanking. Firstly, primary adult cartilage cells (ACCs) and fetal cartilage cells (FCC) were cryopreserved by vitrification and slow freezing. Cells were vitrified after a two-step equilibration in a solution composed of ethylene glycol (EG), Ficoll and sucrose. For slow freezing three different cooling rates (0.5, 1 and 2 °C/min) were tested in straws. Secondly, the tissues taken from articular cartilage were cryopreserved by vitrification and slow freezing (1 °C/min). The results revealed no significant difference between the viability ratios, proliferative activity and GAG synthesis of cartilage cells which were cryopreserved by using vitrification or slow freezing methods. Despite the significant decrease in the viability ratio of freeze–thawed cartilage tissues, cryopreservation did not prevent the establishment of primary cell cultures from cartilage tissues. The results revealed that the vitrification method could be recommended to cryopreserve cartilage tissue and cells from bovine to be used as alternative cell donor sources in nuclear transfer studies for biobanking as a part of biodiversity conservation strategy. Moreover, cartilage cell suspensions were successfully cryopreserved in straws by using a controlled-rate freezing machine in the present study.     

Further work on the cryopreservation of articular cartilage with particular reference to the liquidus tracking (LT) method

The cryopreservation of articular cartilage with survival of living cells has been a difficult problem. We have provided evidence that this is due to the formation of ice crystals in the chondrons. We have developed a method in which the concentration of the cryoprotectant dimethyl sulphoxide (Me(2)SO) is increased progressively, in steps, as cooling proceeds so that ice is never allowed to form, but the very high concentrations of Me(2)SO required at low temperatures are reached only at those low temperatures. In this paper, we describe some new experiments with discs of ovine articular cartilage similar to those used in our previous studies and we show that continuous stirring throughout the process resulted in a significant increase in the rate of (35)S sulphate incorporation into glycosoaminoglycans (GAGs), now reaching 87% of the corresponding fresh control values. We confirmed that the method is also effective for human knee joint cartilage, which gave 70% of fresh control ability to synthesise GAGs; continuous stirring was also used in this experiment. We then extended the method to ovine knee joint osteochondral dowels and showed that, again with continuous stirring, the method produced tissue concentrations of Me(2)SO that were sufficient to prevent freezing in dowels too, and to permit cell function at 60% of control. The most important mechanical property (instantaneous compressive modulus) was unaffected by the process. Finally, we experimented with some technical variations to facilitate clinical use-a more rapid process for warming and removal of Me(2)SO was developed and a method of short-term storage before or after cryopreservation was developed. Finally, pilot experiments were carried out to provide proof of principle for a closed, continuous flow method in which both temperature and Me(2)SO concentration were computer-controlled.     

Bimetallic ferrocenyl derivatives: Molecular second order hyperpolarizabilities and second harmonic generation

The ground and excited states dipole moments and the second order hyperpolarizabilities of a series of oxazolinyl-ferrocenyl derivatives have been measured. After complexation of the oxazoline group with a second metal ion, the new bimetallic complexes show an increased hyperpolarizability, as determined by the EFISHG technique. A copolymer of the same bimetallic complex with methyl methacrylate has been synthesized, and the second order susceptibility has been measured by second harmonic generation at 1.06µm.     

Fourier transform infrared imaging spectroscopy investigations in the pathogenesis and repair of cartilage

Significant complications in the management of osteoarthritis (OA) are the inability to identify early cartilage changes during the development of the disease, and the lack of techniques to evaluate the tissue response to therapeutic and tissue engineering interventions. In recent studies several spectroscopic parameters have been elucidated by Fourier transform infrared imaging spectroscopy (FT-IRIS) that enable evaluation of molecular and compositional changes in human cartilage with progressively severe OA, and in repair cartilage from animal models. FT-IRIS permits evaluation of early-stage matrix changes in the primary components of cartilage, collagen and proteoglycan on histological sections at a spatial resolution of ∼6.25 μm. In osteoarthritic cartilage, the collagen integrity, monitored by the ratio of peak areas at 1338 cm⁻¹/Amide II, was found to correspond to the histological Mankin grade, the gold standard scale utilized to evaluate cartilage degeneration. Apparent matrix degradation was observable in the deep zone of cartilage even in the early stages of OA. FT-IRIS studies also found that within the territorial matrix of the cartilage cells (chondrocytes), proteoglycan content increased with progression of cartilage degeneration while the collagen content remained the same, but the collagen integrity decreased. Regenerative (repair) tissue from microfracture treatment of an equine cartilage defect showed significant changes in collagen distribution and loss in proteoglycan content compared to the adjacent normal cartilage, with collagen fibrils demonstrating a random orientation in most of the repair tissue. These studies demonstrate that FT-IRIS is a powerful technique that can provide detailed ultrastructural information on heterogeneous tissues such as diseased cartilage and thus has great potential as a diagnostic modality for cartilage degradation and repair.     

