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DOI: 10.1055/a-2705-2876
Duraplasty with Autologous Blood: A Cost-Effective and Efficient Alternative to Medical Products
Authors
Abstract
Objective
The aim of this experimental study was to investigate the effects of autologous plasma used as an alternative to duraplasty.
Materials and Methods
We operated 21 patients and 8 New Zealand Rabbits and performed duraplasty with autologous blood. First, heparin was added to autologous blood withdrawn from the patient/rabbit. The sample was then centrifuged to obtain plasma. Protamine sulfate was added to the plasma. This mixture was then applied to the dural space and tumor cavity, resulting in fibrin formation within 2 to 3 minutes. All 21 patients had magnetic resonance imaging (MRI) scans 1 month after surgery to show neodura formation. Three of our patients and all rabbits were operated at least a month later, and the biopsy was taken to show the neodura formation microsopically.
Results
In MRI scans, as well as in biopsies, we have detected the neodura formation. In rabbits that underwent experimental craniotomy and duratomy, neodura had formed as a weak, thin membrane that did not show continuity into the defect area after one month. In the control group, the distribution of collagen fibers appeared relatively normal in areas close to the intact dura. However, further from this area, the regular structure was disrupted, edematous areas had formed in the fibrous layers, and bone fragments were separated from the endosteal layer
Conclusion
The hypothesis of this study was that plasma obtained from the patient's own arterial blood could serve as an alternative to traditional duraplasty materials. Plasma possesses many of the properties required for duraplasty material and can be a cost-effective, readily available option. Results demonstrate that autologous plasma does not induce significant histological changes and shows excellent biocompatibility with brain parenchyma. Therefore, autologous plasma can be considered a reliable and safe tissue sealant. It is easy to prepare and apply, remains stable in the operating room for 1 to 2 hours, and can be adjusted in size and thickness according to the dural defect and tumor cavity dimensions.
Publication History
Received: 12 December 2024
Accepted: 18 September 2025
Accepted Manuscript online:
19 September 2025
Article published online:
10 February 2026
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References
- 1 Zwirner J, Ondruschka B, Scholze M, Schulze-Tanzil G, Hammer N. Biomechanical characterization of human temporal muscle fascia in uniaxial tensile tests for graft purposes in duraplasty. Sci Rep 2021; 11 (01) 2127
- 2 Zwirner J, Scholze M, Ondruschka B, Hammer N. What is considered a variation of biomechanical parameters in tensile tests of collagen-rich human soft tissues? Critical considerations using the human cranial dura mater as a representative morpho-mechanic model. Medicina (Kaunas) 2020; 56 (10) 520
- 3 Fam MD, Potash A, Potash M. et al. Skull base dural thickness and relationship to demographic features: a postmortem study and literature review. J Neurol Surg B Skull Base 2018; 79 (06) 614-620
- 4 Pukšec M, Semenski D, Ježek D. et al. Biomechanical comparison of the temporalis muscle fascia, the fascia lata, and the dura mater. J Neurol Surg B Skull Base 2019; 80 (01) 23-30
- 5 Camlar M, Türk Ç, Buhur A. et al. Does decompressive duraplasty have a neuroprotective effect on spinal trauma? An experimental study. World Neurosurg 2019; 126: e288-e294
- 6 Schick B, Abd El Rahman ELT, Brors D, Mosler P, Draf W. Endosal dural teparir: techniques and results. Saudi J Otorhinolaryngol Head Neck Surg 1998; 1: 17-26
- 7 Matulla CW, Steiger CN. Hemostasin and Fleece- Bound Sealing in Neurosurgery. New York: Thieme; 2005: 1-86
- 8 Lee KC, Park SK, Lee KS. Neurosurgical application of fibrin adhesive. Yonsei Med J 1991; 32 (01) 53-57
