Decreased collagen thermal stability as a response to the loss of structural integrity of thyroid cartilage

The amino acid composition, thermal behavior and birefringence properties of thyroid cartilage tissues have been studied. A collagen component in perichondrium consists of type-I and type-II collagens whose fibers form a highly ordered anisotropic structure with a birefringence of 4.75 × 10^?3 and a melting (denaturation) temperature of 65°C. The hyaline constituent, which is visualized as a quasi-anisotropic medium, contains of only type-II collagen, which does not denature in intact tissues at temperatures up to 100°C. However, in tissues whose proteoglycane subsystem is damaged by trypsin, the denaturation of collagen takes place at 60°C. In the integral perichondrium-hyaline system, the temperature of collagen denaturation in the perichondrium reaches 75°C, which indicates the immobilization of collagen in this tissue by the extracellular matrix of the hyaline constituent.     

Transformation of the dermal collagen framework under laser heating

The aim of this study was to compare between the changes undergone by the dermal collagen framework when heated by IR laser radiation and by traditional means and to reveal the specific features of the dermal matrix modification under moderate IR laser irradiation. Rabbit skin specimens were heated to 50°C, 55°C, 60°C and 65°C in a calorimeter furnace and with a 1.68‐μm fiber Raman laser. The proportion of the degraded collagen macromolecules was determined by differential scanning calorimetry. Changes in the architectonics of the collagen framework were revealed by using standard, phase‐contrast, polarization optical and scanning electron microscopy techniques. The collagen denaturation and dermal matrix amorphization temperature in the case of laser heating proved to be lower by 10°C than that for heating in the calorimeter furnace. The IR laser treatment of the skin was found to cause a specific low‐temperature (45°C‐50°C) transformation of its collagen framework, with some collagen macromolecules remaining intact. The transformation reduces to the splitting of collagen bundles and distortion of the course of collagen fibers. The denaturation of collagen macromolecules in the case of traditional heating takes its course in a threshold manner, so that their pre‐denaturation morphological changes are insignificant.     

Water activity‐temperature state diagrams of freeze‐dried Lactobacillus acidophilus (La‐5): Influence of physical state on bacterial survival during storage

Water activity‐temperature state diagrams for Lactobacillus acidophilus freeze‐dried in a sucrose or a lactose matrix were established based on determination of stabilized glass transition temperatures by differential scanning calorimetry during equilibration with respect to water activity at fixed temperatures. The bacteria in the lactose matrix had higher stabilized glass transition temperatures for all a_w investigated. The survival of Lactobacillus acidophilus determined as colony forming units for up to 10 weeks of storage at 20°C for (i) a_w = 0.11 with both freeze‐dried matrices in the glassy state, (ii) a_w = 0.23 with the bacteria in the lactose matrix in a glassy state but with the bacteria in sucrose matrix in the nonglassy state, and (iii) a_w = 0.43 with both freeze‐dried matrices in a nonglassy state showed that the nature of the sugar was more important for storage stability than the physical state of the matrix with the nonreducing sucrose providing better stability than the reducing lactose. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

The effect of deuterium oxide on the stability of the collagen model peptides H‐(Pro‐Pro‐Gly)10‐OH,H‐(Gly‐Pro‐4(R)Hyp)9‐OH,and Type I collagen

The collagen triple helix has a larger accessible surface area per molecular mass than globular proteins, and therefore potentially more water interaction sites. The effect of deuterium oxide on the stability of collagen model peptides and Type I collagen molecules was analyzed by circular dichroism and differential scanning calorimetry. The transition temperatures (T_m) of the protonated peptide (Pro‐Pro‐Gly)₁₀ were 25.4 and 28.7°C in H₂O and D₂O, respectively. The increase of the T_m of (Pro‐Pro‐Gly)₁₀ measured calorimetrically at 1.0°C min^?1 in a low pH solution from the protonated to the deuterated solvent was 5.1°C. The increases of the T_m for (Gly‐Pro‐4(R)Hyp)₉ and pepsin‐extracted Type I collagen were measured as 4.2 and 2.2°C, respectively. These results indicated that the increase in the T_m in the presence of D₂O is comparable to that of globular proteins, and much less than reported previously for collagen model peptides [Gough and Bhatnagar, J Biomol Struct Dyn 1999, 17, 481–491]. These experimental results suggest that the interaction of water molecules with collagen is similar to the interaction of water with globular proteins, when the ratio of collagen to water is very small and collagen is monomerically dispersed in the solvent. © 2009 Wiley Periodicals, Inc. Biopolymers 93: 93–101, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Collapse temperature of solutions important for lyopreservation of living cells at ambient temperature

