Total disc arthroplasty offers both theoretical and practical advantages over fusion surgery as a treatment for low back pain. In the majority of cases, these relatively new devices owe much of their evolution to the success of other total joint replacements, in particular, hip and knee prostheses, which have been developed over the last four decades. The demands on these new joints are substantial, and although short-term data appear to demonstrate good outcomes in a significant proportion of patients, medium- and longer-term results are sparse. The wear performance of these devices should be emphasized as a possible cause of failure through both adverse biological reactions, such as osteolysis, and inappropriate biomechanics, similar to that observed in a small proportion but numerically significant number of hip and knee prostheses. This article reviews the current technology in terms of the performance parameters these devices are required to operate within and the evidence for future problems akin to those observed in other joint arthroplasties. The article calls for more rigorous preclinical testing and follow-up protocols, based on the technologies and procedures developed for the current range of conventional hip and knee replacements.
DeyoR. A.WeinsteinJ. N.Low back painNew Engl. J. Med., 2001, 344, 363–370.
2.
FrymoyerJ. W.Cats-BarilW. L.An overview of the incidences and costs of low back painOrthop. Clin. North Am., 1991, 22, 263–271.
3.
NachemsonA.WaddellG.NorlundA.Epidemiology of neck and low back pain In Neck and back pain: the scientific evidence of causes, diagnosis and treatment (Eds NachemesonA.JonssonE.), 2000 (Lippincott, Williams, and Wilkins, Philadelphia).
4.
MaetzelA.LiL.The economic burden of low back pain: A review of studies published between 1996 and 2001. BailliereBest Pract. Res. Clin. Rheumatol., 2002, 16, 23–30.
5.
WeinsteinJ. N.BodenS. D.AnH.Emerging technology in spine: Should we rethink the past or move forward in spite of the past?Spine, 2003, 28, S1.
6.
BlumenthalS. L.OhnmeissD. D.GuyerR.HochschulerS.McAfeeP.GarciaR.SalibR.YuanH.LeeC.BertagnoliR.BryanU.WinterR.Artificial intervertebral discs and beyond: A North American spine society annual meeting symposiumSpine J., 2002, 2, 460–463.
7.
Scott-YoungM.Artificial intervertebral discs and beyondNorth American Spine Society, San Diego, 2003.
8.
SantosE. G.PollyD. W.MehbodA. A.SalehK. J.Disc arthroplasty: Lessons learned from total joint arthroplastySpine J., 2004, 4, 182S-189S.
McAfeeP. C.The indications for lumbar and cervical disc replacementSpine J., 2004, 4, 177S-181S.
11.
PollyD. W.JrAdapting innovative motion-preserving technology to spinal surgical practice: What should we expect to happen?Spine, 2003, 28, S104-S109.
12.
VillarragaM. L.CriptonP. A.The clinical performance of UHMWPE in the spine In The UHMWPE handbook: ultra-high molecular weight polyethylene in total joint replacement, (Ed. KurtzS. M.) 2004, pp. 219–242, (Elsevier Academic Press).
13.
CunninghamB. W.OrbegosoC. M.DmitrievA. E.HallabN. J.SefterJ. C.AsdourianP.McAfeeP. C.The effect of spinal instrumentation particulate wear debris. An in vivo rabbit model and applied clinical study of retrieved instrumentation casesSpine J., 2003, 3, 19–32.
DeyoR. A.NachemsonA.MirzaS. K.Spinalfusion surgery - the case for restraintNew Engl. J. Med., 2004, 350, 722–726.
16.
AnderssonG. B.Epidemiological features of chronic low-back painLancet, 1999, 354, 581–585.
17.
WipfJ. E.DeyoR. A.Low back painMed. Clin. North Am., 1995, 79, 231–246.
18.
