STABILITY WITHOUT COMPROMISES MAGNEZIX PIN: AT FIRST METAL THEN BONE

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STABILITY WITHOUT COMPROMISES MAGNEZIX PIN: AT FIRST METAL THEN BONE UP TO 5x MORE STABLE THAN POLYMER PINS! Intelligent innovations for a better life. www.syntellix.com

The benefits at a glance Metallic and transformable. Osteoconductive. Suitable for MRI and CT diagnostics. Reduced risk of infection. Minimal radiological artifacts. Free of cobalt, chrome, nickel and aluminium. Excellent biocompatibility, no known allergies. Superior stability compared to PLA/PGA implants. Prevents "stress shielding". Preisträger 2016 Deutscher Zukunftspreis Gesundheitswirtschaft Top-Innovator 2015 & 2016

MAGNEZIX Pin KEEPS ITS PROMISES Innovation has no end: MAGNEZIX, the world s unique material for metal implants that are both stable and transformable, is now also available as a pin! No more compromises: The metallic MAGNEZIX Pins are mechanically stable and therefore much more resilient than conventional polymer implants. However, unlike normal metal screws or wires, they do not need to be removed instead, they degrade completely within the body and are replaced by endogenous tissue. The ideal solution: MAGNEZIX implants are suitable for all indications that require temporary but secure fixation of the bone, but for which remaining material or a surgical removal of the metal following the healing process is not desirable. The MAG- NEZIX Pin therefore opens up a broader spectrum of indications particularly for trauma and sports surgery. MAGNEZIX [ma gnezi ks]: A magnesium alloy (Mg content > 90%) with unique stability properties and material of the world s first approved bioabsorbable metal implants. MAGNEZIX Pins offer you: Stability: MAGNEZIX Pins offer significantly greater stability than polymer pins. Inhibition of infection: When magnesium degrades, an alkaline, anti-bacterial environment is created. Transformation: MAGNEZIX Pins transform in the body and will be replaced by endogenous bone tissue. Tolerance: The components of the alloy are not known to cause any allergic reactions. Osteoconductivity: MAGNEZIX implants stimulate bone growth. A WORLD FIRST! The MAGNEZIX principle First healing, then dissolving! MAGNEZIX Pins combine metallic stability and transformation, setting new standards for traumatology and sports surgery.

SUPERIOR STABILITY UP TO 5 TIMES MORE STABLE THAN POLYMER PINS (E.G. PLA) Setting new standards: MAGNEZIX Pins boast mechanical stability values far superior to those of previously available bioresorbable materials. Both initially and during the degradation process, MAGNEZIX Pins offer considerably greater stability than comparable PLA pins and even those with larger dimensions. That means superior stability that is sure to impress during day-to-day surgery. Not only this, MAGNEZIX can offer you and your patients even more benefits: osteoconductivity, inhibition of infection and very high tolerance levels. DESIGN AND FUNCTION SOPHISTICATED DETAILS FROM THE HEAD TO THE TIP Head design The flat design of the MAGNEZIX Pin head enables the bone fragment to be repositioned with a high degree of stability and the pin head to be completely countersunk. Axially stabilising shaft design The symmetrically positioned collars on the pin shaft result in the compression of the free bone fragment during impaction of the implant. In addition, they increase the axial positioning precision of the implant. Design of the pin tip The tip design of the MAGNEZIX Pin displaces cancellous bone, thereby compressing the implant bed and facilitating positioning.

Comparative stability values MAXIMUM SHEAR [N] 816 962 931 525 548 682 258 270 85 138 246 1.5 mm 2.0 mm 2.7 mm 3.2 mm (Tested in accordance with ASTM F1044-05 ASTM F2502-11 Load rate 5 mm/min) MAXIMUM BENDING [N] 165 130 84 28 19 9 46 34 12 66 18 1.5 mm 2.0 mm 2.7 mm 3.2 mm (Tested in accordance with ASTM F1264-14 ASTM F2502-11 Load rate 5 mm/min) MAGNEZIX Pin 0 h corrosion MAGNEZIX Pin 288 h corrosion 1 PLA pin 0 h degradation IMPRESSING STABILITY! Not only initially, but also when corroded, even the smallest MAGNEZIX Pin 1.5 offers significantly better stability than a larger, non-degraded PLA pin with a diameter of 2.7 mm. Corrosion: PBS 37 C ph 7.4 1 288 hours of corrosion in vitro correspond to approx. 80 days in vivo (individual values may vary according to the patient and the implant bed).