In this study, the collapse temperature was determined using the freeze‐drying microscopy (FDM) method for a variety of cell culture medium‐based solutions (with 0.05–0.8 M trehalose) that are important for long‐term stabilization of living cells in the dry state at ambient temperature (lyopreservation) by freeze‐drying. Being consistent with what has been reported in the literature, the collapse temperature of binary water‐trehalose solutions was found to be similar to the glass transition temperature (T′_g ～ ?30°C) of the maximally freeze‐concentrated trehalose solution (～80 wt% trehalose) during the freezing step of freeze‐drying, regardless of the initial concentration of trehalose. However, the effect of the initial trehalose concentration on the collapse temperature of the cell culture medium‐based trehalose solutions was identified to be much more significant, particularly when the trehalose concentration is less than 0.2 M (the collapse temperature can be as low as ?65°C). We also determined that cell density from 1 to 10 million cells/mL and ice seeding at high subzero temperatures (?4 and ?7°C) have negligible impact on the solution collapse temperature. However, ice seeding does significantly affect the ice crystal morphology formed during the freezing step and therefore the drying rate. Finally, bulking agents (mannitol) could significantly affect the collapse temperature only when trehalose concentration is low (<0.2 M). However, improving the collapse temperature by using a high concentration of trehalose might be preferred to the addition of bulking agents in the solutions for freeze‐drying of living cells. We further confirmed the applicability of the collapse temperature measured with small‐scale (2 µL) samples using the FDM system to freeze‐drying of large‐scale (1 mL) samples using scanning electron microscopy (SEM) data. Taken together, the results reported in this study should provide useful guidance to the development of optimal freeze‐drying protocols for lyopreservation of living cells at ambient temperature for easy maintenance and convenient wide distribution to end users, which is important to the eventual success of modern cell‐based medicine. Biotechnol. Bioeng. 2010;106: 247–259. © 2010 Wiley Periodicals, Inc.     

Freeze drying of histocompatibility typing sera.

This report describes a unit employed for the freeze drying of histocompatibility typing serum using a 50-hr cycle. This unit will process approximately 3200 3-ml vials with a final residual moisture content of less than 2%. The system employs dry ice-alcohol cooled circulating baths to maintain the condensers below ?60 °C, and two shelf cooling baths to maintain the product at required temperatures during the freeze drying process.The results of a 5-yr study of the effect of residual moisture as a function of time and storage temperature is also included. Studies conducted to date indicate that with residual moistures below 2%, freeze dried histocompatibility sera can be stored at +4 °C without the loss of significant tissue typing factors. Solubility of all serum was lost when stored at +37 °C or higher during this same 5-year period.     

Double thermal transitions of type I collagen in acidic solution

Contributed equally to this work. To further understand the origin of the double thermal transitions of collagen in acidic solution induced by heating, the denaturation of acidic soluble collagen was investigated by micro-differential scanning calorimeter (micro-DSC), circular dichroism (CD), dynamic laser light scattering (DLLS), transmission electron microscopy (TEM), and two-dimensional (2D) synchronous fluorescence spectrum. Micro-DSC experiments revealed that the collagen exhibited double thermal transitions, which were located within 31–37?°C (minor thermal transition, T _s?～?33?°C) and 37–55?°C (major thermal transition, T _m?～?40?°C), respectively. The CD spectra suggested that the thermal denaturation of collagen resulted in transition from polyproline II type structure to unordered structure. The DLLS results showed that there were mainly two kinds of collagen fibrillar aggregates with different sizes in acidic solution and the larger fibrillar aggregates (T _p2?=?40?°C) had better heat resistance than the smaller one (T _p1?=?33?°C). TEM revealed that the depolymerization of collagen fibrils occurred and the periodic cross-striations of collagen gradually disappeared with increasing temperature. The 2D fluorescence correlation spectra were also applied to investigate the thermal responses of tyrosine and phenylalanine residues at the molecular level. Finally, we could draw the conclusion that (1) the minor thermal transition was mainly due to the defibrillation of the smaller collagen fibrillar aggregates and the unfolding of a little part of triple helices; (2) the major thermal transition primarily arose from the defibrillation of the larger collagen fibrillar aggregates and the complete denaturation of the majority part of triple helices.     