Detection and imaging of non-contractile inclusions and sarcomeric anomalies in skeletal muscle by second harmonic generation combined with two-photon excited fluorescence

The large size of the multinucleated muscle fibers of skeletal muscle makes their examination for structural and pathological defects a challenge. Sections and single fibers are accessible to antibodies and other markers but imaging of such samples does not provide a three-dimensional view of the muscle. Regrettably, bundles of fibers cannot be stained or imaged easily. Two-photon microscopy techniques overcome these obstacles. Second harmonic generation (SHG) by myosin filaments and two-photon excited fluorescence (2PEF) of mitochondrial and lysosomal components provides detailed structural information on unstained tissue. Furthermore, the infrared exciting light can penetrate several layers of muscle fibers and the minimal processing is particularly valuable for fragile biopsies. Here we demonstrate the usefulness of SHG, combined with 2PEF, to reveal enlarged lysosomes and accumulations of non-contractile material in muscles from the mouse model for the lysosomal storage disorder Pompe disease (PD), and in biopsies from adult and infant PD patients. SHG and 2PEF also detect sarcomeric defects that may presage the loss of myofibrils in atrophying muscle and signify loss of elasticity. The combination of SHG and 2PEF should be useful in the analysis and diagnosis of a wide range of skeletal muscle pathologies.     

Osteoarthritis: cellular and molecular changes in degenerating cartilage

Osteoarthritis (OA) is a disease of high ethical and economical importance. In advanced stages, the patients suffer from severe pain and restriction of mobility. The consequence in many cases is an inability to work and often the substitution of the diseased joint with an artificial implant becomes inevitable. As cartilage tissue itself has only very limited capacities of self-renewing, the development of this disorder is chronic and progressive. Generally, OA is diagnosed in more advanced stages, when clinical and radiographic signs become evident. At this time point the options for therapeutic intervention without surgery are limited. It is, therefore, crucial to know about the basic incidents in the course of OA and especially in early stages to develop new diagnostic and therapeutic strategies. Numerous studies on human osteoarthritic tissue and in animal models have addressed various aspects of OA progression to get a better understanding of the pathophysiology of this disease. This review presents an overview on different aspects of OA research and the cellular and molecular alterations in degenerating cartilage.     

Proteomic analysis of mouse growth plate cartilage

Cartilage is a highly specialized load-bearing tissue with a small number of cells and a high proportion of extracellular matrix (ECM). The abundance of heavily sulfated proteoglycans and a poorly soluble collagenous ECM presents a major technical challenge to 2-DE. Here we report proteomic analysis of mouse growth plate cartilage using novel methodology for tissue dissection and sample prefractionation. We have successfully resolved cartilage tissue extracts by 2-DE for the first time and identified cartilage ECM proteins by Western blotting and MS/MS.     

Cryopreservation of articular cartilage. Part 3: the liquidus-tracking method

Although it is relatively straightforward to cryopreserve living isolated chondrocytes, at the present time there is no satisfactory method to preserve surgical grafts between the time of procurement or manufacture and actual use. In earlier papers we have established that the cryoprotectants dimethyl sulphoxide or propylene glycol do penetrate into this tissue very rapidly. Chondrocytes are not unusually susceptible to osmotic stress; in fact they appear to be particularly resistant. It appears that damage is associated with the formation of ice per se, even at cooling rates that are optimal for the cryopreservation of isolated chondrocytes. We then showed that current methods of cartilage cryopreservation involve the nucleation and growth of ice crystals within the chondrons rather than ice being restricted to the surrounding acellular matrix. This finding established the need to avoid the crystallization of ice—in other words, vitrification. Song and his colleagues have published a vitrification method that is based on the use of one of Fahy’s vitrification formulations. We confirmed the effectiveness of this method but found it to be very dependent on ultra rapid warming. However, we were able to develop a ‘liquidus-tracking’ method that completely avoids the crystallization of ice and does not require rapid warming. The ability of cartilage preserved in this way to incorporate sulphate into newly synthesized glycosaminoglycans (GAGs) approached 70% of that of fresh control cartilage. In this method the rates of cooling and warming can be very low, which is essential for any method that is to be used in Tissue Banks to process the bulky grafts that are required by orthopaedic surgeons. Work is continuing to refine this method for Tissue Bank use.     

