Present Status of Reliability Research on the Effects of Medical Instrument at the Instrument-tissue Interface_Journal of Biomedical Engineering

Authors：

LIWeizheng , WANGGuohui , TANJuan , ZHULiyong , LIPengzhou ,  ZHUShaihong

Department of General Surgery, Xiangya Third Hospital of Central South University, Changsha 410013, China;

Corresponding author：

ZHUShaihong, Email: zhushaihong@medmail.com.cn

Keywords：

instrument-tissue interface; reliability; minimally invasive surgery; biomechanics

DOI：

10.7507/1001-5515.20150126

Video：

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Abstract Full text Figures/Tables Video References Cited by

The interaction between medical instrument and target tissue during the surgery occurs in instrument-tissue interface. The reliability research on the interface is directly related to the safety and effectiveness of medical instrument in the clinical application. This paper illustrates the necessity of reliability research on instrument-tissue interface. Two main contents are synthetically reviewed the present paper: (1) reliability research on medical instruments; (2) biological tissue properties and its mechanical response.

Citation： LIWeizheng, WANGGuohui, TANJuan, ZHULiyong, LIPengzhou, ZHUShaihong. Present Status of Reliability Research on the Effects of Medical Instrument at the Instrument-tissue Interface. Journal of Biomedical Engineering, 2015, 32(3): 693-696. doi: 10.7507/1001-5515.20150126 Copy

1.	SWAIN C P, BALLY K, PARK P O, et al. New methods for innovation:the development of a toolbox for natural orifice translumenal endoscopic surgery (NOTES) procedures[J]. Surg Endosc, 2012, 26(4):1010-1020.
2.	AUTORINO R, CADEDDU J A, DESAI M M, et al. Laparoendoscopic single-site and natural orifice transluminal endoscopic surgery in urology:a critical analysis of the literature[J]. Eur Urol, 2011, 59(1):26-45.
3.	RANE A, AUTORINO R. Robotic natural orifice translumenal endoscopic surgery and laparoendoscopic single-site surgery:current status[J]. Curr Opin Urol, 2011, 21(1):71-77.
4.	TSIAMOULOS Z P, SAUNDERS B P. A new accessory, endoscopic cuff, improves colonoscopic access for complex polyp resection and scar assessment in the sigmoid colon (with video)[J]. Gastrointest Endosc, 2012, 76(6):1242-1245.
5.	THUIJLS G, VAN WIJCK K, GROOTJANS J, et al. Early diagnosis of intestinal ischemia using urinary and plasma fatty acid binding proteins[J]. Ann Surg, 2011, 253(2):303-308.
6.	SHI H, WU B Y, LIU W H, et al. The value of serum intestinal fatty acid binding protein measurement in discriminating intestinal ischemia in patients with acute abdomen[J]. Zhonghua Nei Ke Za Zhi, 2012, 51(9):690-693.
7.	VONCK D, GOOSSENS R H, VAN EIJK D J, et al. Vacuum grasping as a manipulation technique for minimally invasive surgery[J]. Surg Endosc, 2010, 24(10):2418-2423.
8.	CHO S B, LEE W S, JOO Y E, et al. Therapeutic options for iatrogenic colon perforation:feasibility of endoscopic clip closure and predictors of the need for early surgery[J]. Surg Endosc, 2012, 26(2):473-479.
9.	YUICHI K, TOSHIO T, TOMOHIRO K, et al. Force-based automatic classification of basic manipulations with grasping forceps[J]. Int J Life Sci Med Res, 2013, 4(2):75-81.
10.	DOBBELSTEEN J J, LEE R A, NOORDEN M V, et al. Indirect measurement of pinch and pull forces at the shaft of laparoscopic graspers[J]. Med Biol Eng Comput, 2012, 50(3):215-221.
