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Hyperbaric Oxygen Therapy and Associated Cataracts

Editor: Jeffrey S. Cooper Updated: 1/9/2024 12:48:11 AM

Introduction

Hyperbaric oxygen therapy (HBOT) involves the administration of 100% oxygen at pressures exceeding 1 atmosphere absolute (ATA) for therapeutic purposes. A rare but potentially overlooked adverse effect of HBOT is the development of cataracts, which involves clouding of the eye's lens. This condition leads to significant loss of visual acuity and may progress to incapacitating blindness. Nuclear cataracts are the most prevalent type of cataracts that affect the central part of the lens and are commonly found in older populations. Although the exact cause of cataracts is not fully understood, recent evidence indicates that prolonged exposure to oxygen throughout one's lifetime is a primary contributing factor. This is particularly relevant when it comes to the increased partial pressure of oxygen that reaches the lens as the vitreous humor deteriorates with age.[1][2]

Excessive exposure to HBOT sessions beyond the average duration of 20 to 50 sessions may increase the risk of permanent lenticular changes in the eye, such as cataracts. Experts attribute the presence of nuclear cataracts and a reversible myopic shift or negative change in refraction in patients undergoing HBOT to the likely cause of oxidative damage to the crystalline lens proteins. In an experiment involving guinea pigs exposed to hyperbaric oxygen, the average apparent diameter of proteins in the lens nucleus of animals treated with HBOT is almost double that of the control animals.[2][3][4] These findings are similar to the aggregates identified in human nuclear cataracts.

Researchers have linked many reported symptoms to oxygen toxicity of the lens, which can cause myopia and the development and progression of cataracts. Commonly reported symptoms include eyelid twitching, blurry vision, and visual-field disturbances. Researchers believe that molecular oxygen in vivo induces the cross-linking of lens nuclear crystallins into large disulfide-bonded aggregates capable of scattering light. A similar process may be involved in forming human nuclear cataracts and could represent the end-stage of the frequently reported "myopic shift" observed in most patients undergoing 20 to 30 HBOTs.[2][4]  Although myopia changes are usually reversible within days to months after therapy cessation, the development of cataracts is generally permanent and might necessitate lens replacement surgery.

Etiology

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Etiology

The exact cause of cataracts is not fully understood and is believed to be influenced by multiple factors. As individuals age, the lens undergoes changes, and patients experience increased amounts of oxidative damage to the lens over time.

  • The weight and thickness of the lens increase, accompanied by a reduction in its accommodative power.
  • Nuclear sclerosis occurs as new cortical layers are added, leading to the compression and hardening of the central nucleus.
  • The diminished transparency of the lens is attributed to a decrease in lens epithelial cell density and aberrant differentiation of lens fiber cells.
  • The rate at which water and potentially water-soluble low-molecular-weight metabolites can enter the cells of the lens nucleus via the epithelium and cortex decreases, leading to a subsequent reduction in the transport rate of water, nutrients, and antioxidants.
  • Recent evidence suggests that the lifetime exposure to oxygen, and, particularly, the increased partial pressure of oxygen that reaches the lens with increasing age, are significant contributing factors to the development of cataracts. The patients undergoing HBOT develop nuclear cataracts and a reversible myopic shift, which suggests oxidative damage to lens proteins.

Factors that increase the risk of developing cataracts include increasing age, smoking, alcohol consumption, ultraviolet exposure, diabetes, prolonged steroid therapy, and malnutrition. 

Epidemiology

Numerous clinical reports describe the development of reversible myopia during a course of HBOT. Approximately 75% of patients experience this change.[5] The myopic shift appears more pronounced using a hood system than an oronasal mask.[5] Irreversible cataract changes are rarely reported, and when they are, they usually manifest after prolonged exposure to more than 100 treatment sessions. In a study involving 25 patients undergoing 150 or more hyperbaric treatments, 7 out of the 15 individuals with initially clear lenses developed cataracts. Notably, all 25 patients experienced transient myopia, as expected.[6]  Although this series involves an unusually high number of treatments, another study in which subjects only receive a more typical 40 treatments still reveals mild lens opacification changes.[7]

An ongoing randomized trial, not yet published, examining myopic shift in patients administered oxygen through a hood versus a mask will incidentally report the development of nuclear cataracts in approximately 2% of the 120 patients treated with 20 to 40 exposures. This implies that the actual incidence of cataracts may be underestimated. One potential explanation is that the myopic shift in many patients may endure for several weeks, and the failure to resolve may be overlooked by the hyperbaric treatment. Consequently, the diagnosis of cataracts may only be established much later. In addition, an informal belief exists that a course of HBOT could accelerate the maturation of an early cataract that was already present before the initiation of treatment.

Pathophysiology

Nuclear cataracts result from changes in the lens proteins called crystalline. Emerging evidence suggests that these changes likely result from oxidative damage, which nitric oxide pathways could mediate. Notably, the lens cannot eliminate its nonviable cells. These cells continue to compress into the center of the lens and begin to lose their transparency. The modifications in crystalline structures affect the lens's capacity to refract light, thereby decreasing visual acuity. This overall understanding of the pathophysiology of nuclear cataracts aligns with the observed increase in myopic changes and cataracts related to hyperbaric oxygen.

