DEVELOPMENT OF A BURGER FORMULATION WITH PIZZA AROMA IN A PACKAGING SYSTEM TYPE IN COOK

The market of meat processed products, including hamburgers, grows up every year and consumers demand quality and convenience.  The objective of this study was to prepare a hamburger with chicken meat, making use of the chicken meat cuts that are considered more noble such as chicken breast and thigh, source of unsaturated fatty acids, in packaging cook in. The formulation was defined based on market survey and testing in a pilot plant through various modifications of the formulation, seeking the care of sensory patterns, a chicken burger formula with 50.0 % breast and 23.0 % thigh, added aroma identical to pizza, provolone cheese and ground dried tomato was used in the tests and its physicochemical, microbiological and sensorial analysis. Physicochemical, microbiological and sensorial analysis was carried out of this burgues. The samples were tested by 53 tasters without training, through affective hedonic scale of 5 points. The physicochemical analyses indicated the following contents: moisture 62.42 %, proteins 16.00 %, lipids 15.25 %, fiber 1.83 % and sodium chloride 1.90 %, all of which meet the requirements of Brazilian legislation. The sensorial analysis indicated excellent acceptance of the product, with an average score of 4.44, classifying it as “like it moderately” and “like it very much.” Thus, the product developed has great potential for dissemination in the consumer market as well as being innovative by using a packaging type bakes easy that allows for adding value and differentiation for consumers seeking sensuousness and practicality in your meals

Optical study of the band structure of wurtzite GaP nanowires

We investigated the optical properties of wurtzite (WZ) GaP nanowires by performing photoluminescence (PL) and time-resolved PL measurements in the temperature range from 4 K to 300 K, together with atom probe tomography to identify residual impurities in the nanowires. At low temperature, the WZ GaP luminescence shows donor-acceptor pair emission at 2.115 eV and 2.088 eV, and Burstein-Moss band-filling continuum between 2.180 and 2.253 eV, resulting in a direct band gap above 2.170 eV. Sharp exciton α-β-γ lines are observed at 2.140-2.164-2.252 eV, respectively, showing clear differences in lifetime, presence of phonon replicas, and temperature- dependence. The excitonic nature of those peaks is critically discussed, leading to a direct band gap o

Probing Lattice Dynamics and Electronic Resonances in Hexagonal Ge and SixGe1-x Alloys in Nanowires by Raman Spectroscopy

Recent advances in nanowire synthesis have enabled the realization of crystal phases that in bulk are attainable only under extreme conditions, i . e ., high temperature and/or high pressure. For group IV semiconductors this means access to hexagonal-phase Si x Ge 1- x nanostructures (with a 2H type of symmetry), which are predicted to have a direct band gap for x up to 0.5-0.6 and would allow the realization of easily processable optoelectronic devices. Exploiting the quasi-perfect lattice matching between GaAs and Ge, we synthesized hexagonal-phase GaAs-Ge and GaAs-Si x Ge 1- x core-shell nanowires with x up to 0.59. By combining position-, polarization-, and excitation wavelength-dependent μ-Raman spectroscopy studies with first-principles calculations, we explore the full lattice dynamics of these materials. In particular, by obtaining frequency-composition calibration curves for the phonon modes, investigating the dependence of the phononic modes on the position along the nanowire, and exploiting resonant Raman conditions to unveil the coupling between lattice vibrations and electronic transitions, we lay the grounds for a deep understanding of the phononic properties of 2H-Si x Ge 1- x nanostructured alloys and of their relationship with crystal quality, chemical composition, and electronic band structure

In-plane thermal diffusivity determination using beam-offset frequency-domain thermoreflectance with a one-dimensional optical heat source

We present an innovative contactless method suitable to study in-plane thermal transport based on beam-offset frequency-domain thermoreflectance using a one-dimensional heat source with uniform power distribution. Using a one-dimensional heat source provides a number of advantages as compared to point-like heat sources, as typically used in time- and frequency-domain thermoreflectance experi- ments, just to name a few: (i) it leads to a slower spatial decay of the temperature field in the direction perpendicular to the line-shaped heat source, allowing to probe the temperature field at larger distances from the heater, hence, enhancing the sensitivity to in-plane thermal transport; (ii) the frequency range of interest is typically < 100 kHz. This rather low frequency range is convenient regarding the cost of the required excitation laser system but, most importantly, it allows the study of materials without the presence of a metallic transducer with almost no influence of the finite optical penetration depth of the pump and probe beams on the thermal phase lag, which arises from the large thermal penetration depth imposed by the used frequency range. We also show that for the case of a harmonic thermal excitation source, the phase lag between the thermal excitation and thermal response of the sample exhibits a lin- ear dependence with their spatial offset, where the slope is proportional to the inverse of the thermal diffusivity of the material. We demonstrate the applicability of this method to the cases of: (i) suspended thin films of Si and PDPP4T, (ii) Bi bulk samples, and (iii) Si, glass, and highly-oriented pyrollitic graphite (HOPG) bulk samples with a thin metallic transducer. Finally, we also show that it is possible to study in-plane heat transport on substrates with rather low thermal diffusivity, e.g., glass, even using a metallic transducer. We achieve this by an original approach based on patterning the transducer using focused ion beam, with the key purpose of limiting in-plane heat transport through the thin metallic transducer

