Abstracts

INTRODUCTION

Cyclotorsions are movements of cyclorotation of the eyes⁽¹1 Spielmann A. [Cyclotorsions]. J Fr Ophtalmol. 2002;25(9):959-67. French.⁾. The cyclotorsion of the human eye occurs with movement of the head and body, changing the original position of the corneal axis. A significant different range of cyclotorsion between a lie and a supine position was previously reported as varying from 2 to 7 degrees⁽²2 Kim H, Joo CK. Ocular cyclotorsion according to body position and flap creation before laser in situ keratomileusis. J Cataract Refract Surg. 2008;34(4):557-61.⁾. The measurement of the rotation raised concern among refractive and cataract surgeons especially regarding astigmatism correction where a mistake in the position of the axis will lead to a significant impact in patients visual acuity.

Peribulbar block is one of the techniques for anesthesia for cataract surgery and is one of the most popular throughout the world because it is a safe procedure and it's able to warrant a cataract surgery with no pain⁽³3 Clausel H, Touffet L, Havaux M, Lamard M, Savean J, Cochener B, et al. [Peribulbar anesthesia: efficacy of a single injection with a limited local anesthetic volume]. J Fr Ophtalmol. 2008;31(8):781-5. French.⁾. The objective is not only the analgesia but also ocular akinesia during the surgical procedure. It is believed that after the peribulbar block, the torsional motion of the eye suffers distortions, which could result in consequences if not evaluated prior to surgery procedure⁽⁴4 Swami AU, Steinert RF, Osborne WE, White AA. Rotational malposition during laser in situ keratomileusis. Am J Ophthalmol. 2002;133(4):561-2.^,55 Chang J. Cyclotorsion during laser in situ keratomileusis. J Cataract Refract Surg. 2008;34(10):1720-6.⁾.

Toric intraocular lenses (IOLs) are spherocylindrical and correct for corneal astigmatism after cataract surgery. The orientation of the toric IOL in the capsular bag is critical because misalignment negates the desired effect of correcting astigmatism. If, for instance, a toric IOL rotates 30 degrees off the prescribed axis of alignment, there is virtually no correction of astigmatism; if it rotates more than 45 degrees from the prescribed axis, the IOL augments the preoperative ocular cylinder⁽⁶6 Novis C. Astigmatism and toric intraocular lenses. CurrOpinOphthalmol. 2000;11(1):47-50. Review.⁾.

The aim of this prospective study is to determine the amount of ocular cyclotorsion in lie positions after topical anethesia and peribulbar block.

METHODS

This prospective series of cases included 112 eyes of 112 patients. The study was approved by the ethical committee of University of São Paulo. Exclusion criteria were patients who showed any alteration in ocular extrinsic motility and patients with very shallow or deep orbit, abnormalities of their visual system and their stereopsis less than 40 seconds of arc. Strabismus (especially dissociated vertical divergence, DVD) and any organic eye disease were excluded by thorough ophthalmological examination including biomicroscopy, indirect ophthalmoscopy, refractometry or retinoscopy in cycloplegia, cover test, assessment of ocular motility, prism and cover test, verification of stable, central fixation by using the so called "Haidinger Büschel" and after image, determination of stereopsis by the Lang stereotest and the Titmus test. The nature of the study had been clearly explained and informed consent was obtained from all subjects before testing. The study follows the tenets of declaration of Helsinki.

Perilimbar mark was performed in the position of 180 degrees in right eye and zero degrees of left eye, with the patient seat down, in the immediately sequence requested that the patient lie down, and then a new dial in 180 and zero degrees respectively from right and left eye were made. The angle of rotation of the original mark was recorded after topical anesthesia.

After that, the block was performed with peribulbar infiltration of 5mL of anesthetics in access inferotemporal. New measures were taken in lying down position, always with reference to the initial marking in the supine position.

Statistical analysis was performed using SPSS for Windows (version 115, SPSS, Inc.). For statistical analysis of visual acuity, LogMAR values were used. Normality was checked using the Kolmogorov-Smirnov test.When parametric analysis was not possible the non-parametric Mann-Whitney U test was used to compare data between the two IOL groups. The analysis of primary outcome measures was based on a non-normal distribution of the data. When parametric analysis was possible, the Student's t-test was used to compare the outcomes. All the statistical tests have been conducted at an alpha level of 0.05.

RESULTS

This study evaluated 112 eyes of 112 patients and the measured cyclotorsional deviation in supine position, in patients with topical anesthesia was located around 6.89 degrees (82 eyes) of incyclotorsion and 6.93 (38 eyes) degrees of excyclotorsion, with a mean of cyclotorsion located around 6.91 degrees.

In patients with peribulbar block, the deviation were located around 5.68 degrees (73 eyes) of incyclotorsion and 4.81 degrees (47 eyes) of excyclotorsion and a mean of cyclotorsion of 4.92 degrees. (p=0.002).