Toxicokinetics

An experiment in guinea pigs illustrates that hyperbaric oxygen induces the cross-linking of lens nuclear crystallins into substantial disulfide-bonded aggregates capable of scattering light. A similar process may be involved in the formation of human nuclear cataracts.[3]  

History and Physical

The routine assessment of patients undergoing HBOT includes obtaining an ocular history, specifically focusing on any history of cataracts or deterioration in visual acuity. Individuals with cataracts typically report a gradual decline in visual acuity and challenges with night and near vision. Key symptoms include reduced visual acuity, glare sensitivity in well-lit environments, and myopic shift due to cataract progression. Moreover, individuals may encounter monocular diplopia attributed to nuclear changes in the lens, resulting in a "lens within a lens" phenomenon. This diplopia is often uncorrectable with spectacles, prisms, or contact lenses.

Clinicians should assess visual acuity before initiating a course of HBOT and repeat the assessment after therapy, even without reported visual disturbances. Interim examinations and referral for specialist assessment may be warranted if patients complain of deteriorating vision or if a myopic shift persists 10 to 12 weeks after HBOT. A formal ocular refraction can detect changes in lens opacity, aiding in future treatment planning. An established cataract may present as a cloudy or yellowish lens during examination. However, in the context of hyperbaric oxygen, the gross appearance of the lens may appear normal despite potential underlying changes.

Evaluation

Although some authorities recommend formal refraction and visual acuity testing by an ophthalmologist, more often, patients undergo a simple measurement of visual acuity using a Snellen chart or similar tool before commencing HBOT. This is followed by repeated testing at the end of therapy or in the presence of visual complaints during treatment. Symptomatic patients undergo a nondilated fundal examination, which may reveal darkening, opacities, or obscuration within the red reflex. A more comprehensive ophthalmic examination is then conducted to assess the type and extent of lens opacity. Furthermore, a dilated fundus examination is performed to exclude other pathologies contributing to reduced vision or impede complete vision restoration after cataract surgery.

Formally diagnosing cataracts is exceedingly uncommon during or in the weeks following the completion of HBOT. However, clinicians should consider the possibility of cataracts if the myopic shift associated with HBOT persists beyond 2 to 3 months of treatment. Notably, all patients need to be aware that the late development of cataracts is a recognized but rare complication of HBOT.

Treatment / Management

The myopic shift following the cessation of HBOT should be managed expectantly. Temporary spectacles can be used to assist with daily activities during this period. If the changes are significant, an early referral for further examination is warranted. If visual acuity does not show improvement after 10 to 12 weeks, a thorough eye examination may reveal the presence of a cataract. Cataract extraction and replacement with an intraocular lens will be necessary in such cases. Before starting HBOT, healthcare professionals should inform patients about the possibility of experiencing myopic shifts and the potential development of cataracts. Patients with early cataracts should be aware that these may likely progress more rapidly during and after HBOT.[8][9][10](B3)

Differential Diagnosis

Clinicians should conduct a comprehensive evaluation during HBOT to explore alternative causes of visual acuity deterioration. Notably, a history of sudden acuity reduction within minutes or hours constitutes an ocular emergency. An ophthalmologist should rule out more prevalent causes of acute blindness, including retinal arterial occlusion, retinal venous occlusion, cerebral stroke, retinal detachment, and vitreous hemorrhage.

Complications

Complications arising from HBOT-induced cataracts primarily pertain to surgical challenges associated with lens replacement. The risk of uveitis and infectious and noninfectious endophthalmitis exist immediately postoperatively and during the delayed postoperative period.

Intraoperative Complications 

Intraoperative complications may include a shallow or flat anterior chamber, capsular rupture, suprachoroidal hemorrhage or effusion, expulsive choroidal hemorrhage, retained lens material, vitreous disruption, and incarceration into the wound, iridodialysis, and retinal light toxicity.

Immediate Postoperative Complications

Immediate postoperative complications include acute endophthalmitis, intraocular lens displacement or malposition, corneal and macular edema, toxic anterior segment syndrome, and hemorrhagic occlusive retinal vasculitis due to intraocular vancomycin use.

Notably, using vancomycin as prophylaxis against endophthalmitis in cataract surgery is generally not recommended. Additional complications may include a flat or shallow anterior chamber due to wound leak, choroidal detachment, pupillary and ciliary block, suprachoroidal hemorrhage, stromal and epithelial edema, hypotony, Brown-McLean syndrome, vitreocorneal adherence, delayed choroidal hemorrhage, hyphema, elevated intraocular pressure, and uveitis-glaucoma-hyphema syndrome.

Potential Late Postoperative Complications 

Potential late postoperative complications may include suture-induced astigmatism, retinal detachment, posterior capsule opacification, macular degeneration, pupillary capture, decentration, iris atrophy, chronic uveitis, chronic endophthalmitis, and the use of an incorrect power of intraocular lens.

