Subtle changes in the flavour and texture of a drink enhance expectations of satiety

Background: The consumption of liquid calories has been implicated in the development of obesity and weight gain. Energy-containing drinks are often reported to have a weak satiety value: one explanation for this is that because of their fluid texture they are not expected to have much nutritional value. It is important to consider what features of these drinks can be manipulated to enhance their expected satiety value. Two studies investigated the perception of subtle changes in a drink’s viscosity, and the extent to which thick texture and creamy flavour contribute to the generation of satiety expectations. Participants in the first study rated the sensory characteristics of 16 fruit yogurt drinks of increasing viscosity. In study two, a new set of participants evaluated eight versions of the fruit yogurt drink, which varied in thick texture, creamy flavour and energy content, for sensory and hedonic characteristics and satiety expectations. Results: In study one, participants were able to perceive small changes in drink viscosity that were strongly related to the actual viscosity of the drinks. In study two, the thick versions of the drink were expected to be more filling and have a greater expected satiety value, independent of the drink’s actual energy content. A creamy flavour enhanced the extent to which the drink was expected to be filling, but did not affect its expected satiety. Conclusions: These results indicate that subtle manipulations of texture and creamy flavour can increase expectations that a fruit yogurt drink will be filling and suppress hunger, irrespective of the drink’s energy content. A thicker texture enhanced expectations of satiety to a greater extent than a creamier flavour, and may be one way to improve the anticipated satiating value of energy-containing beverages

Fiber optic temperature sensor

A fiber optic temperature sensor uses a light source which transmits light through an optical fiber to a sensor head at the opposite end of the optical fiber from the light source. The sensor head has a housing coupled to the end of the optical fiber. A metallic reflective surface is coupled to the housing adjacent the end of the optical fiber to form a gap having a predetermined length between the reflective surface and the optical fiber. A detection system is also coupled to the optical fiber which determines the temperature at the sensor head from an interference pattern of light which is reflected from the reflective surface

Extracellular matrix-modulated expression of human cell surface glycoproteins A42 and J143. Intrinsic and extrinsic signals determine antigenic phenotype.

Extracellular matrix (ECM)' plays an important regulatory role in cellular growth, migration, and differentiation (1-4). Pathologic processes such as tumor cell invasion and metastasis are also determined by cellular interactions with ECM (5, 6). Biochemical studies have identified collagens, fibronectin, laminin, proteoglycans, and several other proteins as major ECM components (1-3), and have shown that ECM composition varies between different normal and tumor tissues. The complexity and heterogeneity of ECM composition have hampered the molecular analysis of ECM-cell interactions . However, a range of phenotypic changes has been described for cultured cells after transfer from plastic surfaces to substrates coated with native ECM (7, 8) or with purified ECM components; ECM-induced phenotypic changes include enhanced substrate adhesiveness, cell spreading and migration, changes in cell morphology and proliferative activity, and expression of differentiated cellular functions (I-4). Some of these effects, e.g., increased substrate adhesion, may result directly from the binding of specialized cell surface structures to ECM molecules. Others are likely mediated by an active cellular response triggered by the interaction of ECM with cell surface receptors. Thus, ECM-derived signals (9) may activate a cascade of molecular changes within the cell and on the cell surface that account for the pleiotropic effects observed with ECM

Fiber Optic Control System integration for advanced aircraft. Electro-optic and sensor fabrication, integration, and environmental testing for flight control systems

This report describes the design, development, and testing of passive fiber optic sensors and a multiplexing electro-optic architecture (EOA) for installation and flight test on a NASA-owned F-18 aircraft. This hardware was developed under the Fiber Optic Control Systems for Advanced Aircraft program, part of a multiyear NASA initiative to design, develop, and demonstrate through flight test 'fly-by-light' systems for application to advanced aircraft flight and propulsion control. This development included the design and production of 10 passive optical sensors and associated multiplexed EOA hardware based on wavelength division multiplexed (WDM) technology. A variety of sensor types (rotary position, linear position, temperature, and pressure) incorporating a broad range of sensor technologies (WDM analog, WDM digital, analog microbend, and fluorescent time rate of decay) were obtained from different manufacturers and functionally integrated with an independently designed EOA. The sensors were built for installation in a variety of aircraft locations, placing the sensors in a variety of harsh environments. The sensors and EOA were designed and built to have the resulting devices be as close as practical to a production system. The integrated system was delivered to NASA for flight testing on a NASA-owned F-18 aircraft. Development and integration testing of the system provided valuable information as to which sensor types were simplest to design and build for a military aircraft environment and which types were simplest to operate with a multiplexed EOA. Not all sensor types met the full range of performance and environmental requirements. EOA development problems provided information on directions to pursue in future fly-by-light flight control development programs. Lessons learned in the development of the EOA and sensor hardware are summarized