11.	VONCK D, JAKIMOWICZ J J, LOPUHAÄ H P, et al. Grasping soft tissue by means of vacuum technique[J]. Med Eng Phys, 2012, 34(8):1088-1094.
12.	DE VISSER H, HEIJNSDIJK E A, HERDER J L, et al. Forces and displacements in colon surgery[J]. Surg Endosc, 2002, 16(10):1426-1430.
13.	VAN DER PUTTEN E W, HAJIAN M, GOOSSENS R, et al. A laparoscopic grasper handle with integrated augmented tactile feedback, designed for training grasp control[J]. Eurohaptics, 2010(6192):243-250.
14.	YOSHIDA K, KINOSHITA H, KURODA Y, et al. Analysis of laparoscopic dissection skill by instrument tip force measurement[J]. Surg Endosc, 2013, 27(6):2193-2200.
15.	HOREMAN T, KURTEVA D D KURTEVA D D, VALDASTRI P, et al. The influence of instrument configuration on tissue handling force in laparoscopy[J]. Surg Innov, 2013, 20(3):260-267.
16.	WOTTAWA C R, COHEN J R, FAN R E, et al. The role of tactile feedback in grip force during laparoscopic training tasks[J]. Surg Endosc, 2013, 27(4):1111-1118.
17.	MARUCCI D D, CARTMILL J A, WALSH W R, et al. Patterns of failure at the instrument-tissue interface[J]. J Surg Res, 2000, 93(1):16-20.
18.	HEIJNSDIJK E A, KRAGTEN G A, MUGGE W, et al. Fenestrations in the Jaws of laparoscopic graspers[J]. Minim Invasive Ther Allied Technol, 2005, 14(1):45-48.
19.	BIANCHI G, PUCCI A, MATTEUCCI M, et al. Mechanical properties and biological interaction of aortic clamps:are these all minimally invasive?[J]. Innovations (Phila), 2013, 8(1):42-49.
20.	HEIJNSDIJK E A, VAN DER VOORT M, DE VISSER H, et al. Inter-and intraindividual variabilities of perforation forces of human and pig bowel tissue[J]. Surg Endosc, 2003, 17(12):1923-1926.
21.	BOURGOUIN S, BÈGE T, MASSON C, et al. Biomechanical characterisation of fresh and cadaverous human small intestine:applications for abdominal trauma[J]. Med Biol Eng Comput, 2012, 50(12):1279-1288.
22.	GREGERSEN H, JIANG W, LIAO D, et al. Evidence for stress-dependent mechanoreceptors linking intestinal biomechanics and sensory signal transduction[J]. Exp Physiol, 2013, 98(1):123-133.
23.	ZHAO J, LIAO D, YANG J, et al. Stress and strain analysis of contractions during ramp distension in partially obstructed Guinea pig jejunal segments[J]. J Biomech, 2011, 44(11):2077-2082.
24.	KANDALAM V, BASU R, MOORE L, et al. Lack of tissue inhibitor of metalloproteinases 2 leads to exacerbated left ventricular dysfunction and adverse extracellular matrix remodeling in response to biomechanical stress[J]. Circulation, 2011, 124(19):2094-2105.
25.	NOVÁ AČU EK V, TRAN T N, KLINGE U, et al. Finite element modelling of stapled colorectal end-to-end anastomosis:advantages of variable height stapler design[J]. J Biomech, 2012, 45(15):2693-2697.
26.	YANG J, SOLTZ M, RUSSELL H, et al. Surface deformation analysis of end-to-end stapled intestinal anastomosis[J]. Surg Innov, 2012, 19(3):281-287.
27.	CHEN W, KE Q, HE S, et al. Experimental research on anchoring force in intestine for the motion of capsule robot[J]. J Med Eng Technol, 2013, 37(5):334-341.
28.	LEONG F, HUANG W H, CHUI C K. Modeling and analysis of coagulated liver tissue and its interaction with a scalpel blade[J]. Med Biol Eng Comput, 2013, 51(6):687-695.
29.	PAN J J, CHANG J, YANG X, et al. Graphic and haptic simulation system for virtual laparoscopic rectum surgery[J]. Int J Med Robot, 2011, 7:304-317.
30.	COSTA I F. A novel deformation method for fast simulation of biological tissue formed by fibers and fluid[J]. Med Image Anal, 2012, 16(5):1038-1046.