Deterrence and Patient Education

Advancing age is the most significant risk factor for cataract development. Considering hyperbaric conditions as a potential catalyst for expediting the natural progression of age-related cataracts should be included in the assessment when weighing the risks and benefits of HBOT. Generally, the risk is minimal for a short-term series of hyperbaric therapy, particularly for well-established indications involving fewer than 40 treatments. No evidence indicates that a single session of HBOT can affect vision. Ophthalmologists should assess the vision and diagnose the cause of any impairment in patients undergoing multiple HBOT treatments, especially if they report persistent visual changes lasting more than 2 to 3 months after completing HBOT.

Enhancing Healthcare Team Outcomes

Treating cataracts in patients undergoing HBOT requires collaboration among all interprofessional healthcare providers involved in their care, including the primary care clinicians, hyperbaric oxygen team, and ophthalmologists. Healthcare providers should have the requisite knowledge and skills to recognize patients with cataracts resulting from HBOT therapy, including the ability to differentiate an anticipated myopic shift from cataract development.

Individual roles within the healthcare team should be delineated, with each member contributing their specialized expertise to optimize patient care and reduce morbidity. Effective interprofessional communication is essential to foster a collaborative environment where members efficiently share information, encourage questions, and promptly address concerns. Care coordination is crucial to ensure effective management of a patient's progress from diagnosis to treatment and follow-up, leading to timely diagnosis and improved patient safety.

By adhering to these principles of skill, responsibilities, interprofessional communication, and care coordination, healthcare professionals can provide patient-centered care, ultimately improving patient outcomes and enhancing team performance in managing patients with cataracts due to HBOT.

References


[1]

Gengel KC, Hendriksen S, Cooper JS. Hyperbaric Related Myopia and Cataract Formation. StatPearls. 2024 Jan:():     [PubMed PMID: 28613605]


[2]

Churchill S, Deru K, Wilson G, Cable R, Bell JE, Weaver LK. Rates of visual acuity change in patients receiving hyperbaric oxygen in monoplace and multiplace chambers. Undersea & hyperbaric medicine : journal of the Undersea and Hyperbaric Medical Society, Inc. 2016 May-Jun:43(3):217-23     [PubMed PMID: 27416689]


[3]

Simpanya MF, Ansari RR, Suh KI, Leverenz VR, Giblin FJ. Aggregation of lens crystallins in an in vivo hyperbaric oxygen guinea pig model of nuclear cataract: dynamic light-scattering and HPLC analysis. Investigative ophthalmology & visual science. 2005 Dec:46(12):4641-51     [PubMed PMID: 16303961]

Level 3 (low-level) evidence

[4]

McMonnies CW. Hyperbaric oxygen therapy and the possibility of ocular complications or contraindications. Clinical & experimental optometry. 2015 Mar:98(2):122-5. doi: 10.1111/cxo.12203. Epub 2014 Oct 12     [PubMed PMID: 25308346]


[5]

Bennett MH, Hui CF, See HG, Au-Yeung KL, Tan C, Watson S. The myopic shift associated with hyperbaric oxygen administration is reduced when using a mask delivery system compared to a hood - a randomised controlled trial. Diving and hyperbaric medicine. 2019 Dec 20:49(4):245-252. doi: 10.28920/dhm49.4.245-252. Epub     [PubMed PMID: 31828742]

Level 1 (high-level) evidence

[6]

Palmquist BM, Philipson B, Barr PO. Nuclear cataract and myopia during hyperbaric oxygen therapy. The British journal of ophthalmology. 1984 Feb:68(2):113-7     [PubMed PMID: 6691953]


[7]

Riedl P, Škiljić D, Arnell P, Wannholt R, Zetterberg M, Andersson Grönlund M. Myopic shift and lens turbidity following hyperbaric oxygen therapy - a prospective, longitudinal, observational cohort study. Acta ophthalmologica. 2019 Sep:97(6):596-602. doi: 10.1111/aos.14010. Epub 2019 Jan 28     [PubMed PMID: 30690920]


[8]

Gesell LB, Trott A. De novo cataract development following a standard course of hyperbaric oxygen therapy. Undersea & hyperbaric medicine : journal of the Undersea and Hyperbaric Medical Society, Inc. 2007 Nov-Dec:34(6):389-92     [PubMed PMID: 18251434]

Level 3 (low-level) evidence

[9]

Gosselin ME, Kapustij CJ, Venkateswaran UD, Leverenz VR, Giblin FJ. Raman spectroscopic evidence for nuclear disulfide in isolated lenses of hyperbaric oxygen-treated guinea pigs. Experimental eye research. 2007 Mar:84(3):493-9     [PubMed PMID: 17196965]

Level 3 (low-level) evidence

[10]

Schaal S, Beiran I, Rubinstein I, Miller B, Dovrat A. [Oxygen effect on ocular lens]. Harefuah. 2005 Nov:144(11):777-80, 822     [PubMed PMID: 16358652]

Level 3 (low-level) evidence