How do medical specialists value their own intercultural communication behaviour? A reflective practice study.

BACKGROUND: Intercultural communication behaviour of doctors with patients requires specific intercultural communication skills, which do not seem structurally implemented in medical education. It is unclear what motivates doctors to apply intercultural communication skills. We investigated how purposefully medical specialists think they practise intercultural communication and how they reflect on their own communication behaviour. METHODS: Using reflective practice, 17 medical specialists independently watched two fragments of videotapes of their own outpatient consultations: one with a native patient and one with a non-native patient. They were asked to reflect on their own communication and on challenges they experience in intercultural communication. The interviews were open coded and analysed using thematic network analysis. RESULTS: The participants experienced only little differences in their communication with native and non-native patients. They mainly mentioned generic communication skills, such as listening and checking if the patient understood. Many participants experienced their communication with non-native patients positively. The participants mentioned critical incidences of intercultural communication: language barriers, cultural differences, the presence of an interpreter, the role of the family and the atmosphere. CONCLUSION: Despite extensive experience in intercultural communication, the participants of this study noticed hardly any differences between their own communication behaviour with native and non-native patients. This could mean that they are unaware that consultations with non-native patients might cause them to communicate differently than with native patients. The reason for this could be that medical specialists lack the skills to reflect on the process of the communication. The participants focused on their generic communication skills rather than on specific intercultural communication skills, which could either indicate their lack of awareness, or demonstrate that practicing generic communication is more important than applying specific intercultural communication. They mentioned well-known critical incidences of ICC: language barriers, cultural differences, the presence of an interpreter, the role of the family and the atmosphere. Nevertheless, they showed a remarkably enthusiastic attitude overall was noteworthy. A strategy to make doctors more aware of their intercultural communication behaviour could be a combination of experiential learning and ICC training, for example a module with reflective practice.

Brillouin spectroscopy: a new tool to decipher viscoelastic properties of biological scaffold functionalized with nanoscale films.

BACKGROUND: In tissue engineering, the endothelialization of vascular scaffold can be a crucial step to improve graft patency. A functional cellularization requires coating surfaces. Since 2003, our group used polyelectrolyte multilayer films (PEMFs) made of poly(allylamine hydrochloride) and polystyren sulfonate to coat luminal surface of blood vessel. Previous results showed that PEMFs have remarkable effect on cellular behavior: adhesion, proliferation, differentiation. However, no method seems adapted for in vitro measurement of the viscoelastic shift after PEMFs buildup. OBJECTIVE: In this present work, we proposed to use a new analytical method based on Brillouin spectroscopy (BS) to investigate the influence PEMFs coating on vessel intrinsic viscoelasticy. METHODS: On human umbilical arteries and rabbit vessels, PEMFs were buildup and the luminal surfaces viscoelasticy were measuring by BS. RESULTS: It seems that these films do not alter dynamic functionality and BS could be an interesting method for understanding the role of the tissue architecture, the interrelation between the different structures constituting the wall and the influence of this architecture on the tissue behavior, especially with the characterized components of the different vascular wall. CONCLUSION: The ability of BS to characterize biological samples opens potential applications in tissue engineering field, especially as a tool for a better understanding of vascular diseases.

Polyelectrolyte multilayer films promote human cord blood stem cells differentiation into mature endothelial cells exhibiting a stable phenotype.

BACKGROUND: recent studies in bio-engineering have showed the influence of Polyelectrolyte Multilayer (PEM) films on endothelial cells (ECs), especially poly(sodium-4-styrene-sulfonate) (PSS) and poly(allylamine hydrochloride) (PAH). They were tested either with human mature ECs or rabbit immature endothelial progenitor cells (EPCs), but never on human EPCs. In view to obtain an EC covered surface, human cord blood (HCB) EPCs were cultivated on PSS/PAH films. MATERIAL AND METHODS: PEMs were obtained by 7 alternate depositions of cationic PAH and anionic PSS layers. HCB mononuclear cells were isolated by centrifugation through density gradient. 7 days after seeding on PEM, unattached cells were removed and adherent EPCs were cultivated in endothelial specific medium until P6. Appearance of CD31 and vWF was evaluated by confocal microscopy. RESULTS: EPCs not only successfully adhered on PEM, but also spread and proliferated. Moreover, cells differentiated into a typical endothelial cobblestone monolayer within 2 weeks. Immunostaining of CD31 and vWF confirmed the formation of an EC-like confluent monolayer. Furthermore, these cells showed after 6 passages a good phenotypic stability while reseeded on the PEM film. CONCLUSION: these results show an easy way to obtain mature ECs from human stem cells, which may open new applications for a scaffold cellularization in tissue bio-engineering.

Review: behaviour of endothelial cells faced with hypoxia.

Hypoxia is a diminution of oxygen quantity delivered to tissue for cellular need to product energy. Hypoxia derives from two major conditions in health diseases: anemia and ischemia. Anemic hypoxia comes from damage to O(2) transport like red blood cells diminution or disease. Ischemic hypoxia is a diminution of blood flow following a diminution of blood volume after a hemorrhagic shock. After hypoxia, vessels dilate to increase blood flow allowing a better oxygenation of peripheral tissues. This vasodilation appears immediately after the beginning of hypoxia and can be maintained during several hours. Today, the molecular mechanisms of this vasodilation stay unclear. But it seems that potassic channels, ATP concentration and medium acidification in addition to vasodilator/vasoconstrictor balance play a great role to facilitate the oxygenation of the ischemic areas.As endothelial cells (EC) are lining the vasculature, they are always in contact with blood, which carries, amongst other compounds, oxygen. In this way, they are the first target for an oxygen partial pressure (PO(2)) diminution. EC, through different mechanosensors, can sense a variation in PO(2) and adapt their metabolism to maintain ATP production. Under hypoxia, EC switch into hypoxic metabolism, leading to the production of reactive oxygen species (ROS). Indeed, when PO(2) is low, the respiratory chain in the mitochondria runs slower. Furthermore, cytochrome C capacity to trap O(2) is reduced; this phenomenon alters the cellular redox potential and leads to the accumulation of electrons that induce the formation of ROS.This review presents an overview of the behaviour of endothelial cells face to hypoxia. We propose to focus on nitric oxide, hypoxia inducible factor (HIF), lactate and ROS productions. Then we present the different mode of culture of EC under hypoxia. Finally, we conclude on the difficulty to study hypoxia because of the various types of system developed to reproduce this phenomenon and the different signalling ways that can be activated.