Immunohistochemical molecular phenotypes of gastric cancer based on SOX2 and CDX2 predict patient outcome

Background Gastric cancer remains a serious health concern worldwide. Patients would greatly benefit from the discovery of new biomarkers that predict outcome more accurately and allow better treatment and follow-up decisions. Here, we used a retrospective, observational study to assess the expression and prognostic value of the transcription factors SOX2 and CDX2 in gastric cancer. Methods SOX2, CDX2, MUC5AC and MUC2 expression were assessed in 201 gastric tumors by immunohistochemistry. SOX2 and CDX2 expression were crossed with clinicopathological and follow-up data to determine their impact on tumor behavior and outcome. Moreover, SOX2 locus copy number status was assessed by FISH (N = 21) and Copy Number Variation Assay (N = 62). Results SOX2 was expressed in 52% of the gastric tumors and was significantly associated with male gender, T stage and N stage. Moreover, SOX2 expression predicted poorer patient survival, and the combination with CDX2 defined two molecular phenotypes, SOX2+CDX2- versus SOX2-CDX2+, that predict the worst and the best long-term patients’ outcome. These profiles combined with clinicopathological parameters stratify the prognosis of patients with intestinal and expanding tumors and in those without signs of venous invasion. Finally, SOX2 locus copy number gains were found in 93% of the samples reaching the amplification threshold in 14% and significantly associating with protein expression. Conclusions We showed, for the first time, that SOX2 combined with CDX2 expression profile in gastric cancer segregate patients into different prognostic groups, complementing the clinicopathological information. We further demonstrate a molecular mechanism for SOX2 expression in a subset of gastric cancer cases.

Influência da cirurgia abdominal na função pulmonar e capacidade de tosse

Introdução: A cirurgia abdominal acarreta grande risco de complicações pulmonares pós-operatórias. As alterações pós-cirúrgicas abdominais, reflectem-se na dinâmica ventilatória, de modo particular nos volumes e capacidades pulmonares, e na capacidade de tosse. Objectivos: Compreender qual a variação dos volumes e capacidades pulmonares e da capacidade de tosse antes e depois da cirurgia abdominal (estômago e cólon), e qual a correlação dessa variação com o nível de dor percepcionada. Desenho do estudo: Unicêntrico, prospectivo e observacional. Amostra: 10 indivíduos, propostos para cirurgia abdominal – estômago e cólon. Metodologia: Dois momentos de avaliação: um nas 24h préoperatórias em que se mediu a capacidade vital forçada (CVF) e o volume expirado máximo no primeiro segundo (VEMS1) com espirometria, e do pico de fluxo de tosse (PCF); e um segundo momento nas 24h pós-operatórias onde se repetiram as medições do primeiro momento com o acréscimo da avaliação da dor. Resultados: No pós-operatorio imediato há uma diminuição significativa da CVF de 44,30%±17,24 (p=0,005), do VEMS1 de 35,50%±28,47 (p=0,009) e do PCF de 38,97%±38,66 (p=0,012). Não se verificou nenhuma relação entre a dor percepcionada na realização das manobras de espirometria e tosse com diminuição a da CVF e do VEMS1 e do PCF respectivamente. O sexo apresentou uma relação significativa com a variação da CRF e do VEMS1 (p=0,046 e p=0,008 respectivamente). A frequência respiratória apresentou um aumento significativo no pós-operatório de 10±11,22 cpm (p=0,019). A saturação periférica de oxigénio apresentou uma diminuição significativa no pós-operatório de 3,52±2,47 (p=0,011) Conclusão: No estudo efectuado fica demonstrado o impacto negativo da cirurgia abdominal na dinâmica respiratória. A diminuição dos valores da CVF, do VEMS1 e do PCF podem contribuir de forma significativa para o aumento do risco de complicações respiratória pós-operatórias. No entanto seria importante a realização deste estudo com uma amostra maior.

Electrospun Polyaniline-Reduced Graphene Oxide Composite Nanofibers Based High Sensitive Ammonia Gas Sensor

Ammonia is an important gas in many power plants and industrial processes so its detection is of extreme importance in environmental monitoring and process control due to its high toxicity. Ammonia’s threshold limit is 25 ppm and the exposure time limit is 8 h, however exposure to 35 ppm is only secure for 10 min. In this work a brief introduction to ammonia aspects are presented, like its physical and chemical properties, the dangers in its manipulation, its ways of production and its sources. The application areas in which ammonia gas detection is important and needed are also referred: environmental gas analysis (e.g. intense farming), automotive-, chemical- and medical industries. In order to monitor ammonia gas in these different areas there are some requirements that must be attended. These requirements determine the choice of sensor and, therefore, several types of sensors with different characteristics were developed, like metal oxides, surface acoustic wave-, catalytic-, and optical sensors, indirect gas analyzers, and conducting polymers. All the sensors types are described, but more attention will be given to polyaniline (PANI), particularly to its characteristics, syntheses, chemical doping processes, deposition methods, transduction modes, and its adhesion to inorganic materials. Besides this, short descriptions of PANI nanostructures, the use of electrospinning in the formation of nanofibers/microfibers, and graphene and its characteristics are included. The created sensor is an instrument that tries to achieve a goal of the medical community in the control of the breath’s ammonia levels being an easy and non-invasive method for diagnostic of kidney malfunction and/or gastric ulcers. For that the device should be capable to detect different levels of ammonia gas concentrations. So, in the present work an ammonia gas sensor was developed using a conductive polymer composite which was immobilized on a carbon transducer surface. The experiments were targeted to ammonia measurements at ppb level. Ammonia gas measurements were carried out in the concentration range from 1 ppb to 500 ppb. A commercial substrate was used; screen-printed carbon electrodes. After adequate surface pre-treatment of the substrate, its electrodes were covered by a nanofibrous polymeric composite. The conducting polyaniline doped with sulfuric acid (H2SO4) was blended with reduced graphene oxide (RGO) obtained by wet chemical synthesis. This composite formed the basis for the formation of nanofibers by electrospinning. Nanofibers will increase the sensitivity of the sensing material. The electrospun PANI-RGO fibers were placed on the substrate and then dried at ambient temperature. Amperometric measurements were performed at different ammonia gas concentrations (1 to 500 ppb). The I-V characteristics were registered and some interfering gases were studied (NO2, ethanol, and acetone). The gas samples were prepared in a custom setup and were diluted with dry nitrogen gas. Electrospun nanofibers of PANI-RGO composite demonstrated an enhancement in NH3 gas detection when comparing with only electrospun PANI nanofibers. Was visible higher range of resistance at concentrations from 1 to 500 ppb. It was also observed that the sensor had stable, reproducible and recoverable properties. Moreover, it had better response and recovery times. The new sensing material of the developed sensor demonstrated to be a good candidate for ammonia gas determination.