Firework and Shrapnel Eye Injuries
Fireworks are used for recreation as well as religious, cultural, and patriotic celebrations around the world. However, consumer firework-related injuries can be devastating and lead to permanent vision loss, limb amputations, and, in some cases, death. Firework-related injuries are especially prevalent in the United States during New Year’s Eve and Fourth of July celebrations. There is limited large-scale data on the incidence of firework injuries in the literature. Out of all the firework-related injuries requiring surgery or hospitalization in one study, the globe was the second-most affected body region.
Firework injuries are responsible for about 2% of all reported ocular injuries. The 2021 Fireworks Annual Report from the United States Consumer Product Safety Commission reported 11,500 injuries treated in the U.S. during the 2021 calendar year. However, according to the summary, “this number is not complete and should be considered a minimum.” Out of 11,500 injuries, an estimated 8,500 were treated from June 18 to July 18, 2021.
The American Academy of Pediatrics reported that ocular injuries constitute 20% of all firework-related injuries, with some studies reporting upwards of 31 percent. Out of all the ocular firework-related injuries in the United States, 65.9% of individuals were 18 years or younger, and 71.9 – 89% were male. With regards to age, the injury rate was higher in children ages 10-19 years old. These incidents occur in all societies and are more common around the Fourth of July and New Year’s Eve. Studies show that 99 percent of all ocular firework injuries occur from consumer-grade and homemade fireworks.
Children are more commonly bystanders than active users of fireworks compared with adults in severe firework-related injuries. This highlights a need for a public health intervention to prevent serious morbidity and vision loss in children and adolescents. Countries with more restrictive firework legislation has significantly less eye trauma. In the United States, consumer-grade fireworks are widely available, although firework restrictions differ by state. A systematic review notes that regions with a more restrictive firework legislation have an 87% lower ophthalmic injury rate.
Two large US based studiescategorizing most common types of ocular injuries from fireworks are listed in Table 1. Injuries were reported from a multi-center retrospective review of 1007 individuals with firework-related ocular injuries in the United States from 1999 to 2017 and a 11-year experience of a US level 1 trauma center from 2003 to 2013.
|Table 1. Types of ocular firework-related injuries|
|Injuries, No. (%) (n = 1007)7||Injuries, No. (%) (n = 100)6|
|Eyelid injuries||n/a||39 (39)|
|Ocular burn||633 (62.9)||0|
|Ocular foreign body||118 (11.7)||5 (5)|
|Conjunctival irritation||97 (9.6)||0|
|Other severe eye traumab||46 (4.6)||n/a|
|Hyphema||35 (3.5)||42 (42)|
|Ruptured globe||28 (2.8)a||17 (17)|
|Globe laceration [SLH3]||17 (1.7)||n/ac|
|Subconjunctival hemorrhage||13 (1.3)||n/a|
|Traumatic iritis||11 (1.1)a||0|
|Corneal injury (including abrasion)||7 (0.7)||67 (67)|
|Vitreous hemorrhage||n/a||19 (19)|
|Retinal injury||1 (0.1)||17 (17)|
|Lacrimal injury||1 (0.1)||0|
|Orbital fracture||1 (0.1)a||12 (12)|
|Optic neuropathy||0||3 (3)|
|a one patient experienced ruptured globe, traumatic iritis and orbital floor fracture.
b Includes hyphema, globe laceration, subconjunctival hemorrhage, traumatic iritis, corneal injury, retinal injury, and lacrimal injury.
c Globe lacerations were included in ruptured globe numbers in this study.
Overall, the most common ocular injuries noted in these two large studies were ocular burns, eyelid injuries, corneal injuries, and vitreous hemorrhages. Of those with open globe injuries, the majority were full-thickness lacerations including both the cornea and sclera, one patient sustained bilateral globe ruptures. Out of 1007 individuals with firework-related ocular injuries seen in US emergency departments, 90.5% were treated and released without transfer, while 8.7% required admission or transfer to another hospital.
In the United States, rocket and mortar-type fireworks were significantly associated with ruptured globe and other forms of severe trauma (hyphema and corneal injury) while firecrackers were associated with ocular burn and public displays with foreign bodies. Importantly, ocular injuries from professional firework displays are rare—the majority of injuries occur at home.
