Comparison of Five Different Abdominal Access Trocar Systems: Analysis of Insertion Force,Removal Force,and Defect Size

Abstract

Trocar designs have evolved in response to concerns about complication rates and surgical ergonomics. Functional properties of trocar systems that can be objectively measured include insertion force, removal force and the size of the tissue defect. This study will evaluate these properties in 5 common trocar designs. A porcine model was used to evaluate five different trocar systems for insertion force, removal force, and functional and measured tissue defect. Insertion force was lowest for cutting trocars and highest for radially dilating trocars. Removal force was similar for all trocars. Functional and measured tissue defect size was smallest for the hybrid type and radially dilating trocars. An ideal trocar system incorporates a low insertion force, secure retention, and a minimal tissue defect. Of the systems we tested, the hybrid type trocar has similar wound characteristics to the radially dilating trocar with the benefit of reduced insertion force. Further study is required to determine if these properties translate to an actual improvement in patient outcome.

Keywords

Laparoscopic trocar abdomen defect force port hernia

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References

Azurin DJ , Go LS , Arroyo LR , Kirkland MC. Trocar site herniation following laparoscopic cholecystectomy and the significance of incidental umbilical hernias. Am Surg. 1995;61: 718-720.

Champault G , Cazacu F , Taffinder N. Serious trocar accidents in laparoscopic surgery: a French survey of 103,852 operations. Surg Laparoscop Endosc. 1996;6: 367-370.

Unger SW , George JP. Presentation and management of laparoscopic incisional hernia. J Am Assoc Gynecol Laparasc. 1994;1: S12-S12.

Bhoyrul S , Vierra MA , Nezhat CR , Krummel TM , Way LW. Trocar injuries in laparoscopic surgery. J Am Coll Surg. 2001;192: 677-683.

Bhoyrul S , Mori T , Way LW. Radially expanding dilatation: a superior method of laparoscopic trocar access. Surg Endosc. 1996;10: 775-778.

Galen DI , Jacobsen A , Weckstein LM , Kaplan RA , DeNevi KC. Reduction of cannula related complications using a radially expanding access device. J Am Assoc Gynecol Lap. 1996;6: 79-84.

Lam TY , Lee SW , So HS , Kwok SP. Radially expanding trocar: a less painful alternative for laparoscopic surgery. J Laparoendo Adv Surg Tech. 2000;10(5): 269-273.

Yim SF , Yuen PM. Randomized double-masked comparison of radially expanding access device and conventional cutting tip trocar in laparoscopy. Obstet Gynecol. 2001; 97: 435-438.

Philips PA , Amaral JF. Abdominal access complications in laparoscopic surgery. J Am Coll Surg. 2001;192(4): 525-536.

10.

Hurd WW , Wang L , Schmmel MT. A comparison of the relative risk of vessel injury with conical versus pyramidal laparoscopic trocars in a rabbit model. Am J Obstet Gynecol. 1995;173: 1731-1733.

11.

Böhm B , Knigge M , Kraft M , Grundel K , Boernick U. Influence of different trocar tips on abdominal wall penetration during laparoscopy. Surg Endosc. 1998;12: 1434-1438.

12.

Tarnay CM , Glass KB , Munro MG.

Incision characteristics associated with six laparoscopic trocar-cannula systems: a randomized comparison

Obstet Gynecol. 1999;94: 89-93.

13.

Turner DJ. A new radially expanding access system for laparoscopic procedures vs. conventional cannulas. J Am Assoc Gynecol Laparosc. 1996;3: 608-615.

14.

Apelgren KN.

Are radially dilating trocars better than the alternatives?

Surg Endosc. 2000;14: 317-317.

15.

Tarnay CM , Glass KB , Munro MG.

Entry force and intra abdominal pressure associated with six laparoscopic trocar-cannula systems: a randomized comparison

Obstet Gynecol. 1999;94: 83-88.