Macro-invertébrés du Cénomanien du Djebel Metrassi (Batna, NE Algérie): Systématique et biostratigraphie

A rich paleontological assemblage was collected in the Cenomanian deposits of the Djebel Metrassi (Batna, NE Algeria). It consists of 327 specimens assigned respectively to a single coral, 24 bivalve, 14 gastropod, 3 ammonite, and 7 echinoid species. This macrofaunal association leads us to establish an original taxonomical reference list along with several species new for the Cenomanian of this area, and supports the lithostratigraphic framework herein proposed.[fr] Un assemblage paléontologique a été récolté dans le Cénomanien du Djebel Metrassi (Batna, NE Algérie). Constitué de 327 spécimens, il comporte un corail, 24 espèces de bivalves, 14 espèces de gastéropodes, 3 espèces d’ammonites et 7 espèces d’échinides. Cet assemblage permet d’établir une liste systématique originale, avec des espèces inédites, pour le Cénomanien de ce Djebel et vient soutenir le découpage lithostratigraphique proposé

A review on biomedical titanium alloys: Recent progress and prospect

Compared with stainless steel and Co–Cr‐based alloys, Ti and its alloys are widely used as biomedical implants due to many fascinating properties, such as superior mechanical properties, strong corrosion resistance, and excellent biocompatibility. After briefly introducing several most commonly used biomedical materials, this article reviews the recent development in Ti alloys and their biomedical applications, especially the low‐modulus β‐type Ti alloys and their design methods. This review also systemically investigates the recently attractive progress in preparation of biomedical Ti alloys, including additive manufacturing, porous powder metallurgy, and severe plastic deformation, applied in the manufacturing and the influenced microstructures and properties. Nevertheless, there are still some problems with the long‐term performance of Ti alloys, and therefore several surface modification methods are reviewed to further improve their biological activity, wear resistance, and corrosion resistance. Finally, the biocompatibility of Ti and its alloys is concluded. Summarizing the findings from literature, future prediction is also conducted

Mechanical and Microstructural Characterization of Porous NiTi Shape Memory Alloys

This article presents the mechanical behavior of porous NiTi in the context of biomedical applications related to bone prostheses. To produce the porous metallic material, a novel technique consisting of mixing prealloyed NiTi powder with a polymer powder and a foaming agent has been used. This method permits control of the size of pores and the porosity level. For the present study, pores similar to those found in bones (400 to 500 \u3bcm) were obtained with a total porosity of the specimens varying from 50 to 70 pct. The compression mechanical testing carried out on small cylindrical specimens revealed shape memory deformation recovery up to 6.4 pct, while the superelastic behavior resulted in a reversible deformation up to 7.7 pct. By varying the amount of porosity, it was possible to obtain Young\u2019s moduli in the range of 2.6 to 4.6 GPa, which is similar to the modulus of cancellous (spongy) human bone.Peer reviewed: YesNRC publication: Ye

The spinal cord dura mater reaction to nitinol and titanium alloy particles: a 1-year study in rabbits

This investigation was undertaken to simulate in an animal model the particles released from a porous nitinol interbody fusion device and to evaluate its consequences on the dura mater, spinal cord and nerve roots, lymph nodes (abdominal para-aortic), and organs (kidneys, spleen, pancreas, liver, and lungs). Our objective was to evaluate the compatibility of the nitinol particles with the dura mater in comparison with titanium alloy. In spite of the great use of metallic devices in spine surgery, the proximity of the spinal cord to the devices raised concerns about the effect of the metal debris that might be released onto the neural tissue. Forty-five New Zealand white female rabbits were divided into three groups: nitinol (treated: N = 4 per implantation period), titanium (treated: N = 4 per implantation period), and sham rabbits (control: N = 1 per observation period). The nitinol and titanium alloy particles were implanted in the spinal canal on the dura mater at the lumbar level L2–L3. The rabbits were sacrificed at 1, 4, 12, 26, and 52 weeks. Histologic sections from the regional lymph nodes, organs, from remote and implantation sites, were analyzed for any abnormalities and inflammation. Regardless of the implantation time, both nitinol and titanium particles remained at the implantation site and clung to the spinal cord lining soft tissue of the dura mater. The inflammation was limited to the epidural space around the particles and then reduced from acute to mild chronic during the follow-up. The dura mater, sub-dural space, nerve roots, and the spinal cord were free of reaction. No particles or abnormalities were found either in the lymph nodes or in the organs. In contact with the dura, the nitinol elicits an inflammatory response similar to that of titanium. The tolerance of nitinol by a sensitive tissue such as the dura mater during the span of 1 year of implantation demonstrated the safety of nitinol and its potential use as an intervertebral fusion device