BodenS. D.DavisD. O.DinaT. S.PatronasN. J.WieselS. W.Abnormal magnetic-resonance scans of the lumbar spine in asymptomatic subjects. A prospective investigationJ. Bone Jt Surg. Am., 1990, 72, 403–408.
19.
BodenS. D.BalderstonR. A.HellerJ. G.HanleyE. N.JrZiglerJ. E.An AOA critical issue. Disc replacements: This time will we really cure low-back and neck pain?J. Bone Jt Surg. Am., 2004, 86, 411–422.
20.
AbrahamD. J.HerkowitzH. N.KatzJ. N.Indications for thoracic and lumbar spine fusion and trends in useOrthop. Clin. North Am., 1998, 29, 803.
21.
GilletP.The fate of the adjacent motion segments after lumbar fusionJ. Spinal Disord. Tech., 2003, 16, 338–345.
22.
BonoC. M.LeeC.Critical analysis of trends in fusion for degenerative disc disease over the last twenty years: Influence of technique on fusion rate and clinical outcomeSpine J., 2004, 29, 455–463.
23.
HingK. A.BestS. M.TannerK. E.BonfieldW.RevellP. A.Mediation of bone ingrowth in porous hydroxyapatite bone graft substitutesJ. Biomed. Mater. Res. A, 2004, 68, 187–200.
24.
BurkusJ. K.HeimS. E.GornetM. F.ZdeblickT. A.Is INFUSE bone graft superior to autograft bone? An integrated analysis of clinical trials using the LT-CAGE lumbar tapered fusion deviceJ. Spinal Disord. Tech., 2003, 16, 113–122.
25.
AndersonD. G.AlbertT. J.Bone grafting, implants, and plating options for anterior cervical fusionsOrthop. Clin. North Am., 2002, 33, 317–328.
26.
MeadowsG. R.Adjunctive use of ultraporous betatricalcium phosphate bone void filler in spinal arthrodesisOrthopedics, 2002, 25, s579–s584.
27.
BodenS. D.Overview of the biology of lumbar spine fusion and principles for selecting a bone graft substituteSpine, 2002, 27, S26–S31.
RoussoulyP.GolloglyS.BerthonnaudE.DimnetJ.Classification of the normal variation in the sagittal alignment of the human lumbar spine and pelvis in the standing positionSpine, 2005, 30, 346–353.
30.
LonsteinJ. E.DenisF.PerraJ. H.PintoM. R.SmithM. D.WinterR. B.Complications associated with pedicle screwsJ. Bone Jt Surg. Am., 1999, 81, 1519–1528.
31.
CallaghanJ. P.PatlaA. E.McGillS. M.Low back three-dimensional joint forces, kinematics, and kinetics during walkingClin. Biomech., 1999, 14, 203–216.
32.
FergusonS. A.Gaudes-MacLarenL. L.MarrasW. S.WatersJ. R.DavisK. G.Spinal loading when lifting from industrial storage binsErgonomics, 2002, 45, 399–414.
33.
RohlmanntA.ClaesL. E.BergmanntG.GraichenF.NeefP.WilkeH. J.Comparison of intradiscal pressures and spinal fixator loads for different body positions and exercisesErgonomics, 2001, 44, 781–794.
34.
RohlmannA.ArntzU.GraichenF.BergmannG.Loads on an internal spinal fixation device during sittingJ. Biomech., 2001, 34, 989–993.
35.
RohlmannA.GraichenF.WeberU.BergmannG.2000 Volvo Award winner in biomechanical studies: Monitoring in vivo implant loads with a telemeterized internal spinal fixation deviceSpine, 2000, 25, 2981–2986.
36.
RohlmannA.BergmannG.GraichenF.Loads on internal spinal fixators measured in different body positionsEur. Spine J., 1999, 8, 354–359.
37.
KumarS.MoroL.NarayanY.A biomechanical analysis of loads on x-ray technologists: A field studyErgonomics, 2003, 46, 502–517.
38.
