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01-11-2009 | Ideas and Technical Innovations

An injectable nucleus replacement as an adjunct to microdiscectomy: 2 year follow-up in a pilot clinical study

Authors: Ulrich Berlemann, Othmar Schwarzenbach

Published in: European Spine Journal | Issue 11/2009

Abstract

Literature indicates that loss of disc tissue from herniation and/or surgery can accelerate degeneration of the disc. The associated loss of disc height may correspond with recurrent back and/or leg pain. A novel hydrogel has been developed to replace lost nucleus pulposus and potentially restore normal disc biomechanics following herniation and surgery. A single-center, non-randomized, prospective feasibility study was undertaken to investigate the use of NuCore^® Injectable Nucleus hydrogel (Spine Wave, Inc., Shelton, CT, USA) as a replacement for nuclear tissue lost to herniation and microdiscectomy. Fourteen patients were enrolled at the authors’ hospital as the initial site in a worldwide multicenter pilot study. Subjects who were entered into the study suffered from radicular pain due to single-level herniated nucleus pulposus and were non-respondent to conservative therapy. Following a standard microdiscectomy procedure, the hydrogel material was injected into the nuclear void to replace what tissue had been lost to the herniation and surgery. Leg and back pain, function and disability scores were monitored pre- and post-operatively through 2 years. Neurologic and physical evaluations, blood and serum analyses, and radiographic evaluations of disc height and implant stability were also performed. Results showed significant improvement for leg and back pain, as well as function scores. No complications or device related adverse events were observed. MR controls confirmed stable position of the implants with no reherniations. Radiographic measurements indicated better maintenance of disc height compared to literature data on microdiscectomy alone. The NuCore^® material appears to protect the disc from early collapse following microdiscectomy; and therefore, may have the potential to slow the degenerative cascade of the spinal segment over time.

McCulloch JA (1996) Focus issue on lumbar disc herniation: macro- and microdiscectomy. Spine 21:45S–56SCrossRefPubMed

Koebbe CJ, Maroon JC, Abla A, El-Kadi H, Bost J (2002) Lumbar microdiscectomy: a historical perspective and current technical considerations. Neurosurg Focus 13:1–6CrossRef

Wenger M, Mariani L, Kalbarczyk A, Gröger U (2001) Long-term outcome of 104 patients after lumbar sequestrectomy according to Williams. Neurosurgery 49:329–334CrossRefPubMed

Carragee EJ, Spinnickie AO, Alamin TF, Paragioudakis S (2006) A prospective controlled study of limited versus subtotal posterior discectomy: short-term outcomes in patients with herniated lumbar intervertebral discs and large posterior annular defect. Spine 31:653–657CrossRefPubMed

Brinckmann P, Grootenboer H (1991) Change of disc height, radial disc bulge, and intradiscal pressure from discectomy: an in vitro investigation on human lumbar discs. Spine 16:641–646CrossRefPubMed

Thome C, Barth MB, Diepers M, Schmiedek P (2006) A prospective randomized comparison of clinical and radiological outcome after lumbar sequestrectomy versus microdiscectomy. Eur Spine J 15:S477–S478

Tibrewal SB, Pearcy MJ (1985) Lumbar intervertebral disc heights in normal subjects and patients with disc herniation. Spine 10:452–454CrossRefPubMed

Yorimitsu E, Chiba K, Toyama Y, Hirabayashi K (2001) Long-term outcomes of standard discectomy for lumbar disc herniation. Spine 26:652–657CrossRefPubMed

Atlas SJ, Keller RB, Wu YA, Deyo R, Singer D (2005) Long-term outcome of surgical and nonsurgical management of sciatica secondary to a lumbar disc herniation: 10 year results from the Main lumbar spine study. Spine 30:927–935CrossRefPubMed

10.

Korge A, Nydegger T, Polard JL, Mayer H, Husson J (2002) A spiral implant as nucleus prosthesis in the lumbar spine. Eur Spine J 11:S149–S153PubMed

11.

Bertagnoli R, Schönmayr R (2002) Surgical and clinical results with the PDN^® prosthetic disc-nucleus device. Eur Spine J 11:S143–S148PubMed

12.

Walkenhorst J, Lee D, Spenciner D (2004) Extrusion resistance of an injectable nucleus replacement in the human cadaver spine. Poster IMAST

13.

Kitchel S, Capello J (2003) Injectable biomaterials for augmentation of the nucleus pulposus. Poster IMAST

14.

Dewing CB, Provencher MT, Riffenburgh RH, Kerr S, Manos RE (2008) The outcomes of lumbar microdiscectomy in a young, active population: correlation by herniation type and level. Spine 33:33–38CrossRefPubMed

15.

Fountas KN, Kapsalaki EZ, Feltes CH, Smisson HF, Johnston KW, Vogel RL et al (2004) Correlation of the amount of disc removed in a lumbar microdiscectomy with long-term outcome. Spine 29:2521–2524CrossRefPubMed

16.

Ray CD (2002) The PDN^® prosthetic disc-nucleus device. Eur Spine J 11:S137–S142CrossRefPubMed

17.