Cartilage induction in vitro : Ultrastructural studies

When 19-day fetal rat triceps muscle was cultured for 7 to 14 days upon decalcified, sequentially extracted adult rat bone, cartilage formed within clefts and vascular spaces of the decalcified bone. The bone substrata were prepared by extracting tibias and femurs of Sprague-Dawley rats with 1:1 chloroform:methanol, 0.6 N HCl, 2 M CaCl₂, 0.6 M EDTA, 8 M LiCl, and H₂O at 56°C. The culture medium used was CMRL 1066 with 15% newborn calf serum. During cultivation, fibroblastic mesenchymal cells migrated out of muscle and into bone crevices where they secreted a cartilaginous matrix composed of thin, randomly dispersed collagen fibrils and proteoglycan granules. The latter are characteristic for cartilage matrix. Extracted bone matrix contained mature collagen fibrils, some of which retained their typical 640-Å banding. Other collagen fibrils were partially disaggregated and expanded to reveal component 50-Å-thick, beaded micro fibrils. Such an expansion of collagen fibrils is known to result from exposure to proteoglycan solvents such as 2 M CaCl₂. The decalcified bone matrix contained many residual devitalized cells and cell fragments which often were seen in close proximity to chondrifying mesenchymal cells. This finding indicates the possibility that residual cellular material could play a role in stimulating cartilage development.     

Preparation, properties, and uses of two fluorogenic substrates for the detection of 5'-(venom) and 3'-(spleen) nucleotide phosphodiesterases

A new method for ³H-labeling of native collagen and a specific microassay for collagenase activity are presented. Acid-soluble type I collagen derived from rat tail tendons was reacted with pyridoxal phosphate and then reduced with NaB³H₄ to yield [³H]collagen with a specific activity of more than 10 μCi/mg. With respect to rate of hydrolysis, trypsin susceptibility, and gelling properties this collagen compares favorably with biosynthetically labeled preparations. It was shown that chemical labeling procedures such as this, or N-acetylation with acetic anhydride, do not adversely affect properties of collagen which are important for its use as substrate in specific assays. The microassay employs 50-μl [³H]collagen gels (1 mg/ml) dispensed in microtest plates. At 36°C this assay combines rapid rate of hydrolysis with low trypsin susceptibility. As little as 1 ng of clostridial collagenase activity can be measured reproducibly. The high specific activity of the [³H]collagen allowed us to explore microassay conditions employing minute quantities of substrate in solution. These studies indicated that native type I collagen whether labeled or not, is cleaved in the helical region by trypsin at subdenaturation temperatures. It was concluded that, in order to remain specific, collagenase assays with collagen in solution as with collagen in fibrils must be performed at 10–12°C below the denaturation temperature, i.e., at 35–37°C with collagen gels and 27–29°C with collagen in solution.     

Exending the range of application of the biuret reaction: quantitative determination of insoluble proteins.

A method for quantitative determination of insoluble proteins by means of the biuret reaction is proposed. The sample is oxidized with excess H₂O₂, dried, and subsequently dissolved in 0.05% sodium dodecyl sulfate-1 n NaOH at 100°C. The clear solution obtained is treated with biuret reagent and the absorbance of the chromogen is measured at 35–40°C. The method is applied successfully to collagen from bovine Achilles tendon, keratin of sheep's wool, and defatted sheepskin. Biuret chromogen absorbance of H₂O₂-oxidized human serum albumin is 10 ± 0.5% lower than that obtained with the native protein.     