Statistical analysis of the different test positions and anesthesia showed less positionaly induced incyclotorsion on patients with peribulbar block.

There were also no statistically significant difference between the topical anesthesia and peribulbar block on excyclotorsion (p=0.120).

DISCUSSION

In this prospective series of 112 consecutive cases we observed that the range of cyclotorsion (incyclotorsion) previously the block, in lie positions was 6.91±2.36 degrees. After the peribulbar block there was a decrease in the cyclotorsion, for 4.92±2.91degrees (p=0.002).

These results lead us to suggest that, despite the apparent akinesia achieved with the peribulbar block, the cyclotorsion persists and presents significant different values when compared to topical anesthesia. It is known that a rotation of 6 degrees can reduce the effect of an astigmatic correction by approximately_20%⁽²2 Kim H, Joo CK. Ocular cyclotorsion according to body position and flap creation before laser in situ keratomileusis. J Cataract Refract Surg. 2008;34(4):557-61.^,55 Chang J. Cyclotorsion during laser in situ keratomileusis. J Cataract Refract Surg. 2008;34(10):1720-6.).

Positional induced inexcyclotorsion could be an important factor concerning of astigmatism in refractive surgery. Before performing refractive and cataract surgery correcting astigmatism, the axis of astigmatism is usually measured in seated position, while the procedure of correction itself takes place in a supine position.

Positional induced inexcyclotorsion could be an important factor in the outcome of cataract and refractive surgery. Two possible mistakes with clinical significance may occur. Firstly, a simple difference of the axis of astigmatism between the sitting and supine position will lead not only to an erroneous correction of the astigmatism itself, but the whole spherocylindrical correction could be false⁽⁷7 Becker R, Krzizok TH,Wassill H. Use of preoperative assessment of positionally induced cyclotorsion: a video-oculographic study. Br J Ophthalmol. 2004;88(3):417-21.⁾.

The refractive outcome of the cylinder correction depends on the accuracy of the axis treatment. For example, a 10-degree axis shift decreases the efficiency of the desired cylinder correction by more than 30%. Even minimal meridional errors can have significant negative refractive consequences, particularly in cases of moderate to high astigmatism⁽⁸8 Febbraro JL, Aron-Rosa D, Gross M, Aron B, Brémond-Gignac D. One year clinical results of photoastigmatic refractive keratectomy for compound myopic astigmatism. J Cataract Refract Surg. 1999;25(7):911-20.⁾.

Febbraro et al. also evaluated cyclorotationand found that the mean static of cyclotorsionin their study was 3.08 +/ - 2.68 degrees, which was statistically significant greater than 0 degrees. The cyclotorsion was less than 5 degrees in 53 eyes (71%), 5 to 9 degrees in 19 eyes (26%) and 10 degrees or more in 2 eyes (3%). Incyclotorsion appeared in 22 eyes (31%) and the mean of rotation was 2.9 degrees. Excyclotorsion ocurred in 42 eyes (60%) and the mean was 3.6 degrees. There were no cyclotorsion in 6 eyes⁽⁹9 Febbraro JL, Koch DD, Khan HN, Saad A, Gatinel D. Detection of static cyclotorsion and compensation for dynamic cyclotorsion in laser in situ keratomileusis. J Cataract Refract Surg. 2010;36(10):1718-23.⁾.

Postural changes, such as moving from an upright to a supine position, can induce a mean ocular cyclotorsional effect of 0.4 to 4.2 degrees (range 0 to 16 de- grees)⁽¹⁰10 Swami AU, Steinert RF, Osborne WE, White AA. Rotational malposition during laser in situ keratomileusis. Am J Ophthalmol. 2002;133(4):561-2.^,1111 Smith EM Jr, Talamo JH, Assil KK, Petashnick DE. Comparison of astigmatic axis in the seated and supine positions. J Refract Corneal Surg. 1994;10(6):615-20.⁾,and this effect can be incyclotorsional or excylcotorsional⁽¹⁰10 Swami AU, Steinert RF, Osborne WE, White AA. Rotational malposition during laser in situ keratomileusis. Am J Ophthalmol. 2002;133(4):561-2.⁾. However, keratometry is typically recorded with the patient upright, whereas ocular surgery is performed with the patient supine. As a consequence, it has been recommended that preoperative corneal markings of the 0- to 180-degree meridian using specifically designed instruments should be made with the patient upright and that the markings should then be aligned with the 0- to 180-degree meridian of a fixation ring with the patient supine, from which the meridian of the toric IOL to be implanted is marked with a meridian marker.

In conclusion, cyclotorsion represents another potential source of residual refractive errors that subsequently will lead to a reduced visual quality postoperatively. Therefore should be carefully taken into account in the preoperative analyses.

REFERÊNCIAS

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