Quantitative imaging of fibrotic and morphological changes in liver of non-alcoholic steatohepatitis (NASH) model mice by second harmonic generation (SHG) and auto-fluorescence (AF) imaging using two-photon excitation microscopy (TPEM)

Non-alcoholic steatohepatitis (NASH) is a common liver disorder caused by fatty liver. Because NASH is associated with fibrotic and morphological changes in liver tissue, a direct imaging technique is required for accurate staging of liver tissue. For this purpose, in this study we took advantage of two label-free optical imaging techniques, second harmonic generation (SHG) and auto-fluorescence (AF), using two-photon excitation microscopy (TPEM). Three-dimensional ex vivo imaging of tissues from NASH model mice, followed by image processing, revealed that SHG and AF are sufficient to quantitatively characterize the hepatic capsule at an early stage and parenchymal morphologies associated with liver disease progression, respectively.     

High resolution imaging of collagen organisation and synthesis using a versatile collagen specific probe

Collagen is the protein primarily responsible for the load-bearing properties of tissues and collagen architecture is one of the main determinants of the mechanical properties of tissues. Visualisation of changes in collagen three-dimensional structure is essential in order to improve our understanding of collagen fibril formation and remodelling, e.g. in tissue engineering experiments. A recently developed collagen probe, based on a natural collagen binding protein (CNA35) conjugated to a fluorescent dye, showed to be much more specific to collagen than existing fluorescent techniques currently used for collagen visualisation in live tissues. In this paper, imaging with this fluorescent CNA35 probe was compared to imaging with second harmonic generation (SHG) and the imaging of two- and three-dimensional collagen organisation was further developed. A range of samples (cell culture, blood vessels and engineered tissues) was imaged to illustrate the potential of this collagen probe. This images of collagen organisation showed improved detail compared to images generated with SHG, which is currently the most effective method for viewing three-dimensional collagen organisation in tissues. In conclusion, the fluorescent CNA35 probe allows easy access to high resolution imaging of collagen, ranging from very young fibrils to more mature collagen fibres. Furthermore, this probe enabled real-time visualisation of collagen synthesis in cell culture, which provides new opportunities to study collagen synthesis and remodelling.     

Second harmonic generation microscopy reveals altered collagen microstructure in usual interstitial pneumonia versus healthy lung

Background

It is not understood why some pulmonary fibroses such as cryptogenic organizing pneumonia (COP) respond well to treatment, while others like usual interstitial pneumonia (UIP) do not. Increased understanding of the structure and function of the matrix in this area is critical to improving our understanding of the biology of these diseases and developing novel therapies. The objectives herein are to provide new insights into the underlying collagen- and matrix-related biological mechanisms driving COP versus UIP.

Methods

Two-photon second harmonic generation (SHG) and excitation fluorescence microscopies were used to interrogate and quantify differences between intrinsic fibrillar collagen and elastin matrix signals in healthy, COP, and UIP lung.

Results

Collagen microstructure was different in UIP versus healthy lung, but not in COP versus healthy, as indicated by the ratio of forward-to-backward propagating SHG signal (F_SHG/B_SHG). This collagen microstructure as assessed by F_SHG/B_SHG was also different in areas with preserved alveolar architecture adjacent to UIP fibroblastic foci or honeycomb areas versus healthy lung. Fibrosis was evidenced by increased col1 and col3 content in COP and UIP versus healthy, with highest col1:col3 ratio in UIP. Evidence of elastin breakdown (i.e. reduced mature elastin fiber content), and increased collagen:mature elastin ratios, were seen in COP and UIP versus healthy.

Conclusions

Fibrillar collagen’s subresolution structure (i.e. “microstructure”) is altered in UIP versus COP and healthy lung, which may provide novel insights into the biological reasons why unlike COP, UIP is resistant to therapies, and demonstrates the ability of SHG microscopy to potentially distinguish treatable versus intractable pulmonary fibroses.     