Freezing and high temperature thresholds of photosystem 2 compared to ice nucleation, frost and heat damage in evergreen subalpine plants

Freezing and high temperature thresholds of photosystem 2 (PS2), ice formation and frost and heat damage were measured in leaves of evergreen subalpine plants under conditions of naturally low (winter) to high (summer) PS2 efficiencies (F_V/F_M). The temperature‐dependent change in basic Chl fluorescence (F₀) (T‐F₀) technique that is usually used to assess the high temperature threshold of PS2 in a new approach was applied to test freezing temperature thresholds of PS2. T‐F₀ curves (+5 °C to ?10 °C at 2 K h^?1) revealed a significant, sudden increase in F₀ on extracellular ice formation (?4.0 or ?5.5 °C). The rise in F₀ was recorded 0.3–0.6 K below ice nucleation (10–20 min later) and was produced by freeze dehydration of cells. The rise in F₀ was not caused by frost damage, as during winter LT₅₀ was lower than ?27 °C and not by formation of ice on the leaf surface. Hence, F₀ measurements during freezing are a useful tool to distinguish between surface ice and extracellular ice inside the leaf tissue which cannot be differentiated by other ice‐detecting methods. PS2 efficiency significantly affected the shape of the high temperature T‐F₀ curves (20–65 °C at 1 K min^?1). Under F_V/F_M >0.6, two F₀ maxima were recorded. The fast rise phase to the first F₀ maximum corresponded with tissue heat damage (LT₅₀: 46.9–54.3 °C). The second F₀ maximum occurred at leaf temperatures between 55 and 60 °C. Under F_V/F_M <0.2 only, the second F₀ maximum was detectable. Lack of awareness of the missing F₀ maximum would lead to an overestimation of the PS2 high temperature threshold by >10 K; hence, under low F_V/F_M, it cannot be determined by the T‐F₀ technique.     

An optimized MALDI MSI protocol for spatial detection of tryptic peptides in fresh frozen prostate tissue

MALDI MS imaging (MSI) is a powerful analytical tool for spatial peptide detection in heterogeneous tissues. Proper sample preparation is crucial to achieve high quality, reproducible measurements. Here we developed an optimized protocol for spatially resolved proteolytic peptide detection with MALDI time-of-flight MSI of fresh frozen prostate tissue sections. The parameters tested included four different tissue washes, four methods of protein denaturation, four methods of trypsin digestion (different trypsin densities, sprayers, and incubation times), and five matrix deposition methods (different sprayers, settings, and matrix concentrations). Evaluation criteria were the number of detected and excluded peaks, percentage of high mass peaks, signal-to-noise ratio, spatial localization, and average intensities of identified peptides, all of which were integrated into a weighted quality evaluation scoring system. Based on these scores, the optimized protocol included an ice-cold EtOH+H₂O wash, a 5 min heating step at 95°C, tryptic digestion incubated for 17h at 37°C and CHCA matrix deposited at a final amount of 1.8 μg/mm². Including a heat-induced protein denaturation step after tissue wash is a new methodological approach that could be useful also for other tissue types. This optimized protocol for spatial peptide detection using MALDI MSI facilitates future biomarker discovery in prostate cancer and may be useful in studies of other tissue types.     

A High‐Rate Aqueous Proton Battery Delivering Power Below −78 °C via an Unfrozen Phosphoric Acid

The sluggish ion diffusion and electrolyte freezing with volumetric changes limit the low‐temperature performance of rechargeable batteries. Herein, a high‐rate aqueous proton battery (APB) operated at and below ?78 °C via a 62 wt% (9.5 m) H₃PO₄ electrolyte is reported. The APB is a rocking‐chair battery that operates with protons commuting between a Prussian blue cathode and an MoO₃ anode. At ?78 °C, the APB full cells exhibit stable cycle life for 450 cycles, high round‐trip efficiency of 85%, and appreciable power performance. The APB delivers 30% of its room‐temperature capacity even at ?88 °C. The proton storage mechanism is investigated by ex situ synchrotron XRD, XAS, and XPS. The APB pouch cells demonstrate no capacity fading at ?78 °C, and thus offers a safe and reliable candidate for high‐latitude applications.     