Examplary applications - Osteochondral fractures of the upper arm and shoulder joint Elbow: - Distal humerus - Radial head - Distal radius and ulna - Metaphyseal fractures of the radius and ulna - Carpal bones and metacarpal bones - Osteochondral fractures in the hip joint (e.g. Pipkin) - Fingers - Finger joints - Osteochondral flakes and fractures - Osteochondrosis dissecans - Distal femur - Proximal tibia - Osteochondral flakes and fractures - Osteochondrosis dissecans - Tarsal and metatarsal bones

INDICATIONS A MULTITUDE OF TRAUMATOLOGY APPLICATIONS MAGNEZIX implants are ideally suited for indications in acute medicine or sports medicine that require secure fixation of the bone with no foreign material remaining in the body a clear advantage for you and your patients. The indications for MAGNEZIX Pins are reconstructive procedures following fractures and misalignment of the human skeleton, for example: Intra-articular and extra-articular fractures of small bones and bone fragments Arthrodeses and osteotomies of small bones and joints Small osseous ligament and tendon ruptures Osteochondral fractures and dissecates Indications for MAGNEZIX Pin 1.5 include: Phalangeal and metacarpal bones Osteochondrosis dissecans Indications for MAGNEZIX Pin 2.0 include: Carpal, metacarpal, tarsal and metatarsal bones Ulnar and radial styloid processes Capitulum of the humerus and radial head Indications for MAGNEZIX Pin 2.7 and 3.2 include: Pipkin fractures Metaphyseal fractures of the radius and ulna A QUICKER RETURN TO FITNESS! MAGNEZIX implants stimulate bone growth, support the healing process and help to avoid unnecessary sick days and risks, as no foreign material that could cause problems and requires removal remains within the body.

THE MAGNEZIX MATERIAL REVOLUTIONARY AND PIONEERING While metal implants that convert to bone may at first seem like fantasy, this has become a reality for medicine following years of research into materials. Specifically, MAGNEZIX is a magnesium-based alloy (more than 90 % Mg content), which, despite its metallic properties, completely degrades within the body and is replaced by endogenous tissue. The biomechanical properties of MAGNEZIX closely resemble those of human bone. Some studies have also shown that magnesium-based alloys exhibit osteoconductive 2 properties. As magnesium is degraded by means of corrosion, an alkaline, anti-bacterial environment is also created in the immediate vicinity of the implant. For this reason, MAGNEZIX ( > 90 % Mg) can be expected to exhibit anti-infective properties. Advantages for users and patients: The mechanical properties (e.g. bending, tension, torsion) are significantly better than those of conventional resorbable implants. Fully conversion of the implant to endogenous tissue makes subsequent removal of the metal unnecessary. The favorable elasticitiy (Young s modulus) of MAGNEZIX implants helps to prevent "stress shielding". There are barely any differences in application between MAGNEZIX implants and conventional implants made of steel or titanium. Histological investigations show bone formation at the surface of the implant, as well as bone growth in the implant areas where resorption has already taken place. MAGNEZIX implants are radiologically visible, conditionally MRI-proof and only generate minimal artifacts. Cost savings as MAGNEZIX eliminates the need to prepare/plan and perform an implant removal. 2 Revell et al.: The effect of magnesium ions on bone bonding to hydroxyapatite coating on titanium alloy implants. Key Eng Mater 2004:254-256:447-50. Liu et al.: Magnesium directly stimulates osteoblast proliferation. J Bone Miner Res 1988;3:104. Zreiqat et al.: Mechanisms of magnesium-stimulated adhesion of osteoblastic cells to commonly used orthopaedic implants. J Biomed Mater Res 2002 Nov;62(2):175-84.

Supporting the healing process b. Overview a: Histological evaluations of an animal study have shown complete conversion of the metal implant after a 12-month implantation period. c. a. b. c. Orthopaedic Clinic of the Hannover Medical School Section b: Formation of new bone (osteoid) on the surface of the degraded implant has been histologically demonstrated. Section c: The presence of osteoclasts and osteoblasts characterises the bone conversion process. Diagrams: SAGE Publications Ltd. All rights reserved. Waizy et al: In vivo study of a biodegradable orthopedic screw (MgYREZr-alloy) in a rabbit for up to 12 months. Journal of Biomaterials Applications, 03.01.2013

