| Q38665118 | A Randomized Trial of Soft Multifocal Contact Lenses for Myopia Control: Baseline Data and Methods |
| Q89101188 | A Review of Current Concepts of the Etiology and Treatment of Myopia |
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| Q51065654 | Accommodation and Phoria in Children Wearing Multifocal Contact Lenses. |
| Q101038748 | Additive effect of atropine eye drops and short-term retinal defocus on choroidal thickness in children with myopia |
| Q36417347 | Adverse events during 2 years of daily wear of silicone hydrogels in children. |
| Q41231876 | Analysis of the power profile of a new soft contact lens for myopia progression |
| Q38719533 | Astigmatic Peripheral Defocus with Different Contact Lenses: Review and Meta-Analysis |
| Q34406069 | Axial eye growth and refractive error development can be modified by exposing the peripheral retina to relative myopic or hyperopic defocus |
| Q91693863 | Bifocal & Atropine in Myopia Study: Baseline Data and Methods |
| Q92134118 | Bifocal and Multifocal Contact Lenses for Presbyopia and Myopia Control |
| Q38635054 | Centration and Decentration of Contact Lenses during Peripheral Gaze |
| Q90472021 | Changing accommodation behaviour during multifocal soft contact lens wear using auditory biofeedback training |
| Q27001108 | Clinical management of progressive myopia |
| Q54959248 | Comparison of myopia control between toric and spherical periphery design orthokeratology in myopic children with moderate-to-high corneal astigmatism. |
| Q30372541 | Concise Review: Using Stem Cells to Prevent the Progression of Myopia-A Concept |
| Q53769957 | Contact lenses to slow progression of myopia. |
| Q26796398 | Controlling myopia progression in children and adolescents |
| Q36766574 | Coordinated genetic scaling of the human eye: shared determination of axial eye length and corneal curvature |
| Q35784870 | Corneal and crystalline lens dimensions before and after myopia onset |
| Q51378092 | Corneal parameters of six- to 12-year-old Chinese children. |
| Q48685375 | Current recommendations for deceleration of myopia progression |
| Q92380001 | Defocus Incorporated Multiple Segments (DIMS) spectacle lenses slow myopia progression: a 2-year randomised clinical trial |
| Q34381022 | Defocus Incorporated Soft Contact (DISC) lens slows myopia progression in Hong Kong Chinese schoolchildren: a 2-year randomised clinical trial |
| Q41479374 | Does peripheral retinal input explain the promising myopia control effects of corneal reshaping therapy (CRT or ortho-K) & multifocal soft contact lenses? |
| Q60302902 | Effect of bilberry extract on slowing high-myopia progression in children: 2-year follow-up study |
| Q53492746 | Effect of retinal image defocus on the thickness of the human choroid. |
| Q39519385 | Effects of multifocal soft contact lenses used to slow myopia progression on quality of vision in young adults |
| Q57387531 | Evaluating the peripheral optical effect of multifocal contact lenses |
| Q47189631 | Experimental investigation of accommodation in eyes fit with multifocal contact lenses using a clinical auto-refractor |
| Q47388335 | Eye size and shape in newborn children and their relation to axial length and refraction at 3 years |
| Q48208922 | Identification of myopia-associated WNT7B polymorphisms provides insights into the mechanism underlying the development of myopia |
| Q58597206 | In-Vivo Evaluation of Peripheral Refraction Changes with Single Vision and Multifocal Soft Contact Lenses |
| Q41959417 | Integration of defocus by dual power Fresnel lenses inhibits myopia in the mammalian eye. |
| Q38976298 | Interventions to Reduce Myopia Progression in Children |
| Q24234516 | Interventions to slow progression of myopia in children |
| Q48112179 | MiSight Assessment Study Spain (MASS). A 2-year randomized clinical trial |
| Q27307990 | Micro-Fresnel-Zone-Plate Array on Flexible Substrate for Large Field-of-View and Focus Scanning |
| Q89656244 | Morphological ciliary muscle changes associated with form deprivation-induced myopia |