1. SWAIN C P, BALLY K, PARK P O, et al. New methods for innovation:the development of a toolbox for natural orifice translumenal endoscopic surgery (NOTES) procedures[J]. Surg Endosc, 2012, 26(4):1010-1020.
2. AUTORINO R, CADEDDU J A, DESAI M M, et al. Laparoendoscopic single-site and natural orifice transluminal endoscopic surgery in urology:a critical analysis of the literature[J]. Eur Urol, 2011, 59(1):26-45.
3. RANE A, AUTORINO R. Robotic natural orifice translumenal endoscopic surgery and laparoendoscopic single-site surgery:current status[J]. Curr Opin Urol, 2011, 21(1):71-77.
4. TSIAMOULOS Z P, SAUNDERS B P. A new accessory, endoscopic cuff, improves colonoscopic access for complex polyp resection and scar assessment in the sigmoid colon (with video)[J]. Gastrointest Endosc, 2012, 76(6):1242-1245.
5. THUIJLS G, VAN WIJCK K, GROOTJANS J, et al. Early diagnosis of intestinal ischemia using urinary and plasma fatty acid binding proteins[J]. Ann Surg, 2011, 253(2):303-308.
6. SHI H, WU B Y, LIU W H, et al. The value of serum intestinal fatty acid binding protein measurement in discriminating intestinal ischemia in patients with acute abdomen[J]. Zhonghua Nei Ke Za Zhi, 2012, 51(9):690-693.
7. VONCK D, GOOSSENS R H, VAN EIJK D J, et al. Vacuum grasping as a manipulation technique for minimally invasive surgery[J]. Surg Endosc, 2010, 24(10):2418-2423.
8. CHO S B, LEE W S, JOO Y E, et al. Therapeutic options for iatrogenic colon perforation:feasibility of endoscopic clip closure and predictors of the need for early surgery[J]. Surg Endosc, 2012, 26(2):473-479.
9. YUICHI K, TOSHIO T, TOMOHIRO K, et al. Force-based automatic classification of basic manipulations with grasping forceps[J]. Int J Life Sci Med Res, 2013, 4(2):75-81.
10. DOBBELSTEEN J J, LEE R A, NOORDEN M V, et al. Indirect measurement of pinch and pull forces at the shaft of laparoscopic graspers[J]. Med Biol Eng Comput, 2012, 50(3):215-221.
11. VONCK D, JAKIMOWICZ J J, LOPUHAÄ H P, et al. Grasping soft tissue by means of vacuum technique[J]. Med Eng Phys, 2012, 34(8):1088-1094.
12. DE VISSER H, HEIJNSDIJK E A, HERDER J L, et al. Forces and displacements in colon surgery[J]. Surg Endosc, 2002, 16(10):1426-1430.
13. VAN DER PUTTEN E W, HAJIAN M, GOOSSENS R, et al. A laparoscopic grasper handle with integrated augmented tactile feedback, designed for training grasp control[J]. Eurohaptics, 2010(6192):243-250.
14. YOSHIDA K, KINOSHITA H, KURODA Y, et al. Analysis of laparoscopic dissection skill by instrument tip force measurement[J]. Surg Endosc, 2013, 27(6):2193-2200.
15. HOREMAN T, KURTEVA D D KURTEVA D D, VALDASTRI P, et al. The influence of instrument configuration on tissue handling force in laparoscopy[J]. Surg Innov, 2013, 20(3):260-267.
16. WOTTAWA C R, COHEN J R, FAN R E, et al. The role of tactile feedback in grip force during laparoscopic training tasks[J]. Surg Endosc, 2013, 27(4):1111-1118.
17. MARUCCI D D, CARTMILL J A, WALSH W R, et al. Patterns of failure at the instrument-tissue interface[J]. J Surg Res, 2000, 93(1):16-20.
18. HEIJNSDIJK E A, KRAGTEN G A, MUGGE W, et al. Fenestrations in the Jaws of laparoscopic graspers[J]. Minim Invasive Ther Allied Technol, 2005, 14(1):45-48.
19. BIANCHI G, PUCCI A, MATTEUCCI M, et al. Mechanical properties and biological interaction of aortic clamps:are these all minimally invasive?[J]. Innovations (Phila), 2013, 8(1):42-49.
20. HEIJNSDIJK E A, VAN DER VOORT M, DE VISSER H, et al. Inter-and intraindividual variabilities of perforation forces of human and pig bowel tissue[J]. Surg Endosc, 2003, 17(12):1923-1926.
21. BOURGOUIN S, BÈGE T, MASSON C, et al. Biomechanical characterisation of fresh and cadaverous human small intestine:applications for abdominal trauma[J]. Med Biol Eng Comput, 2012, 50(12):1279-1288.
22. GREGERSEN H, JIANG W, LIAO D, et al. Evidence for stress-dependent mechanoreceptors linking intestinal biomechanics and sensory signal transduction[J]. Exp Physiol, 2013, 98(1):123-133.
23. ZHAO J, LIAO D, YANG J, et al. Stress and strain analysis of contractions during ramp distension in partially obstructed Guinea pig jejunal segments[J]. J Biomech, 2011, 44(11):2077-2082.
24. KANDALAM V, BASU R, MOORE L, et al. Lack of tissue inhibitor of metalloproteinases 2 leads to exacerbated left ventricular dysfunction and adverse extracellular matrix remodeling in response to biomechanical stress[J]. Circulation, 2011, 124(19):2094-2105.
25. NOVÁ AČU EK V, TRAN T N, KLINGE U, et al. Finite element modelling of stapled colorectal end-to-end anastomosis:advantages of variable height stapler design[J]. J Biomech, 2012, 45(15):2693-2697.
26. YANG J, SOLTZ M, RUSSELL H, et al. Surface deformation analysis of end-to-end stapled intestinal anastomosis[J]. Surg Innov, 2012, 19(3):281-287.
27. CHEN W, KE Q, HE S, et al. Experimental research on anchoring force in intestine for the motion of capsule robot[J]. J Med Eng Technol, 2013, 37(5):334-341.
28. LEONG F, HUANG W H, CHUI C K. Modeling and analysis of coagulated liver tissue and its interaction with a scalpel blade[J]. Med Biol Eng Comput, 2013, 51(6):687-695.
29. PAN J J, CHANG J, YANG X, et al. Graphic and haptic simulation system for virtual laparoscopic rectum surgery[J]. Int J Med Robot, 2011, 7:304-317.
30. COSTA I F. A novel deformation method for fast simulation of biological tissue formed by fibers and fluid[J]. Med Image Anal, 2012, 16(5):1038-1046.

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