FathallahF. A.MarrasW. S.ParnianpourM.An assessment of complex spinal loads during dynamic lifting tasksSpine, 1998, 23, 706–716.
39.
DennisG. J.BarrettR. S.Spinal loads during individual and team liftingErgonomics, 2002, 45, 671–681.
40.
CallaghanJ. P.McGillS. M.Low back joint loading and kinematics during standing and unsupported sittingErgonomics, 2001, 44, 280–294.
41.
FrobinW.BrinckmannP.LeivsethG.BiggemannM.ReikerasO.Precision measurement of segmental motion from flexion-extension radiographs of the lumbar spineClin. Biomech.1996, 11, 457–465.
42.
HaradaM.AbumiK.ItoM.KanedaK.Cineradiographic motion analysis of normal lumbar spine during forward and backward flexionSpine, 2000, 25, 1932–1937.
43.
McGregorA. H.AndertonL.GedroycW. M.JohnsonJ.HughesS. P.The use of interventional open MRI to assess the kinematics of the lumbar spine in patients with spondylolisthesisSpine, 2002, 27, 1582–1586.
44.
PearcyM. J.TibrewalS. B.Axial rotation and lateral bending in the normal lumbar spine measured by three-dimensional radiographySpine, 1984, 9, 582–587.
45.
PearcyM.PortekI.ShepherdJ.Three-dimensional X-ray analysis of normal movement in the lumbar spineSpine, 1984, 9, 294–297.
46.
WhiteA. A.PanjabiM.Clinical biomechanics of the spine, 1991 (Lippincott, Williams, and Wilkins, Philadelphia).
47.
GattonM. L.PearcyM. J.Kinematics and movement sequencing during flexion of the lumbar spineClin. Biomech., 1999, 14, 376–383.
48.
PearcyM. J.BogdukN.Instantaneous axes of rotation of the lumbar intervertebral jointsSpine, 1988, 13, 1033–1041.
49.
EdwardsJ. C.SedgwickA. D.WilloughbyD. A.The formation of a structure with the features of synovial lining by subcutaneous injection of air: An in vivo tissue culture systemJ. Pathol., 1981, 134, 147–156.
50.
AunobleS.DonkerslootP.Le HuecJ. C.Dislocations with intervertebral disc prosthesis: Two case reportsEur. Spine J., 2004, 13, 464–467.
51.
KurtzS. M.PatwardhanA.van OoijA.LorenzM.ZindrickM. R.O'LearyP.PelozaJ.CiccarelliL.VillarragaM. L.What is the correlation of in vivo wear and fracture patterns with in vitro motion response. In Spine Arthroplasty 6: Global Symposium on Motion preservation technology, Montreal, Canada, 2006 (Spine Arthroplasty Society).
52.
KurtzS. M.van OoijA.PelozaJ.CiccarelliL.ZeigerA.VillarragaL. M.Wear and surface damage analysis of retrieved Charité total disc replacements. Spine Arthroplasty 5: Global Symposium on Motion preservation technology. New York City, USA, 2005 (Spine Arthroplasty Society).
53.
BertagnoliR.KumarS.Indications for full prosthetic disc arthroplasty: A correlation of clinical outcome against a variety of indicationsEur. Spine J., 2002, 11, S131-S136.
54.
CinottiG.DavidT.PostacchiniF.Results of disc prosthesis after a minimum follow-up period of 2 yearsSpine, 1996, 21995–1000.
55.
EnkerP.SteffeeA.McMillinC.KepplerL.BiscupR.MillerS.Artificial disc replacement. preliminary report with a 3-year minimum followupSpine, 1993, 18, 1061–1070.
56.
GriffithS. L.ShelokovA. P.Buttner-JanzK.Le MaireJ. P.ZeegersW. S.A multicenter retrospective study of the clinical results of the LINK SB Charite intervertebral prosthesis. The initial European experienceSpine, 1994, 19, 1842–1849.
57.