| Q56443024 | Myopia |
| Q36269769 | Myopia Control with a Novel Peripheral Gradient Soft Lens and Orthokeratology: A 2-Year Clinical Trial |
| Q92626228 | Myopia control with novel central and peripheral plus contact lenses and extended depth of focus contact lenses: 2 year results from a randomised clinical trial |
| Q47877218 | Myopia progression control lens reverses induced myopia in chicks. |
| Q30720148 | Myopia, an underrated global challenge to vision: where the current data takes us on myopia control |
| Q34425331 | Myopic anisometropia: ocular characteristics and aetiological considerations |
| Q51027092 | Neural adaptation to peripheral blur in myopes and emmetropes. |
| Q36648656 | Optical and neural anisotropy in peripheral vision |
| Q36842913 | Optical control of myopia has come of age: or has it? |
| Q38071761 | Optical treatment strategies to slow myopia progression: effects of the visual extent of the optical treatment zone |
| Q95266765 | Orthokeratology with increased compression factor (OKIC): study design and preliminary results |
| Q64991043 | Orthokeratology: clinical utility and patient perspectives. |
| Q91632312 | Pathogenesis and Prevention of Worsening Axial Elongation in Pathological Myopia |
| Q64053025 | Peripheral Refraction and Eye Lengths in Myopic Children in the Bifocal Lenses In Nearsighted Kids (BLINK) Study |
| Q37127582 | Peripheral defocus and myopia progression in myopic children randomly assigned to wear single vision and progressive addition lenses |
| Q37599618 | Peripheral defocus with spherical and multifocal soft contact lenses |
| Q36501604 | Peripheral optics with bifocal soft and corneal reshaping contact lenses |
| Q91647683 | Peripheral refraction and spherical aberration profiles with single vision, bifocal and multifocal soft contact lenses |
| Q49149961 | Peripheral refraction in myopia corrected with spectacles versus contact lenses |
| Q41893592 | Peripheral refraction with different designs of progressive soft contact lenses in myopes |
| Q37595078 | Practical applications to modify and control the development of ametropia. |
| Q36021593 | Prentice Award Lecture 2010: A case for peripheral optical treatment strategies for myopia |
| Q42364713 | Preventing Myopia |
| Q57063802 | Prevention of Progression in Myopia: A Systematic Review |
| Q35797279 | Protective effects of high ambient lighting on the development of form-deprivation myopia in rhesus monkeys |
| Q38536058 | Rate of change and predictive factors for increasing minus contact lens powers in young myopes |
| Q41368447 | Relationship between higher-order wavefront aberrations and natural progression of myopia in schoolchildren |
| Q61809493 | Retardation of Myopia Progression by Multifocal Soft Contact Lenses |
| Q36202737 | Studies using concentric ring bifocal and peripheral add multifocal contact lenses to slow myopia progression in school-aged children: a meta-analysis |
| Q27009158 | Temporal integration of visual signals in lens compensation (a review) |
| Q37161352 | The Effects of the Relative Strength of Simultaneous Competing Defocus Signals on Emmetropization in Infant Rhesus Monkeys |
| Q33760347 | The Safety of Soft Contact Lenses in Children |
| Q48871124 | The effect of fractal contact lenses on peripheral refraction in myopic model eyes. |
| Q36257898 | The effect of simultaneous negative and positive defocus on eye growth and development of refractive state in marmosets |
| Q36072945 | The effects of simultaneous dual focus lenses on refractive development in infant monkeys |
| Q88118523 | Visual Acuity and Over-refraction in Myopic Children Fitted with Soft Multifocal Contact Lenses |
| Q57496009 | Visual performance of myopia control soft contact lenses in non-presbyopic myopes |
| Q64974014 | Visual performance with multifocal soft contact lenses in non-presbyopic myopic eyes during an adaptation period. |
| Q84843108 | [Clinical risk factors for progressive myopia] |