Modeling the dynamic composition of engineered cartilage

Mathematical models to describe extracellular matrix (ECM) deposition and scaffold degradation in cell-polymer constructs for the design of engineered cartilage were developed and validated. The ECM deposition model characterized a product-inhibition mechanism in the concentration of cartilage molecules, collagen and glycosaminoglycans (GAG). The scaffold degradation model used first-order kinetics to describe hydrolysis (not limited by diffusion) of biodegradable polyesters, polyglycolic acid and polylactic acid. Each model was fit to published accumulation and degradation data. As experimental validation, cell-polymer constructs (n=24) and unseeded scaffolds (n=24) were cultured in vitro. Biochemical assays for ECM content and measurements of scaffold mass were performed at 1, 2, 4, 6, 8, or 10 weeks (n=8 per time point). The models demonstrated a strong fit with published data and experimental results (R(2)=0.75 to 0.99) and predicted the temporal total construct mass with reasonable accuracy (30% RMS error). This approach can elucidate mechanisms governing accumulation/degradation and may be coupled with structure-function relationships to describe time-dependent changes in construct elastic properties.     

Synthesis rates and binding kinetics of matrix products in engineered cartilage constructs using chondrocyte-seeded agarose gels

Large-sized cartilage constructs suffer from inhomogeneous extracellular matrix deposition due to insufficient nutrient availability. Computational models of nutrient consumption and tissue growth can be utilized as an efficient alternative to experimental trials to optimize the culture of large constructs; models require system-specific growth and consumption parameters. To inform models of the [bovine chondrocyte]−[agarose gel] system, total synthesis rate (matrix accumulation rate+matrix release rate) and matrix retention fractions of glycosaminoglycans (GAG), collagen, and cartilage oligomeric matrix protein (COMP) were measured either in the presence (continuous or transient) or absence of TGF-β3 supplementation. TGF-β3's influences on pyridinoline content and mechanical properties were also measured. Reversible binding kinetic parameters were characterized using computational models. Based on our recent nutrient supplementation work, we measured glucose consumption and critical glucose concentration for tissue growth to computationally simulate the culture of a human patella-sized tissue construct, reproducing the experiment of Hung et al. (2003). Transient TGF-β3 produced the highest GAG synthesis rate, highest GAG retention ratio, and the highest binding affinity; collagen synthesis was elevated in TGF-β3 supplementation groups over control, with the highest binding affinity observed in the transient supplementation group; both COMP synthesis and retention were lower than those for GAG and collagen. These results informed the modeling of GAG deposition within a large patella construct; this computational example was similar to the previous experimental results without further adjustments to modeling parameters. These results suggest that these nutrient consumption and matrix synthesis models are an attractive alternative for optimizing the culture of large-sized constructs.     

Retained structural integrity of collagen and elastin within cryopreserved human heart valve tissue as detected by two-photon laser scanning confocal microscopy

Cryopreservation is commonly used for the long-term storage of heart valve allografts. Despite the excellent hemodynamic performance and durability of cryopreserved allografts, reports have questioned whether cryopreservation affects the valvular structural proteins, collagen and elastin. This study uses two-photon laser scanning confocal microscopy (LSCM) to evaluate the effect of cryopreservation on collagen and elastin integrity within the leaflet and conduit of aortic and pulmonary human heart valves. To permit pairwise comparisons of fresh and cryopreserved tissue, test valves were bisected longitudinally with one segment imaged fresh and the other imaged after cryopreservation and brief storage in liquid nitrogen. Collagen was detected by second harmonic generation (SHG) stimulation and elastin by autofluorescence excitation. Qualitative analysis of all resultant images indicated the maintenance of collagen and elastin structure within leaflet and conduit post-cryopreservation. Analysis of the optimized percent laser transmission (OPLT) required for full dynamic range imaging of collagen and elastin showed that OPLT observations were highly variable among both fresh and cryopreserved samples. Changes in donor-specific average OPLT in response to cryopreservation exhibited no consistent directional trend. The donor-aggregated results predominantly showed no statistically significant change in collagen and elastin average OPLT due to cryopreservation. Since OPLT has an inverse relationship with structural signal intensity, these results indicate that there was largely no statistical difference in collagen and elastin signal strength between fresh and cryopreserved tissue. Overall, this study indicates that the conventional cryopreservation of human heart valve allografts does not detrimentally affect their collagen and elastin structural integrity.     