HochschulerS. H.OhnmeissD. D.GuyerR. D.BlumenthalS. L.Artificial disc: Preliminary results of a prospective study in the United StatesEur. Spine J., 2002, 11, S106-S110.
58.
ZeegersW. S.BohnenL. M.LaaperM.VerhaegenM. J.Artificial disc replacement with the modular type SB Charite III: 2-year results in 50 prospectively studied patientsEur. Spine J., 1999, 8, 210–217.
59.
De KleuverM.OnerF. C.JacobsW. C.Total disc replacement for chronic low back pain: Background and a systematic review of the literatureEur. Spine J., 2003, 12, 108–116.
60.
McAfeeP. C.FedderI. L.SaiedyS.ShucoskyE. M.CunninghamB. W.SB Charite disc replacement: Report of 60 prospective randomized cases in a US centerJ. Spinal Disord. Tech., 2003, 16, 424–433.
61.
BlumenthalS. L.OhnmeissD. D.GuyerR. D.HochschulerS. H.Prospective study evaluating total disc replacement: Preliminary resultsJ. Spinal Disord. Tech., 2003, 16, 450–454.
62.
LemaireJ. P.SkalliW.LavasteF.TemplierA.MendesF.DiopA.SantyV.LalouxE.Intervertebral disc prosthesis. Results and prospects for the year 2000Clin. Orthop., 1997, 337, 64–76.
63.
LinkH. D.History, design and biomechanics of the LINK SB Charite artificial discEur. Spine J., 2002, 11, S98-S105.
64.
van OoijA.OnerF. C.VerboutA. J.Complications of artificial disc replacement: A report of 27 patients with the SB Charite discJ. Spinal Disord. Tech., 2003, 16, 369–383.
65.
HallR. M.FisherJ.InghamE. Metal-on-poly versus metal-on-metal: fact versus fiction 1st Annual Spine Athroplasty Summit, Salt Lake City, 2006.
66.
ZiglerJ. E.DelamarterR. B.BaeH. W.SachsB. L.RashbaumR. F.OhnmeissD. D.KanimL. E.PradhanP. B.Lumbar total disc replacement: A 2 to 3 year report from 2 centers in the United States clinical trial for the Prodisc-II prosthesis. In Spine Arthroplasty 5: Global Symposium onMotion preservation technology.2005, pp. 511–512 (Spine Arthroplasty Society, New York City, USA).
HuangR. C.GirardiF. P.CammisaF. P.JrTropianoP.MarnayT.Long-term flexion-extension range of motion of the prodisc total disc replacementJ. Spinal Disord. Tech., 2003, 16, 435–440.
69.
TropianoP.HuangR. C.GirardiF. P.MarnayT.Lumbar disc replacement: Preliminary results with ProDisc II after a minimum follow-up period of 1 yearJ. Spinal Disord. Tech., 2003, 16, 362–368.
70.
CunninghamB. W.GordonJ. D.DmitrievA. E.HuN.McAfeeP. C.Biomechanical evaluation of total disc replacement arthroplasty: An in vitro human cadaveric modelSpine, 2003, 28, S110-S117.
71.
LorenzM. A.O'LearyP.NicolakisM.GhanayemA. J.VoronovL. I.ZindrickM. R.PatwardhanA.Effect of placement variability on the motion response of total disc replacement under physiologic loads. In Spine Arthroplasty 6: Global Symposium onMotion preservation technology, 2006, pp. 9–10 (Spine Arthroplasty Society, Montreal, Canada).
72.
SharmaM.LangranaN. A.RodriguezJ.Role of ligaments and facets in lumbar spinal stabilitySpine, 1995, 20, 887–900.
73.
WroblewskiB. M.Revision surgery in total hip arthroplasty, 1990, p. 240 (Springer-Verlag, Hamburg).
74.
HuddlestonH. D.Femoral lysis after cemented hip arthroplastyJ. Arthroplasty, 1988, 3, 285–297.
