Straumann® SLActive®

Más allá de la capacidad hidrofílica: la ciencia del alto rendimiento

Nanoestructuras diferenciadas presentes en la superficie SLActive®27,28

Nanoestructuras diferenciadas descubiertas en la superficie SLActive® demuestran que la topografía de la superficie SLActive® es diferente de la de SLA®.

Roxolid® SLA®

Roxolid® SLActive®

Las nanoestructuras de SLActive® aumentan el área superficial en más de un 50 %25

Incremento del área superficial del implante: +50 % más que Roxolid® SLA®.

¿Cómo maximizar la superficie del implante?

  • Una mayor área superficial en contacto con el hueso aumenta el BIC*32
  • La microrrugosidad de SLA®/SLActive® aumenta el área superficial al menos en un 100 % en comparación con la superficie mecanizada26
  • Además, las nanoestructuras aumentan el área superficial de SLActive® en más del 50 %25

*BIC = contacto hueso-implante

La investigación in vitro avanzada demuestra que las nanoestructuras favorecen una osteointegración precoz23,24

Mejora de la formación de la red de fibrina en SLActive® con nanoestructuras.23,24 Toma de imágenes SEM de la formación de la red de fibrina sobre Roxolid® SLActive® (incubación de 15 min con sangre humana completa).*

Superficie Roxolid® SLActive® sin nanoestructuras**

Superficie Roxolid® SLActive® con nanoestructuras

Las últimas investigaciones in vitro sugieren que la hidrofilia sola no explica completamente el proceso de osteointegración acelerado asociado con las propiedades de la superficie SLActive®. Nuevos datos indican que las nanoestructuras de la superficie SLActive® contribuyen a la formación de la red de fibrina y a la mineralización, lo cual facilita las primeras fases de la osteointegración. Efectivamente, SLActive® con nanoestructuras presenta un nivel más elevado de formación de la red de fibrina y mineralización de las células óseas en comparación con SLActive® sin nanoestructuras (in vitro).23,24

* Empa, Laboratorios Federales Suizos de Ciencia y Tecnología de los Materiales. www.empa.ch
** Superficie experimental para estudiar el efecto de las nanoestructuras

Mayor mineralización de las células óseas en SLActive® con nanoestructura23,24

Mineralización de células óseas humanas medida después de 28 días colocadas sobre superficies incubadas con sangre. Resumen de las concentraciones de Ca2+ al final del cultivo en función de la superficie.*

* Empa, Laboratorios Federales Suizos de Ciencia y Tecnología de los Materiales. www.empa.ch
** Superficie experimental para estudiar el efecto de las nanoestructuras

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Acuerdo sobre el uso de los datos*
Vuelve a escribir el código anterior

Referencias

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