High‐solids biphasic CO2–H2O pretreatment of lignocellulosic biomass

A high pressure (200 bar) CO₂–H₂O process was developed for pretreating lignocellulosic biomass at high‐solid contents, while minimizing chemical inputs. Hardwood was pretreated at 20 and 40 (wt.%) solids. Switchgrass, corn stover, big bluestem, and mixed perennial grasses (a co‐culture of big bluestem and switchgrass) were pretreated at 40 (wt.%) solids. Operating temperatures ranged from 150 to 250°C, and residence times from 20 s to 60 min. At these conditions a biphasic mixture of an H₂O‐rich liquid (hydrothermal) phase and a CO₂‐rich supercritical phase coexist. Following pretreatment, samples were then enzymatically hydrolyzed. Total yields, defined as the fraction of the theoretical maximum, were determined for glucose, hemicellulose sugars, and two degradation products: furfural and 5‐hydroxymethylfurfural. Response surfaces of yield as a function of temperature and residence time were compared for different moisture contents and biomass species. Pretreatment at 170°C for 60 min gave glucose yields of 77%, 73%, and 68% for 20 and 40 (wt.%) solids mixed hardwood and mixed perennial grasses, respectively. Pretreatment at 160°C for 60 min gave glucan to glucose yields of 81% for switchgrass and 85% for corn stover. Biotechnol. Bioeng. 2010;107: 451–460. © 2010 Wiley Periodicals, Inc.     

On the hydration of DNA. I. Preferential hydration and stability of DNA in concentrated trifluoroacetate solution

The hydration of DNA is an important factor in the stability of its secondary structure. Methods for measuring the hydration of DNA in solution and the results of various techniques are compared and discussed critically. The buoyant density of native and denatured T-7 bacteriophage DNA in potassium trifluoroacetate (KTFA) solution has been measured as a function of temperature between 5 and 50°C. The buoyant density of native DNA increased linearly with temperature, with a dependence of (2.3 ± 0.5) × 10^?4 g/cc-°C. DNA which has been heat denatured and quenched at 0°C in the salt solution shows a similar dependence of buoyant density on temperature at temperatures far below the T_m, and above the T_m. However, there is an inflection region in the buoyant density versus T curve over a wide range of temperatures below the T_m. Optical density versus temperature studies showed that this is due to the. inhibition by KTFA of recovery of secondary structure on quenching. If the partial specific volume is assumed to be the same for native and denatured DNA, the loss of water of hydration on denaturation is calculated to be about 20% in KTFA at a water activity of 0.7 at 25°C. By treating the denaturation of DNA as a phase transition, an equation has immmi derived relating the destabilizing effect of trifluoroacetate to the loss of hydration on denaturation. The hydration of native DNA is abnormally high in the presence of this anion, and the loss of hydration on denaturation is greater than in CsCl. In addition, trifluoroacetate appears to decrease the ΔHof denaturation.     

A cell leakproof PLGA‐collagen hybrid scaffold for cartilage tissue engineering

A cell leakproof porous poly(DL ‐lactic‐co‐glycolic acid) (PLGA)‐collagen hybrid scaffold was prepared by wrapping the surfaces of a collagen sponge except the top surface for cell seeding with a bi‐layered PLGA mesh. The PLGA‐collagen hybrid scaffold had a structure consisting of a central collagen sponge formed inside a bi‐layered PLGA mesh cup. The hybrid scaffold showed high mechanical strength. The cell seeding efficiency was 90.0% when human mesenchymal stem cells (MSCs) were seeded in the hybrid scaffold. The central collagen sponge provided enough space for cell loading and supported cell adhesion, while the bi‐layered PLGA mesh cup protected against cell leakage and provided high mechanical strength for the collagen sponge to maintain its shape during cell culture. The MSCs in the hybrid scaffolds showed round cell morphology after 4 weeks culture in chondrogenic induction medium. Immunostaining demonstrated that type II collagen and cartilaginous proteoglycan were detected in the extracellular matrices. Gene expression analyses by real‐time PCR showed that the genes encoding type II collagen, aggrecan, and SOX9 were upregulated. These results indicated that the MSCs differentiated and formed cartilage‐like tissue when being cultured in the cell leakproof PLGA‐collagen hybrid scaffold. The cell leakproof PLGA‐collagen hybrid scaffolds should be useful for applications in cartilage tissue engineering. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2010     