75.
WillertH. G.BertramH.BuchhornG. H.Osteolysis in alloarthroplasty of the hip. The role of ultra-high molecular weight polyethylene wear particlesClin. Orthop., 1990, 258, 95–107.
76.
AnthonyP. P.GieG. A.HowieC. R.LingR. S.Localised endosteal bone lysis in relation to the femoral components of cemented total hip arthroplastiesJ. Bone Jt Surg. Br., 1990, 72, 971–979.
77.
GoldringS. R.SchillerA. L.RoelkeM.RourkeC. M.O'NeilD. A.HarrisW. H.The synovial-like membrane at the bone-cement interface in loose total hip replacements and its proposed role in bone lysisJ. Bone Jt Surg. Am., 1983, 65, 575–584.
78.
CallaghanJ. J.PedersenD. R.JohnstonR. C.BrownT. D.Clinical biomechanics of wear in total hip arthroplastyIowa Orthop. J., 2003, 23, 1–12.
79.
GoodmanS. B.LindM.SongY.SmithR. L.In vitro, in vivo, and tissue retrieval studies on particulate debrisClin. Orthop., 1998, 352, 25–34.
80.
HirakawaK.JacobsJ. J.UrbanR.SaitoT.Mechanisms of failure of total hip replacements: Lessons learned from retrieval studiesClin. Orthop., 2004, 420, 10–17.
81.
HaileyJ. L.InghamE.StoneM.WroblewskiB. M.FisherJ.Ultra-high molecular weight polyethylene wear debris generated in vivo and in laboratory tests; the influence of counterface roughnessProc. Instn. Mech. Engrs, Part H: J. Engineering in Medicine, 1996, 210, 3–10.
82.
GreenT. R.FisherJ.StoneM.WroblewskiB. M.InghamE.Polyethylene particles of a ‘critical size’ are necessary for the induction of cytokines by macrophagesin vitro. Biomaterials, 1998, 19, 2297–2302.
83.
DoorisA. P.AresP. J.GabrielS. M.SerhanH. A.Wear characterization of Charité artificial discs. American Association of Orthopaedic Surgeons 2005, (AAOS, Washington DC, USA).
84.
ElfickA. P.SmithS. L.UnsworthA.Variation in the wear rate during the life of a total hip arthroplasty: A simulator and retrieval studyJ. Arthroplasty, 2000, 15, 901–908.
85.
HallR. M.UnsworthA.SineyP.WroblewskiB. M.Wear in retrieved Charnley acetabular socketsProc. Instn Mech. Engrs, Part H: J. Engineering in Medicine, 1996, 210, 197–207.
86.
DavidT.Revision of a Charité artificial disc 9.5 years in vivo to a new Charité artifical disc: case report and explant analysisEuro Spine J., 2005, 14, 507–511.
BulloughP. G.DiCarloE. F.HansrajK. K.NevesM. C.Pathologic studies of total joint replacementOrthop. Clin. North Am., 1988, 19, 611–625.
89.
KorovessisP.RepantiM.Evolution of aggressive granulomatous periprosthetic lesions in cemented hip arthroplastiesClin. Orthop., 1994, 300, 155–161.
90.
PizzoferratoA.CiapettiG.SteaS.ToniA.Cellular events in the mechanisms of prosthesis looseningClin. Mater., 1991, 7, 51–81.
91.
MirraJ. M.MarderR. A.AmstutzH. C.The pathology of failed total joint arthroplastyClin. Orthop., 1982, 170, 175–183.
92.
WillertH. G.BuchhornG. H.Particle disease due to wear of ultrahigh molecular weight polyethylene. Findings from retrieval studies, In Biological, material and mechanical considerations of joint replacement (Ed. MorreyB. F.), 1993, p. 97-102 (Raven Press, New York).
93.