Of note, the distribution of injuries may vary from country to country due to different restrictions on types of fireworks. For example, roman candles, small bottle rockets, and launching tubes for rockets are banned in the Netherlands; however, these types of fireworks are the major source of serious ocular injury in the United States. A multi-center study including tertiary care hospitals in 5 countries and private ophthalmology practices of 388 patients reported 219 (85%) closed globe injuries and 34 (13.2%) open globe injuries related to fireworks. Of the open globe injuries, 47% were ruptures, 38% penetrating, 12% perforating and 12% IOFBs.
Incident descriptions obtained from telephone investigations for firework-related injuries discovered that malfunction, specifically errant flightpath, early detonation, or tip over, was the most common hazard pattern to have caused injury.
The American Academy of Ophthalmology recommends staying a safe distance away from fireworks, to not pick up misfires, supervision of children, wearing eye protection and to watch professional firework displays instead of using consumer fireworks.
Homemade or illegal fireworks can have greater explosive powder and lead to more severe injuries. Due to the greater force generated by homemade explosives, these injuries can often be life-threatening. Federal agencies conduct annual surveillance testing on consumer fireworks to look for noncompliant fireworks, which have fuse violations, presence of prohibited chemicals, and an overload of pyrogenic materials.
Risk factors for ocular trauma include lack of protective eyewear, lack of parental supervision, and close distance to fireworks. Other risk factors include using consumer-grade fireworks, as professional fireworks only cause 1 percent of firework-related injuries. Injuries to bystanders are very common, making up 65% of people injured according to one study.
Almost all patients will report recent trauma to the eye involving fireworks or shrapnel fragments. A complete history includes date and time of injury, mechanism of injury, use of eye protection, and use of substances such as alcohol or recreational drugs. It is important to determine the mechanism of injury, as well as the size, weight, velocity, force, and composition of the object, as well as the type of firework in order to determine the need for possible emergent surgery.
Pertinent ocular history, especially history of previous ocular surgery, presence of vision deficits in other eye, and a medical history, including current medications, allergies, tetanus status, is important to know at time of evaluation. It is also pertinent to ask the timing of the patient’s last meal in preparation for possible surgery.
It is important to document visual acuity prior to performing any dilated exam or procedure. Evaluate for optic nerve function by evaluating for pupillary response and color plates. Pay attention to extraocular motility, globe malposition, and areas of chemosis as this might help localize the shrapnel’s entry site. Be careful not to cause extrusion of intraocular contents if an open globe exists. Slit lamp exam should help locate and assess the depth of the foreign body. Inspect closely for possible entry sites and look out for low intraocular pressures in the involved eye, signifying an open globe. Seidel testing will indicate a conjunctival, scleral, or corneal laceration and may reveal an open globe injury.
A complete slit lamp biomicroscopic examination and fundus examination should be done in all patients at the time of presentation and on follow-up visits.
Patients typically complain of foreign body sensation, ocular pain, decreased vision, redness, tearing, and photophobia.
A CT scan of the orbit should be strongly considered in the case of projectile injuries to exclude an intraocular foreign body. Thin cut (1-mm sections) axial, coronal, and parasagittal views are preferred. Avoid MRI in the case of a possible metallic foreign body. B-scan ultrasonography and ultrasound biomicroscopy can also be considered to evaluate for IOFB, retinal detachment or in the case of poor view of the fundus.
The most common injuries include corneal abrasions(67%), hyphema, and eyelid injuries. Ruptured globes occur in about 17% of cases. It is also important to consider thermal and chemical burns from firework material.
Management for all types of possible firework injuries are beyond the scope of this article, and relevant articles will be listed below under “Additional Resources.”
Evaluation of other life-threatening injuries or injuries outside of the orbit should be evaluated and co-managed with the appropriate services. Hand or other orthopedic injuries may need to be more urgently managed, and co-management with orthopedic surgery is necessary. In cases of extensive facial or skull fractures, co-management with neurosurgery, otolaryngology and oral and maxillofacial surgery may be needed. Periocular or facial burns may be co-managed with internal medicine or dermatology.