Ariel - Volume 4 Number 3

Editors David A. Jacoby Eugenia Miller Tom Williams Associate Editors Paul Bialas Terry Burt Michael Leo Gail Tenikat Editor Emeritus and Business Manager Richard J. Bonnano Movie Editor Robert Breckenridge Staff Richard Blutstein Mary F. Buechler Steve Glinks Len Grasman Alice M. Johnson J.D. Kanofsky Tom Lehman Dave Mayer Bernie Odd

Ferroelectricity in the xAg2Nb4O11–(1−x)Na2Nb4O11 solid solution

Compositions in the (AgxNa1-x)2Nb4O11 solid solution have been prepared by a conventional solid state method. Composites containing Ag2Nb4O11 have been shown to be ferroelectric and the Curie temperature shown to decrease from 149 °C at x = 1 to 62 °C at x = 0.7. Roomtemperature compositions with x ≤ 0.7 are monoclinic, while those with x ≥ 0.8 are rhombohedral with structures consistent with the relevant end-members. At x = 0.75, the structure was mainly rhombohedral but with coexistence of the monoclinic structure, indicating the proximity of a phase boundary

Evaluating the Bioavailability of Carbamazepine Using a Novel SNEDDS Formulation

Carbamazepine (CBZ) is an anticonvulsant drug primarily used to treat epilepsy, bipolar disorder, trigeminal and glossopharyngeal neuralgia. CBZ is a lipophilic, poorly soluble drug that belongs to the class-2 category according to the Biopharmaceutics Classification System. As a class-2 drug, the plasma concentration of CBZ is limited by its ability to diffuse across biological membranes. To increase its bioavailability, different methods such as crystal modifications, particle size reduction, amorphization, cyclodextrin complexation, pH modification, and self-emulsification were explored. Of these methods, Self Nano Emulsifying Drug Delivery Systems (SNEDDS) have shown to reduce particle size of CBZ molecules and improve its solubility. However, the bioavailability of CBZ administered as SNEDDS are not yet investigated. Given this background, the current study proposes to evaluate the bioavailability of these novel drug delivery systems using a rat model. The study is designed as a randomized controlled crossover experiment using 10-12 Sprague-Dawley rats divided equally into two groups. For this study, blood samples will be collected at 5, 10, 15, 20, 30, 45, 60, 90, and 120 minutes after administering two different formulations of CBZ nanoemulsions and stored at -20°C until ready for analysis. Plasma concentrations of CBZ will be determined by HPLC method. An unpaired t-test will be used to compare the significance between the two sets of data

Evaluating the Bioavailability of Carbamazepine Using a Novel SNEDDS Formulation

Central to the mechanism of how drugs work are the concepts of solubility and bioavailability. Drugs enter the body via absorption into the bloodstream, arrive at the target location, and bind to receptors to cause an effect. Drugs need to be soluble enough to pass through the cell membrane to enter and exit the bloodstream. Higher solubility generally correlates to higher bioavailability. Additionally, the smaller the particle size, the easier the drug will pass through the membrane into the blood plasma. Researchers have designed a system to categorize solubility class: Class I being high permeability and high solubility, Class II high permeability and low solubility, Class III low permeability and high solubility, and Class IV low permeability and low solubility. The study will use a Class II anticonvulsant, carbamazepine (CBZ). CBZ is a suitable candidate for this study because it requires a higher bioavailability due to its need to cross the blood brain barrier and act on the trigeminal nucleus. To increase bioavailability researchers have tried crystal modifications, particle size reduction, amorphization, cyclodextrin complexation, pH modification, and self-emulsification. These methods have been successful at increasing bioavailability, but this experiment will focus on reducing particle size into a new self-emulsifying formulation. In particular, the formulation of CBZ in this study is a self nano-emulsifying drug delivery system (SNEDDS), which shows more promise than previous methods to increase bioavailability. This study will create a SNEDDS formulation as a nasal nebulizer mist delivery and compare it to a FDA approved oral suspension using a crossover rat model design. Sixteen Sprague-Dawley rats will be ordered through Central State University and normalized to the study environment for a minimum of one week. Pending IACUC approval from Central State University, the tail vein method will be used to collect blood samples. The samples will be stored until needed for analysis using ELISA, enzyme-linked immunosorbent assay, which will be used to determine the concentration of CBZ in blood plasma

Corneal Imaging Techniques for Dry Eye Disease

Dry eye disease (DED) is a common ocular disorder affecting millions worldwide. It is characterized by reduced tear production and/or increased tear evaporation, leading to ocular discomfort and impaired vision. Corneal imaging techniques are valuable tools for diagnosing and monitoring DED, as they can provide objective and quantitative information on the structure and function of the ocular surface and the tear film. This chapter will review the principles and applications of various corneal imaging techniques for DED, such as Slit-Lamp Biomicroscopy, Fluorescein CorneoGraphy, In Vivo Confocal Microscopy, Optical Coherence Tomography, Lipid Layer Interferometry, Topography, and Fluorophotometry. The advantages and limitations of each technique are discussed, as well as their potential role in future research and clinical practice, such as monitoring treatment efficacy and guiding personalized treatment approaches