Peripheral neuropathy after viral eradication with direct-acting antivirals in chronic HCV hepatitis: A prospective study

BACKGROUND: HCV‐related extra‐hepatic complications include peripheral neuropathies, with important prevalence and impact. A recent metanalysis of previous intervention trials concluded for insufficient data to support evidence‐based treatments for this complication. In this longitudinal study, we assessed for the first time prevalence and outcome of neuropathy in a cohort of patients with chronic HCV, before and after direct‐acting antiviral agent (DAA) treatment. METHOD: Ninety‐four patients (mean age 58.5 ± 9.9, infection duration 22.2 ± 6.3 years) without systemic and metabolic diseases, underwent neurological examination and electroneurography studies before (T0) and 10.4 ± 1.7 months after the end of DAA therapy (T1), and cryoglobulins (CG) assessment. Muscle strength was evaluated by Medical Research Council (MRC) score; neuropathic pain, sensory function, disability, quality of life were assessed by validated questionnaires (DN4, NPSI, SSS, INCAT and Euro‐QoL). RESULTS: At T0, sensory‐motor neuropathy was detected in 22 patients (23%), reflexes were depressed in 32 (34%) with no association with infection duration, viral load, age, CG. Neuropathic pain (DN4 ≥4) was present in 37 patients (39%). At T1, out of the 22 patients with altered electroneurography, 3 had died or developed HCC, 4 showed normal electroneurography, and nerve amplitude parameters tended to improve in the whole group. Only 11 patients (12%) had depressed reflexes and 10 (11%) DN4 ≥4 (P < .05 compared to T0). Scores for MRC, questionnaires and Euro‐QoL improved significantly (P < .05). CONCLUSION: Our study confirms the high prevalence of clinical and subclinical peripheral sensory‐motor neuropathy in patients with HCV infection and indicates improvement after eradication by DAA. These results support the need for larger intervention studies

ESTUDO DA COMPOSIÇÃO QUÍMICA E DO PODER DE DISSOLUÇÃO DOS ÓLEOS ESSENCIAIS DE ANIS-ESTRELADO (Illicium verum) E CRAVO DA ÍNDIA (Syzygium aromaticum) PARA RECICLAGEM DO ISOPOR

Este trabalho teve como objetivo caracterizar e avaliar o potencial de dissolução óleos essenciais de Anis-estrelado (Illicium verum) e Cravo da Índia (Syzygium aromaticum) para servir na reciclagem do isopor. A extração dos óleos essenciais foi realizada através da hidrodestilação. Foram identificados, o Anetol (55%) e o Eugenol (90,7%), como componentes químicos majoritários dos óleos estudados. Dentre os óleos essenciais estudados, óleo de Cravo da Índia apresentou melhor eficiência no processo de reciclagem do isopor. Por fim, os resultados apontam que os óleos essenciais estudados, podem ser empregados como solventes alternativos para reciclagem do isopor, gerando maiores possibilidades de aplicação e permitindo sua utilização de forma sustentável

Effect of the GaAsP shell on optical properties of self-catalyzed GaAs nanowires grown on silicon

We realize growth of self-catalyzed core-shell GaAs/GaAsP nanowires (NWs) on Si substrates using molecular-beam epitaxy. Transmission electron microscopy (TEM) of single GaAs/GaAsP NWs confirms their high crystal quality and shows domination of the zinc-blende phase. This is further confirmed in optics of single NWs, studied using cw and time-resolved photoluminescence (PL). A detailed comparison with uncapped GaAs NWs emphasizes the effect of the GaAsP capping in suppressing the non-radiative surface states: significant PL enhancement in the core-shell structures exceeding 2000 times at 10K is observed; in uncapped NWs PL is quenched at 60K whereas single core-shell GaAs/GaAsP NWs exhibit bright emission even at room temperature. From analysis of the PL temperature dependence in both types of NW we are able to determine the main carrier escape mechanisms leading to the PL quench

Local modification of GaAs nanowires induced by laser heating

GaAs nanowires were heated locally under ambient air conditions by a focused laser beam which led to oxidation and formation of crystalline arsenic on the nanowire surface. Atomic force microscopy, photoluminescence and Raman spectroscopy experiments were performed on the same single GaAs nanowires in order to correlate their structural and optical properties. We show that the local changes of the nanowires act as a barrier for thermal transport which is of interest for thermoelectric applications