The treatment for firework injuries depends on the specific injuries present. Exploration in the OR may be required depending on the extent of injury. If open globe injury is suspected, protect the eye from further examination or trauma with an eye shield. CT scan of the brain and orbits (axial, coronal, and parasagittal views with 1-mm sections) to evaluate for IOFB should be obtained urgently, to determine the need for pars plana vitrectomy. Systemic antibiotics, typically cefazolin or vancomycin or moxifloxacin should be administered in addition to tetanus prophylaxis.
In cases where chemical injury is suspected, the pH should be evaluated and, if above or below pH 7-7.4, should be remedied with copious irrigation using saline or Ringer lactate solution. Irrigation should be continued until a neutral pH of 7.0 to 7.4 is achieved. After the exclusion of open globe injury, particulate matter may be irrigated or manually removed.
Globe exploration should be performed in suspected globe rupture or penetrating trauma, with possible vitrectomy if an intraocular foreign body or retinal detachment is present. Surgical removal of intraocular foreign bodies has associated risks, which must be weighed against the complications of leaving the object near important structures in the eye.
The outcomes of these events depend on the mechanism of the injury. Open globe injuries commonly lead to vision loss and even enucleation in severe cases. Open globe injuries and patients with poor visual acuity at presentation have the worst visual prognosis. Long-term effects of trauma may include cataract or angle-recession glaucoma. Less severe injuries such as corneal abrasions typically have a more favorable prognosis. Visual acuity ranges from 20/20 to no light perception, and in a study looking at 18 globe ruptures from firework injuries, 10 (59%) of eyes were no light perception at last follow-up.
- Gudgel D, Steinemann TL. Fireworks Eye Safety. American Academy of Ophthalmology. EyeSmart/Eye health. https://www.aao.org/eye-health/tips-prevention/injuries-fireworks-eye-safety. Accessed December 05, 2019.
- Anterior Segment Trauma: Evaluation, Considerations and Initial Management [./Https://eyewiki.aao.org/Anterior%20Segment%20Trauma:%20Evaluation%2C%20Considerations%20and%20Initial%20Management https://eyewiki.aao.org/Anterior_Segment_Trauma:_Evaluation,_Considerations_and_Initial_Management]
- Eyelid Laceration [./Https://eyewiki.aao.org/Eyelid%20Laceration https://eyewiki.aao.org/Eyelid_Laceration]
- Ruptured Globe [./Https://eyewiki.aao.org/Ruptured%20Globe https://eyewiki.aao.org/Ruptured_Globe]
- Ocular Penetrating and Perforating Injuries [./Https://eyewiki.aao.org/Ocular%20Penetrating%20and%20Perforating%20Injuries https://eyewiki.aao.org/Ocular_Penetrating_and_Perforating_Injuries]
- Intraocular Foreign Bodies (IOFB) [./Https://eyewiki.aao.org/Intraocular%20Foreign%20Bodies%20(IOFB) https://eyewiki.aao.org/Intraocular_Foreign_Bodies_(IOFB)]
- Chemical (Alkali and Acid) Injury of the Conjunctiva and Cornea [./Https://eyewiki.aao.org/Chemical%20(Alkali%20and%20Acid)%20Injury%20of%20the%20Conjunctiva%20and%20Cornea https://eyewiki.aao.org/Chemical_(Alkali_and_Acid)_Injury_of_the_Conjunctiva_and_Cornea]
- ↑ 1.0 1.1 1.2 1.3 Wisse RP, Bijlsma WR, Stilma JS. Ocular firework trauma: a systematic review on incidence, severity, outcome and prevention. Br J Ophthalmol. 2010;94(12):1586-1591. doi:10.1136/bjo.2009.168419
- ↑ 2.0 2.1 2.2 2021 Firework Annual Report. United States Consumer Product Safety Commission; 2022. https://www.cpsc.gov/s3fs-public/2021-Fireworks-Annual-Report.pdf
- ↑ 3.0 3.1 Arya, S., Malhotra, S., Dhir, S., Sood, S. (2001). Ocular firework injuries-Clinical features and Visual Outcomes. Indian Journal of Ophthalmology, 49(3), pp. 189-190.
