Jackson cross cylinder
Jackson cross cylinder of power +/- 0.50 diopter
Test ofAstigmatism
Based oncircle of confusion

The Jackson cross cylinder (JCC) is an instrument used by ophthalmologists, orthoptists and optometrists in their routine eye examination, particularly in determination of corrective lens power in patients with astigmatism. It is also used for testing near point of the eye.

Instrument

Jackson cross cylinder of +/- 0.25 diopter

Jackson cross cylinder is a single low power lens, which is a combination of a plus cylinder and a minus cylinder of equal power with axis perpendicular to each other, with a handle placed between the two axes at 45 degrees.[1][2] Therefore JCC is a spherocylindrical lens in which the power of the cylinder is double the power of the sphere and of opposite sign e.g. +0.5DS/-1.0DC or +0.25DS/-0.5DC. JCC are available in different powers including +/-1.00, most commonly used are of +/- 0.25 and +/- 0.50.[2] There are dots or lines to indicate axis of minus and plus powers.

Indications

The Jackson cross cylinder is used to determine corrective lens power and its axis in patients with astigmatism. It is also used for testing near point of the eye.

Procedure

Best corrected vision with a spherical lens should be identified before using a Jackson cross cylinder. In case of astigmatism the best vision with a spherical lens is obtained when the circle of confusion is on the retina.[3]

Detecting astigmatism

Best corrected vision with a spherical lens should be identified first. The JCC lens is then placed over spherical lens first with the minus-cylinder axis at 180°, and then with the axis at 90°.[4] If there is no difference in vision, repeat the test with JCC lens axis 45° and 135°.[4] If the patient again reports no difference in vision, there is no astigmatism and if there is improvement in either positions cylindrical lens should be tried to correct astigmatism.[4]

Refinement of axis

Refinement of axis of cylindrical lens in astigmatism correction is done by placing JCC along with corrective lens with the handle parallel to the axis of corrective lens in the trial frame.[2] Handle is rotated so that the minus and plus lens in cross cylinder interchanges. If there is no difference in vision in either position, the axis of corrective lens is correct and if there is difference in vision, axis should be rotated to get a clear vision. Axis should be rotated by 5 degree on better side.[2]

Refinement of power

Refinement of power of cylindrical lens in astigmatism correction is done by placing JCC along with corrective lens with the axis of JCC power parallel to the axis of corrective lens in the trial frame. Handle is rotated so that the minus and plus lens in cross cylinder interchanges and if there is no difference in vision in either position, the power of corrective lens is correct and if there is difference in vision, power should be adjusted.[2]

Near point of accommodation

The uniocular and binocular cross cylinder findings at 40 cm give information about near point of accommodation and near addition needed to correct presbyopia.[5]

History

In 1837, English mathematician and astronomer George Biddell Airy invented the cylindrical lens and used it to correct astigmatism.[6] In 1849, Irish English physicist and mathematician George Stokes invented Stokes lens to diagnose astigmatism.[6] This lens consisted of two cylindrical lenses, one plano-convex and one plano-concave, which be rotated in opposite directions. In 1887 Edward Jackson described the use of modified Stokes' lens in detecting astigmatism, and in 1907 he described the determination of the axis of a correcting cylinder in astigmatism using a cross cylinder.[7] The modified cross cylinder lens with a handle, which he used was later known as Jackson cross cylinder.[8][5]

References

  1. Elliott, David. B (2014). Clinical procedures in primary eye care (Fourth ed.). Philadelphia, Pennsylvania: Elsevier. pp. 86–90. ISBN 978-0-7020-5284-2.
  2. 1 2 3 4 5 Khurana, A. K. (2018). "Clinical Refraction:Determination of Errors of Refraction". Theory And Practice Of Optics And Refraction (Fourth ed.). Elsevier. p. 158. ISBN 9788131249154.
  3. "Subjective Cylinder Refraction". Eyedocs.
  4. 1 2 3 Elkington, A. R. (1999). Clinical optics. Helena J. Frank, Michael J. Greaney (3rd ed.). Malden, Mass.: Blackwell Science. p. 73. ISBN 0-632-06206-1. OCLC 47009603.
  5. 1 2 Makgaba, Nkalebetja T.; Mathebula, Solani D. (30 September 2020). "Investigation of the unfused cross cylinder test as an alternative method for the determination of spherical distance refraction end points". African Vision and Eye Health. 79 (1): 5. doi:10.4102/aveh.v79i1.514. ISSN 2410-1516. S2CID 224991918.
  6. 1 2 Wunsh, Stuart E. (10 July 2016). "The Cross Cylinder". Ento Key.
  7. Newell, F. W. (April 1988). "Edward Jackson, MD--a historical perspective of his contributions to refraction and to ophthalmology". Ophthalmology. 95 (4): 555–558. doi:10.1016/s0161-6420(88)33158-1. ISSN 0161-6420. PMID 3050696.
  8. Priors, Lucian V. Del; Guyton, David L. (1 November 1986). "The Jackson Cross Cylinder: A Reappraisal". Ophthalmology. 93 (11): 1461–1465. doi:10.1016/S0161-6420(86)33545-0. ISSN 0161-6420. PMID 3808608.
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