Abstract
References
- 1. Altunrende ME, Hamamcioglu MK, Hicdonmez T, Akcakaya MO, Birgili B, Cobanoglu S: Microsurgical training model for residents to approach to the orbit and the optic nerve in fresh cadaveric sheep cranium. J Neurosci Rural Pract 5:151-154, 2014
- 2. Belykh E, Byvaltsev V: Off-the-job microsurgical training on dry models: Siberian experience. World Neurosurg 82: 20-24, 2014
- 3. Spetzger U, von Schilling A, Brombach T, Winkler G: Training models for vascular microneurosurgery. Acta Neurochir Suppl 112:115-119, 2011
- 4. Yadav YR, Parihar V, Ratre S, Kher Y, Iqbal M: Microneurosurgical Skills Training: J Neurol Surg A Cent Eur Neurosurg 77:146-154, 2016
- 5. Turan Suslu H, Ceylan D, Tatarlı N, et al. Laboratory training in the retrosigmoid approach using cadaveric silicone injected cow brain. Br J Neurosurg 27: 812-814, 2013
Evaluating the Histopathological and Mechanical Effects Of a New Forceps Design: Comparison of Hemispheric Bipolar Forceps Tip with Usual Bipolar Tip on Fresh Cadaver Cattle Brain Model
Abstract
Abstract
Background
Without electrocautery, many modern surgical interventions are practically impossible. In neurosurgery, bipolar cautery forceps has been evolved to not only an auxiliary, but a principal instrument wielded by the dominant hand of the surgeon to navigate through the most delicate tissue that there is.
Objective
The purpose of this study is to introduce our original bipolar forceps designed exclusively for microneurosurgical interventions and compare its feasibility with a standard bipolar forceps tip.
Material and method
This study has been conducted on two fresh cadaveric cow brains under the operating microscope. The coagulative and ablative effects of the hemispheric bipolar forceps tip (HBFT) have been histologically compared with those of the standard bipolar forceps tip (SBFT). Likewise, their efficacies as a dissection instruments have been compared via performing dissections from the parietal surface down to the corpus callosum.
Results
HBFT proved less traumatic to the uninvolved brain tissue during dissection. Also, histological analyses have revealed that ablative effects of the HBFT are more confined to the bleeding point, more effectively sparing the uninvolved brain tissue.
Conclusion:
Results of this experimental study suggest that HBFT is a better instrument to be used in microneurosurgical interventions, along with other surgical disciplines where selective diathermy is critical.
References
- 1. Altunrende ME, Hamamcioglu MK, Hicdonmez T, Akcakaya MO, Birgili B, Cobanoglu S: Microsurgical training model for residents to approach to the orbit and the optic nerve in fresh cadaveric sheep cranium. J Neurosci Rural Pract 5:151-154, 2014
- 2. Belykh E, Byvaltsev V: Off-the-job microsurgical training on dry models: Siberian experience. World Neurosurg 82: 20-24, 2014
- 3. Spetzger U, von Schilling A, Brombach T, Winkler G: Training models for vascular microneurosurgery. Acta Neurochir Suppl 112:115-119, 2011
- 4. Yadav YR, Parihar V, Ratre S, Kher Y, Iqbal M: Microneurosurgical Skills Training: J Neurol Surg A Cent Eur Neurosurg 77:146-154, 2016
- 5. Turan Suslu H, Ceylan D, Tatarlı N, et al. Laboratory training in the retrosigmoid approach using cadaveric silicone injected cow brain. Br J Neurosurg 27: 812-814, 2013
Details
| Primary Language | English |
|---|---|
| Subjects | Health Care Administration |
| Journal Section | Clinical Research |
| Authors | |
| Publication Date | October 9, 2021 |
| Submission Date | March 5, 2021 |
| Acceptance Date | March 7, 2021 |
| Published in Issue | Year 2021 Volume: 38 Issue: 4 |
Cite
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