- ↑ 2021 Firework Annual Report. United States Consumer Product Safety Commission; 2022. https://www.cpsc.gov/s3fs-public/2021-Fireworks-Annual-Report.pdf
- ↑ American Academy of Pediatrics: Committee on Injury and Poison Prevention. Fireworks-related injuries to children. Pediatrics. 2001;108(1):190-191. doi:10.1542/peds.108.1.190
- ↑ 6.0 6.1 6.2 6.3 6.4 6.5 6.6 6.7 6.8 Chang, I., Prendes, M., Tarbet, K., Amadi, A., Chang, S., Shaftel, S. (2016). Ocular injuries from fireworks: the 11-year experience of a US level 1 trauma center. Eye, 30(10), pp. 1324-1330.
- ↑ 7.0 7.1 7.2 7.3 7.4 7.5 Shiuey EJ, Kolomeyer AM, Kolomeyer NN. Assessment of Firework-Related Ocular Injury in the US. JAMA Ophthalmol. 2020;138(6):618-623. doi:10.1001/jamaophthalmol.2020.0832
- ↑ John D, Philip SS, Mittal R, John SS, Paul P. Spectrum of ocular firework injuries in children: A 5-year retrospective study during a festive season in Southern India. Indian J Ophthalmol. 2015;63(11):843-846. doi:10.4103/0301-4738.171966
- ↑ AlGhadeer H, Khandekar R. Profile and Management Outcomes of Fireworks-Related Eye Injuries in Saudi Arabia: A 16-Year Retrospective Study. Clin Ophthalmol. 2021;15:4163-4168. Published 2021 Oct 15. doi:10.2147/OPTH.S333121
- ↑ Moore, J., McGwin, G., Griffin, R. (2014). The Epidemiology of firework-related injuries in the United States: 2000-2010. Injury, 45(11), pp. 1704-1709.
- ↑ Jacobson L, Sandvall BK, Quistberg DA, et al. Severe Fireworks-Related Injuries: Demographic Characteristics, Injury Patterns, and Firework Types in 294 Consecutive Patients. Pediatr Emerg Care. 2021;37(1):e32-e36. doi:10.1097/PEC.0000000000002302
- ↑ Rudisill TM, Preamble K, Pilkerton C. The liberalization of fireworks legislation and its effects on firework-related injuries in West Virginia. BMC Public Health. 2020;20(1):137. Published 2020 Jan 30. doi:10.1186/s12889-020-8249-0
- ↑ 13.0 13.1 Hoskin AK, Low R, de Faber JT, et al. Eye injuries from fireworks used during celebrations and associated vision loss: the international globe and adnexal trauma epidemiology study (IGATES) [published correction appears in Graefes Arch Clin Exp Ophthalmol. 2021 Sep 13;:]. Graefes Arch Clin Exp Ophthalmol. 2022;260(1):371-383. doi:10.1007/s00417-021-05284-z
- ↑ 14.0 14.1 14.2 American Academy of Ophthalmology. Reports of Eye Injuries from Fireworks has Doubled. https://www.aao.org/newsroom/news-releases/detail/reports-of-eye-injuries-from-fireworks-have-double. Accessed July 20, 2019.
- ↑ 15.0 15.1 15.2 15.3 15.4 15.5 Adam, M., Ahmed, F., & Wills Eye Hospital (Philadelphia, Pa.). (2017). The Wills eye manual: Office and emergency room diagnosis and treatment of eye disease. Philadelphia: Lippincott Williams & Wilkins.
- ↑ Moisseiev E, Last D, Goez D, Barak A, Mardor Y. Magnetic resonance imaging and computed tomography for the detection and characterization of nonmetallic intraocular foreign bodies. Retina. 2015;35(1):82-94. doi:10.1097/IAE.0000000000000266
- ↑ Ayalon A, Fanadka F, Levov D, Saabni R, Moisseiev E. Detection of Intraorbital Foreign Bodies Using Magnetic Resonance Imaging and Computed Tomography. Curr Eye Res. 2021;46(12):1917-1922. doi:10.1080/02713683.2021.1945108
- Smith, G., Knapp, J., Barnett, T. (1996). The rockets’ red glare, the bombs bursting in air: fireworks-related injuries to children. Pediatrics, 98(1), pp. 1.