Ahrens M, Donkersloot P, Martens F, Sherman J, Le Huec JC, Tsantrizos A et al (2007) Nucleus replacement using an in situ cured, balloon contained, injectable polyurethane device: clinical results from two prospective multicenter European studies. Spine J 7:S103CrossRef

18.

Nachemson A (1962) Some mechanical properties of the lumbar intervertebral disc. Bull Hosp Joint Dis 23:130–132PubMed

19.

Bao QB, Yuan HA (2002) New technologies in Spine: nucleus replacement. Spine 27:1245–1247CrossRefPubMed

20.

Chenite A, Chaput C, Wang D, Combes C, Buschmann MD, Hoemann CD et al (2000) Novel injectable neutral solutions of chitosan form biodegradable gels in situ. Biomaterials 21:2155–2161CrossRefPubMed

21.

Ferrari FA, Richardson C, Chambers J, Causey S, Pollock T, Cappello J et al (2002) Peptides comprising repetitive units of amino acids and DNA sequences encoding the same. US Patent 6,355,776

22.

Hubbell JA, Wetering Pvd, Cowling DSP (2002) Novel polymer compounds. US Patent 2002/0177680

23.

Olsen DR, Chang R, McMullin H, Hitzeman R, Chisholm G (2002) Recombinant gelatin and full-length triple helical collagen. US Patent 6,413,742

24.

Urry DW (1991) Polynanopeptide bioelastomers having an increased elastic modulus. US Patent 5,064,430

25.

Di Martino A, Vaccaro AR, Lee JY, Denaro V, Lim M (2005) Nucleus pulposus replacement: basic science and indications for clinical use. Spine 30:S16–S22CrossRefPubMed

26.

DeLustro F, Dasch J, Keefe J, Ellingsworth L (1990) Immune response to allogeneic and xenogeneic implants of collagen and collagen derivatives. Clin Orthop 260:263–279PubMed

27.

Mogues T, Junzhi L, Coburn J, Kuter D (2005) IgG antibodies against bovine serum albumin in humans–their prevalence and response to exposure to bovine serum albumin. J Immunol Methods 300:1–11CrossRefPubMed

28.

Findlay GF, Hall BI, Musa BS, Oliveira MD, Fear SC (1998) A 10-year follow-up of the outcome of lumbar microdiscectomy. Spine 23:1168–1171CrossRefPubMed

29.

Pearson AM, Blood EA, Frymoyer JW, Herkowitz H, Abdu W, Woodward R et al (2008) SPORT lumbar intervertebral disk herniation and back pain—does treatment, location, or morphology matter? Spine 33:428–435CrossRefPubMed

30.

Kuisma M, Karppinen J, Niinimäki J, Kurunlahti M, Haapea M, Vanharanta H et al (2006) A 3-year follow-up of lumbar spine endplate (Modic) changes. Spine 31:1714–1718CrossRefPubMed

31.

Mitra D, Cassar-Pullicino VN, McCall IW (2004) Longitudinal study of vertebral type-1 endplate changes on MR of the lumbar spine. Eur Radiol 14:1574–1581CrossRefPubMed

32.

Toyone T, Takahashi K, Kitahara H, Yamagata M, Murakami M, Moriya H (1994) Vertebral bone-marrow changes in degenerative lumbar disc disease: an MRI study of 74 patients with low back pain. J Bone Joint Surg Br 76B:757–764

33.

Mochida J, Toh E, Nomura T, Nishimura K (2001) The risks and benefits of percutaneous nucleotomy for lumbar disc herniation: a 10-year longitudinal study. J Bone Joint Surg Br 83B:501–505CrossRef

34.

Gorensek M, Vilendecic M, Eustacchio S, Trummer M, Eskinja N, Ledic D et al (2007) Early clinical results with the intrinsic therapeutics Barricaid^® annular repair device—comparison to a prospective control group. Proceedings of the 7th annual global symposium on motion preservation technology, Berlin

35.

Kitano T, Zerwekh JE, Usui Y, Edwards M, Flicker P, Mooney V (1993) Biochemical changes associated with the symptomatic human intervertebral disk. Clin Orthop 293:372–377PubMed

36.

Iatridis JC, Weidenbaum M, Setton LA, Mow VC (1996) Is the nucleus pulposus a solid or a fluid? Mechanical behaviors of the nucleus pulposus of the human intervertebral disc. Spine 21:1174–1184CrossRefPubMed

Title: An injectable nucleus replacement as an adjunct to microdiscectomy: 2 year follow-up in a pilot clinical study
Authors: Ulrich Berlemann
Othmar Schwarzenbach
Publication date: 01-11-2009
Publisher: Springer-Verlag
Published in: European Spine Journal / Issue 11/2009
Print ISSN: 0940-6719
Electronic ISSN: 1432-0932
DOI: https://doi.org/10.1007/s00586-009-1136-0

At a glance: The STEP trials

Springer Medicine

An injectable nucleus replacement as an adjunct to microdiscectomy: 2 year follow-up in a pilot clinical study

Abstract

At a glance: The STEP trials

Springer Medicine

Abstract

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