THE IMPLANTS PRODUCT OVERVIEW Depending on size, the MAGNEZIX Pin can be used as a bone pin for children, adolescents or adults for the adaptation-stable or exercise-stable fixation of bones, bone fragments or osteochondral fragments for areas that are only subjected to minor loads. PIN DIMENSIONS LENGTHS MAGNEZIX Pin 1.5 Diameter 1.5 mm 8 to 30 mm Head diameter 2.5 mm MAGNEZIX Pin 2.0 Diameter 2.0 mm 8 to 40 mm Head diameter 3.0 mm MAGNEZIX Pin 2.7 Diameter 2.7 mm 12 to 50 mm Head diameter 4.0 mm MAGNEZIX Pin 3.2 Diameter 3.2 mm 12 to 50 mm Head diameter 5.0 mm

OTHER MAGNEZIX IMPLANTS CS DIMENSIONS LENGTHS CBS DIMENSIONS LENGTHS MAGNEZIX CS 2.0 Diameter 2.0 mm Head diameter 2.5 mm 8 to 24 mm (in 2-mm increments), non-cannulated MAGNEZIX CBS 2.0 Diameter 2.0 mm Head diameter 4.0 mm 6 to 20 mm MAGNEZIX CS 2.7 Diameter 2.7 mm Head diameter 3.5 mm Guide wire 1.0 mm 10 to 34 mm (in 2-mm increments), cannulated MAGNEZIX CBS 2.7 Diameter 2.7 mm Head diameter 5.0 mm 6 to 30 mm MAGNEZIX CS 3.2 Diameter 3.2 mm Head diameter 4.0 mm Guide wire 1.2 mm 10 to 40 mm (in 2-mm increments), cannulated MAGNEZIX CBS 3.5 Diameter 3.5 mm Head diameter 6.0 mm 8 to 40 mm For further information, please contact our field team or write to us at: info@syntellix.com ADDITIONAL LITERATURE AND STUDIES Helling H.-J. Prokop A. Schmid H. U. Nagel M. Lilienthal J. Rehm K. E. (2006): Biodegradable implants versus standard metal fixation for displaced radial head fractures. A prospective, randomized, multicenter study. In: Journal of Shoulder and Elbow Surgery 15 (4), S. 479-485. Plaass C. Ettinger S. Sonnow L. Koenneker S. Noll Y. Weizbauer A. Reifenrath J. Claassen L. Daniilidis K. Stukenborg-Colsman C. Windhagen H. (2016): Early Results Using a Biodegradable Magnesium Screw for Modified Chevron Osteotomies. In: Journal of Orthopaedic Research, online - DOI: 10.1002/jor.23241. Prokop A. Chmielnicki M. (2013): Versorgung von dislozierten Radiuskopffrakturen mit bioresorbierbaren Implantaten. In: Zeitschrift für Orthopädie und Unfallchirurgie 151 (6), S. 565-568. Prokop A. Jubel A. Helling H. J. Udomkaewkanjana C. Brochhagen H. G. Rehm K. E. (2002): Neue biodegradable Polylactidimplantate (Polypin -C) zur Therapie von Radiuskopffrakturen. In: Der Chirurg 73 (10), S. 997-1004. Seitz J.-M. Lucas A. Kirschner M. H. (2016): Magnesium-Based Compression Screws: A Novelty in the Clinical Use of Implants. In: Journal of The Minerals, Metals & Materials Society 68 (4), S. 1177-1182. Sonnow L. Könneker S. Vogt P. M. Wacker F. von Falck C. (2017): Biodegradable magnesium Herbert screw image quality and artifacts with radiography, CT and MRI. In: BMC Medical Imaging 17(1):16, DOI: 10.1186/s12880-017-0187-7. Tabaddor R. R. Banffy M. B. Andersen J. S. McFeely E. Ogunwole O. Micheli L. J. Kocher M. S. (2010): Fixation of Juvenile Osteochondritis Dissecans Lesions of the Knee Using Poly 96L/4D-lactide Copolymer Bioabsorbable Implants. In: Journal of Pediatric Orthopaedics 30 (1), S: 14-20. Waizy H. Diekmann J. Weizbauer A. Reifenrath J. Bartsch I. Neubert V. et al. (2014): In vivo study of a biodegradable orthopedic screw (MgYREZr-alloy) in a rabbit model for up to 12 months. In: Journal of Biomaterials Applications 28 (5), S. 667 675. Waris E. Ashammakhi N. Kaarela O. Raatikainen T. Vasenius J. (2004): Use of Bioabsorbable Osteofixation Devices in the Hand. In: Journal of Hand Surgery 29 (6), S. 590-598.

Syntellix AG Aegidientorplatz 2a 30159 Hannover, Germany T +49 511 270 413 50 F +49 511 270 413 79 info@syntellix.com www.syntellix.com Implants are manufactured in cooperation with Königsee Implantate GmbH in Germany. Misprints and errors are reserved. M 7110.001.002 03/17

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