Towards a GDPR-compliant cloud architecture with data privacy controlled through sticky policies.

Data privacy is one of the biggest challenges facing system architects at the system design stage. Especially when certain laws, such as the General Data Protection Regulation (GDPR), have to be complied with by cloud environments. In this article, we want to help cloud providers comply with the GDPR by proposing a GDPR-compliant cloud architecture. To do this, we use model-driven engineering techniques to design cloud architecture and analyze cloud interactions. In particular, we develop a complete framework, called MDCT, which includes a Unified Modeling Language profile that allows us to define specific cloud scenarios and profile validation to ensure that certain required properties are met. The validation process is implemented through the Object Constraint Language (OCL) rules, which allow us to describe the constraints in these models. To comply with many GDPR articles, the proposed cloud architecture considers data privacy and data tracking, enabling safe and secure data management and tracking in the context of the cloud. For this purpose, sticky policies associated with the data are incorporated to define permission for third parties to access the data and track instances of data access. As a result, a cloud architecture designed with MDCT contains a set of OCL rules to validate it as a GDPR-compliant cloud architecture. Our tool models key GDPR points such as user consent/withdrawal, the purpose of access, and data transparency and auditing, and considers data privacy and data tracking with the help of sticky policies.

Landmarks for the hypoglossal nerve within the anterior cervical triangle / Topografía del nervio hipogloso en el triángulo cervical anterior

SUMMARY: Cranial nerve injury is one of the neurologic complications following carotid endarterectomy. The hypoglossal nerve is one of the most frequently injured nerves during carotid endarterectomy. Guidelines suggest that proper anatomic knowledge is crucial to avoid cranial nerve injury. The aim of the present study is to provide landmarks for the localization of the hypoglossal nerve during carotid endarterectomy. 33 anterior cervical triangles of formalin-fixed adult cadavers were dissected. The "carotid axis" was defined and measured, the level of the carotid bifurcation within the carotid axis was registered. "High carotid bifurcation" was considered for those carotid bifurcation found in the upper 25 mm of the carotid axis. The distance between the hypoglossal nerve and the carotid bifurcation was measured (length 1). The relationship between the hypoglossal nerve and the posterior belly of the digastric muscle was registered. For caudal positions, the distance between hypoglossal nerve and posterior belly of the digastric muscle was determined (length 2). Carotid axis range 88.3 mm-155.4 mm, average 125.8 mm. Level of the carotid bifurcation within the carotid axis range 75.3 mm-126.5 mm, mean 102.5 mm. High carotid bifurcation was found in 19 cases (57 %). Length 1 ranged from 1.6 mm to 38.1, mean 17.5. Finally, in 29 specimens (87.8 %) the hypoglossal nerve was caudal to posterior belly of the digastric muscle, whereas in 4 cases (12.2 %) it was posterior. Length 2 ranged from 1 mm to 17.0 mm, mean 6.9 mm. Distances between the hypoglossal nerve and nearby structures were determined. These findings may aid the surgeon in identifying the hypoglossal nerve during carotid endarterectomy and thus prevent its injury.

RESUMEN: La lesión de pares craneales es una de las complicaciones neurológicas posteriores a la endarterectomía carotídea. El nervio hipogloso es uno de los nervios lesionados más frecuentemente durante la endarterectomía carotídea. Las guías de actuación clínica sugieren que el conocimiento anatómico adecuado es crucial para evitar lesiones de los nervios craneales. El objetivo del presente estudio fue proporcionar puntos de referencia para la ubicación del nervio hipogloso durante la endarterectomía carotídea. Se disecaron 33 triángulos cervicales anteriores de cadáveres adultos fijados en solución a base de formaldehído. Se definió y midió el "eje carotídeo", se registró el nivel de la bifurcación carotídea dentro del eje carotídeo. Se consideró una "bifurcación carotídea alta" para aquellas bifurcaciones carotídeas encontradas en los 25 mm superiores del eje carotídeo. Se midió la distancia entre el nervio hipogloso y la bifurcación carotídea (longitud 1). Se registró la relación entre el nervio hipogloso y el vientre posterior del músculo digástrico. Para las posiciones caudales, se determinó la distancia entre el nervio hipogloso y el vientre posterior del músculo digástrico (longitud 2). Rango del eje carotídeo 88,3 mm-155,4 mm, media 125,8 mm. Rango del nivel de la bifurcación carotídea dentro del eje carotídeo 75,3 mm-126,5 mm, media 102,5 mm. Se encontró una bifurcación carotídea alta en 19 casos (57 %). La longitud 1 osciló entre 1,6 mm y 38,1, con una media de 17,5. Finalmente, en 29 muestras (87,8 %) el nervio hipogloso fue caudal al vientre posterior del músculo digástrico, mientras que en 4 casos (12,2 %) fue posterior. La longitud 2 osciló entre 1 mm y 17,0 mm, con una media de 6,9 mm. Se determinaron las distancias entre el nervio hipogloso y las estructuras cercanas. Estos hallazgos pueden ayudar al cirujano a identificar el nervio hipogloso durante la endarterectomía carotídea y así prevenir su lesión.