Effects of rapid cooling on articular cartilage

In order to improve the technique and protocols of cryopreservation of articular cartilage, a study was carried out to assess the effects of rapid cooling on the intact articular cartilage. Cartilage slices with a thickness ranging from 0.2 to 0.5 mm taken from bovine metacarpal-phalangeal joints were subjected to rapid cooling by immersing them in liquid nitrogen with and without treatment of the VS55 cryoprotective agent (CPA). The ultrastructure, chondrocyte viability, swelling property, and glycosaminoglycan (GAG) content were then examined before and after cryopreservation to give qualitative and quantitative evaluation on the functional state of both chondrocytes and extracellular matrix. The transmission electron microscopy study demonstrated that damage to chondrocytes without CPA was far more pronounced than those with VS55 protection while the structure of the extracellular matrix altered little in either group. The cell viability assay showed that although the exposure to VS55 led to about 36% chondrocytes losing membrane integrity, the VS55 could provide protection to chondrocytes during rapid cooling and thawing, with approximately 51% of the cells having survived rapid cooling compared to fewer than 5% in the absence of CPA. There were no significant differences in degrees of swelling or the GAG contents of cartilage slices after cryopreservation indicating rapid freezing caused little damage to the matrix. Future research activities include searching improved CPA formulation, optimising the treatment protocol and investigating the long-term effects of rapid cooling on articular cartilage.     

Intraocular multiphoton microscopy with subcellular spatial resolution by infrared femtosecond lasers

We reported on the in situ nonlinear optical sectioning of the corneal and retinal tissues based on the multiphoton microscopy (MPM) with different excitation wavelengths of infrared femtosecond (fs) lasers. The multiphoton nonlinear processing including two-photon fluorescence (2PF) and second harmonic generation (SHG) was induced under condition of high light intensities on an order of MW-GW/cm². The laser beams emitted from the solid-state Ti: sapphire systems were focused in a 0.1 femtoliter focus volume of a high numerous aperture diffraction-limited objective (40 × 1.3 N.A., oil). The corneal layers have been visualized using nonlinear optical tomography. In particular, corneal Bowman’s layer was optically determined in situ. The cellular and collagen components of tissues were selectively displayed with submicron spatial resolution and high efficiency without any assistance of staining or slicing. The preliminary study on retinal optical tomography is here also reported. MPM is a promising and convenient non-invasive technique by which the tissue layers can be visualized and the selective displaying of the tissue microstructures be realized. The optical biopsy based on intrinsic emission of MPM yields details that provide three-dimensional displaying of the tissue component and even have the potential to be used in clinical diagnostics.Dedicated on the occasion of the 66th birthday of Professor Dr. Karl-Juergen Halbhuber     

Matrix disruptions, growth, and degradation of cartilage with impaired sulfation

Diastrophic dysplasia (DTD) is an incurable recessive chondrodysplasia caused by mutations in the SLC26A2 transporter responsible for sulfate uptake by chondrocytes. The mutations cause undersulfation of glycosaminoglycans in cartilage. Studies of dtd mice with a knock-in Slc26a2 mutation showed an unusual progression of the disorder: net undersulfation is mild and normalizing with age, but the articular cartilage degrades with age and bones develop abnormally. To understand underlying mechanisms, we studied newborn dtd mice. We developed, verified and used high-definition infrared hyperspectral imaging of cartilage sections at physiological conditions, to quantify collagen and its orientation, noncollagenous proteins, and chondroitin chains, and their sulfation with 6-μm spatial resolution and without labeling. We found that chondroitin sulfation across the proximal femur cartilage varied dramatically in dtd, but not in the wild type. Corresponding undersulfation of dtd was mild in most regions, but strong in narrow articular and growth plate regions crucial for bone development. This undersulfation correlated with the chondroitin synthesis rate measured via radioactive sulfate incorporation, explaining the sulfation normalization with age. Collagen orientation was reduced, and the reduction correlated with chondroitin undersulfation. Such disorientation involved the layer of collagen covering the articular surface and protecting cartilage from degradation. Malformation of this layer may contribute to the degradation progression with age and to collagen and proteoglycan depletion from the articular region, which we observed in mice already at birth. The results provide clues to in vivo sulfation, DTD treatment, and cartilage growth.