BobynJ. D.JacobsJ. J.TanzerM.UrbanR. M.AribindiR.SumnerD. R.TurnerT. M.BrooksC. E.The susceptibility of smooth implant surfaces to periimplant fibrosis and migration of polyethylene wear debrisClin. Orthop., 1995, 311, 21–39.
94.
HowieD. W.HaynesD. R.RogersS. D.McGeeM. A.PearcyM. J.The response to particulate debrisOrthop. Clin. North Am., 1993, 24, 571–581.
95.
MaloneyW. J.JastyM.HarrisW. H.GalanteJ. O.CallaghanJ. J.Endosteal erosion in association with stable uncemented femoral componentsJ. Bone Jt Surg. Am., 1990, 72, 1025–1034.
96.
SchmalzriedT. P.MaloneyW. J.JastyM.KwongL. M.HarrisW. H.Autopsy studies of the bone-cement interface in well-fixed cemented total hip arthroplastiesJ. Arthroplasty, 1993, 8, 179–188.
97.
SchmalzriedT. P.JastyM.HarrisW. H.Periprosthetic bone loss in total hip arthroplasty. Polyethylene wear debris and the concept of the effective joint spaceJ. Bone Jt Surg. Am., 1992, 74, 849–863.
98.
HirakawaK.BauerT. W.StulbergB. N.WildeA. H.BordenL. S.Characterization of debris adjacent to failed knee implants of 3 different designsClin. Orthop., 1996, 331, 151–158.
99.
CampbellP.MaS.YeomB.McKellopH.SchmalzriedT. P.GrigorisP.AmstutzH. C.SarmientoA.Isolation of predominantly submicron-sized UHMWPE wear particles from periprosthetic tissuesJ. Biomed. Mater. Res., 1995, 29, 127–131.
100.
McKellopH. A.CampbellP.ParkS. H.SchmalzriedT. P.GrigorisP.AmstutzH. C.SarmientoA.The origin of submicron polyethylene wear debris in total hip arthroplastyClin. Orthop., 1995, 311, 3–20.
101.
InghamE.FisherJ.Biological reactions to wear debris in total joint replacementProc. Instn Mech. Engrs, Part H: J. Engineering in Medicine, 2000, 214, 21–37.
102.
TipperJ. L.InghamE.HaileyJ. L.BesongA. A.FisherJ.WroblewskiB. M.StoneM. H.Quantitative analysis of polyethylene wear debris, wear rate and head damage in retireved Charnley hip prosthesesJ. Mater: Mater. Med., 2000, 11, 117–124.
103.
RevellP. A.Al-SaffarN.KobayashiA.Biological reaction to debris in relation to joint prosthesesProc. Inst. Mech. Engrs, Part H: Engineering in Medicine, 1997, 211, 187–197.
104.
HeiselC.SilvaM.de la RosaM. A.SchmalzriedT. P.Short-term in vivo wear of crosslinked polyethyleneJ. Bone Jt Surg. Am., 2004, 86, 748–751.
105.
DoornP. F.CampbellP. A.WorrallJ.BenyaP. D.McKellapH. A.AmstutzH. C.Metal wear particle characterization from metal on metal total hip replacements: Transmission electron microscopy study of periprosthetic tissues and isolated particlesJ. Biomed. Mater. Res., 1998, 42, 103–111.
106.
FirkinsP. J.TipperJ. L.SaadatzadehM. R.InghamE.StoneM. H.FarrarR.FisherJ.Quantitative analysis of wear and wear debris from metal-on-metal hip prostheses tested in a physiological hip joint simulatorBiomed. Mater. Eng., 2001, 11, 143–157.
107.
GermainM. A.HattonA.WilliamsS.MatthewsJ. B.StoneM. H.FisherJ.InghamE.Comparison of the cytotoxicity of clinically relevant cobalt-chromium and alumina ceramic wear particlesin vitro. Biomaterials, 2003, 24, 469–479.