Biochemical studies on native and cross-linked aggregates of Aspergillus awamori feruloyl esterase

Thermal stabilities of a native freeze dried Aspergillus awamori feruloyl esterase (FAE-II) enzyme and a cross-linked feruloyl esterase aggregate (CLEAs) at 25–85 °C were evaluated and discussed. Effects of some metal ions and some chemicals on the activity of both native freeze dried FAE-II enzyme and CLEAs were examined and explained. Differential scanning calorimetry, thermogravimetry, and derived thermogravimetry, were used to observe and explain the thermal denaturation processes. Structural analyses were made for native FAE-II and CLEAs using FT-IR and SEM techniques to investigate whether the cross-linking had any effect on the powder structure of native FAE-II enzyme.     

Metabolism of Klebsiella pneumoniae freeze‐dried cultures for the design of BOD bioassays

Aims: The survival rate of freeze‐dried cultures is not enough information for technological applications of micro‐organisms. There could be serious metabolic/structural damage in the survivors, leading to a delay time that can jeopardize the design of a rapid biochemical oxygen demand (BOD) metabolic‐based bioassay. Therefore, we will study the metabolic activity (as ferricyanide reduction activity) and the survival rate (as colony‐forming units, CFU) of different Klebsiella pneumoniae freeze‐dried cultures looking for stable metabolic conditions after 35 days of storage. Method and Results: Here, we tried several simple freeze‐drying processes of Kl. pneumoniae. Electrochemical measurements of ferrocyanide and survival rates obtained with the different freeze‐dried cultures were used to choose the best freeze‐drying process that leads to a rapid metabolic‐based bioassay. Conclusions: The use of milk plus monosodium glutamate was the best choice to obtain a Kl. pneumoniae freeze‐dried culture with metabolic stable conditions after storage at ?20°C without the need of vacuum storage and ready to use after 20 min of rehydration. We also demonstrate that the viability and the metabolic activity are not always directly correlated. Significance and Impact of the Study: This study shows that the use of this Kl. pneumoniae freeze‐dried culture is appropriate for the design of a rapid BOD bioassay.     

The dynamic mechanical, dielectric, and melting behavior of reconstituted collagen

The dielectric, dynamic mechanical, and melting (denaturation) behavior of reconstituted collagen has been investigated. Dynamic mechanical properties are reported for the range of temperature from ?100 to 220°C. Dielectric properties are reported for the range of temperature from ?120 to 90°C. Possible origins of dynamic mechanical and dielectric relaxations are discussed. Effect of moisture content on mechanical and dielectric behavior is also presented. The melting process of collagen immersed in diluents as well as that of dry collagen were studied by the techniques of hot-stage polarizing microscopy, differential thermal analysis, thermal mechanical analysis, and small-angle light scattering. It was concluded that the melting point of dry collagen is about 217°C.     

Dependence of co-operativity in the reaction of haemoglobin with oxygen on deuterium oxide concentration and temperature

Concentrated deionized solutions of haemoglobin in water were diluted with unbuffered pure ²H₂O and left to stand for 15 to 70 hours. Oxygen equilibrium curves were measured at different temperatures and concentrations of ²H₂O. In 98.5% ²H₂O Hill's constant retained its normal value at temperatures below 11 °C, but was reduced by 0.4 above 11 °C. This temperature effect was reversible. Lowering the ²H₂O concentrations raised the transition temperature between the states of low and high co-operativity of the reaction. The shape of the transition curve remained unchanged. Further experiments allowed a phase diagram to be constructed which shows the boundaries between the two states: one of low co-operativity at high concentration of ²H₂O and high temperature, and another of high co-operativity at low values of these variables. Reversibility of the isotope effect even at ²H₂O concentration of 98.5% excludes a purely steric interpretation. Possible dynamic and co-operative interactions between the protein molecule and its surrounding water molecules are discussed.