- 9 Parízek J, Husěk Z, Mĕricka P. et al. Ovine pericardium: a new material for duraplasty. J Neurosurg 1996; 84 (03) 508-513
- 10 Perrini P. Technical nuances of autologous pericranium harvesting for dural closure in Chiari malformation surgery. J Neurol Surg B Skull Base 2015; 76 (02) 90-93
- 11 Parízek J, Měřička P, Němeček S. et al. Posterior cranial fossa surgery in 454 children. Comparison of results obtained in pre-CT and CT era and after various types of management of dura mater. Childs Nerv Syst 1998; 14 (09) 426-438 , discussion 439
- 12 Marin Laut FM, Gómez Cárdenas EA, Dormido JR, Molina NM, López López JA. Spinal dural closure without suture: Minimizing the risk of CSF leakage with a flat non-penetrating titanium U-clip. Neurocirugia (Astur Engl Ed) 2019; 30 (04) 173-178
- 13 Sanchez e Oliveira RdeC, Valente PR, Abou-Jamra RC, Araújo A, Saldiva PH, Pedreira DAL. Biosynthetic cellulose induces the formation of a neoduramater following pre-natal correction of meningomyelocele in fetal sheep. Acta Cir Bras 2007; 22 (03) 174-181
- 14 Islam S, Ogane K, Ohkuma H, Suzuki S. Usefulness of acellular dermal graft as a dural substitute in experimental model. Surg Neurol 2004; 61 (03) 297-302 , discussion 303
- 15 Abuzayed B, Kafadar AM, Oğuzoğlu ŞA, Canbaz B, Kaynar MY. Duraplasty using autologous fascia lata reenforced by on-site pedicled muscle flap: technical note. J Craniofac Surg 2009; 20 (02) 435-438
- 16 Stumpf TR, Sandarage RV, Galuta A. et al. Design and evaluation of a biosynthesized cellulose drug releasing duraplasty. Mater Sci Eng C 2020; 110: 110677
- 17 Ucar B. Natural biomaterials in brain repair: a focus on collagen. Neurochem Int 2021; 146: 105033
- 18 Parlato C, di Nuzzo G, Luongo M. et al. Use of a collagen biomatrix (TissuDura) for dura repair: a long-term neuroradiological and neuropathological evaluation. Acta Neurochir (Wien) 2011; 153 (01) 142-147
- 19 Cobel-Geard RJ, Hassouna HI. Interaction of protamine sulfate with thrombin. Am J Hematol 1983; 14 (03) 227-233
- 20 Van Ryn-McKenna J, Cai L, Ofosu FA, Hirsh J, Buchanan MR. Neutralization of enoxaparine-induced bleeding by protamine sulfate. Thromb Haemost 1990; 63 (02) 271-274
- 21 Preul MC, Campbell PK, Bichard WD, Spetzler RF. Application of a hydrogel sealant improves watertight closures of duraplasty onlay grafts in a canine craniotomy model. J Neurosurg 2007; 107 (03) 642-650
- 22 Hu J, Zeng S, Wang Z, Chen Q, Shi Y, Wu Y. Nursing Observation of Improved Administration Route Proteamine Sulfate Neutralizing Heparin. Hindawi Journal Of Healthcare Engineering 2023, 1–5
- 23 Dlouhy BJ, Menezes AH. Autologous cervical fascia duraplasty in 123 children and adults with Chiari malformation type I: surgical technique and complications. J Neurosurg Pediatr 2018; 22 (03) 297-305
- 24 Ross MH, Romrell LJ, Kaye GI. Composition of basal laminae includes at least five substances. Eds: Coryel PA. Histology A Tex and Atlas. 64–65: 1995
- 25 Martin KD, Franz B, Kirsch M. et al. Autologous bone flap cranioplasty following decompressive craniectomy is combined with a high complication rate in pediatric traumatic brain injury patients. Acta Neurochir (Wien) 2014; 156 (04) 813-824
- 26 Deng K, Yang Y, Ke Y. et al. A novel biomimetic composite substitute of PLL/ gelatin nanofiber membrane for dura repairing, Neurological Research A. J Progress Neurosurg. Neurol Neurosci 2017; 39 (09) 819-829
- 27 Kurpinski K, Patel S. Dura mater regeneration with a novel synthetic, bilayered nanofibrous dural substitute: an experimental study. Nanomedicine (Lond) 2011; 6 (02) 325-337
- 28 Banks ND, Redett RJ. Dural repair with grafts using the gastrointestinal anastomosis stapler. J Craniofac Surg 2008; 19 (04) 1053-1055
- 29 Narayan P, Mapstone TB. Dorsaly exophytic brain stem gliomas. Textbook Neuro Oncology; Elsevier Philadelphia: 2005: 634-637