pediatric hyphema (1)

The Pediatric Traumatic Hyphema
Danielle Trief, MD, MSc
Olumuyiwa T. Adebona, MBChB, MPH
Angela V. Turalba, MD
Ankoor S. Shah, MD, PhD
’
Introduction
The traumatic hyphema, defined as blood in the anterior chamber
(AC) of the eye after trauma, occurs at a rate of approximately 17 per
100,000 per year.1 Between 70% and 75% of these patients are children,
with a male-female ratio of at least 3:1.1,2 The complications of hyphema
include corneal blood staining, elevated intraocular pressure (IOP),
optic atrophy, and glaucoma. These complications can lead to visual
impairment or even blindness. Children are an especially important
population of hyphema patients, both because they comprise the
majority of patients and because of important considerations in their
treatment and management including amblyopia and compliance. This
review broadly defines the traumatic hyphema: pathophysiology, classification, examination, complications, medical and surgical management,
and long-term issues, with special attention toward the pediatric
population.
’
Etiology and Pathophysiology
In the United States, two thirds of traumatic hyphemas occur after
blunt trauma and one third from a lacerating injury, with the majority of
injuries occurring during sports.2,3 When a moving object hits the globe,
it can distort the eye, leading to an equatorial stretching and posterior
displacement of the lens-iris diaphragm.4 This stretching can produce
tears in the anterior face of the ciliary body and iris vessels. Other causes
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Volume 53, Number 4, 43–57
r 2013, Lippincott Williams & Wilkins
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Trief et al
of bleeding include iridodialysis or cyclodialysis.5 As bleeding ensues, the
IOP increases and ultimately tamponades the vessels. A fibrin-platelet
clot formation develops and bleeding stops.4,6 Maximal clot integrity is
achieved approximately 4 to 7 days after the injury. Prior to this
stabilization, rebleeding rates are highest. Clots are ultimately cleared by
fibrinolytically active materials in the anterior chamber (AC).4
In addition to sports injuries, traumatic hyphemas are frequently
seen after blunt trauma from airbag, paintball, or airsoft injuries.7–9
Hyphemas can also occur in the absence of trauma, and other etiologies
should be considered in the proper setting. Hyphemas can result from
iris neovascularization from diabetes, central retinal vein occlusion,
carotid occlusive disease, or chronic retinal detachments.1 These
conditions, however, are more common in adults. There have also
been case reports of malignancy (retinoblastoma or iris melanoma)
masquerading as hyphemas.10,11 The iris nodules that are seen in
juvenile xanthogranuloma can bleed spontaneously as can iris vascular
tufts.12,13 Hyphemas can be seen in some inflammatory conditions
including keratouveitis, Fuchs heterochromic iridocyclitis, and uveitisglaucoma-hyphema syndrome.1 Rarer medical causes of hyphema
include myotonic dystrophy, leukemia, and hemophilia. Hyphemas
can also be secondary to surgical or laser procedures, like the laser
iridotomy.
’
Classification
Hyphemas are quantified as either microscopic or macroscopic
(Table 1).17 Macroscopic hyphemas can be graded according to the
percentage of space they occupy or their height in millimeters in the AC.
Microscopic hyphemas are quantified between 1 and 4+ red blood cells
in the AC. Immediately after trauma the red blood cells may still be
suspended in the AC making classification difficult. If the patient
remains erect or lies in a position in which the head of the bed is
elevated 30 to 45 degrees, the blood will settle inferiorly, and grading of
the hyphema can be achieved. Careful documentation of the grade
ensures adequate monitoring of clearance of the blood over time.
’
History
A careful history is essential in the diagnosis and management of
hyphema. First, the mechanism of injury must be elicited because it can
help a physician determine whether the hyphema is present in isolation
or whether there may be other traumas. Head injuries, fractures, and
open-globe injuries (OGI) must be considered and ruled out before
documenting a closed-globe injury with hyphema. It is paramount to
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Fills entirety of the
anterior chamber
1/2 to nearly entire
anterior chamber
Between 1/3 and 1/2
of anterior chamber
Less than 1/3 of
anterior chamber
1+ cell = 6-15 cells/
HPF (1 1 mm slit
beam)
2+ cell = 16-25 cells
3+ cell = 26-50 cells
4+ cell = >50 cells
Grade 4
Grade 3
Grade 2
Grade 1
Microscopic (based on the
SUN working group
consensus for uveitis)16
Grade
Percentage of
Anterior Chamber
Illustration
58
20
14
8
75-90
75-90
65-70
25-50
25-50
Frequency of Visual Prognosis
Macroscopic
of 20/50 or
Hyphemas2 (%) Better14,15 (%)
Table 1. Quantification of a Hyphema With its Frequency and Visual Prognosis. The Frequency and Visual Prognosis are Based on Studies in Both
Pediatric and Adult Populations. Modified From Brandt and Haug,15 with permission from Elsevier. Adaptations are themselves works protected by
copyright. So in order to publish this adaptation, authorization must be obtained both from the owner of the copyright in the original work and from the
owner of copyright in the translation or adaptation.
Pediatric Traumatic Hyphema
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Trief et al
consider OGI in all hyphemas, especially when there are lacerating
injuries or hyphemas secondary to small, high-velocity, and/or sharp
objects (eg, BB guns, pellet or shot guns, metal from power tools, drills,
or saws).14 The pediatric trauma examination can be challenging, and
OGIs can be subtle. If there is suspicion for an OGI and an examination
cannot be performed adequately, the physician should consider an
examination under anesthesia.
The child’s ocular history is also important. If a recent visual acuity is
available, this should be documented so that it can be used to compare
acuities in subsequent examinations. A history of amblyopia or strabismus should also be noted because this may limit the extent of the child’s
visual recovery.
The family should be questioned about a history of sickle-cell disease
or blood dyscrasias as this will change the prognosis and management of
the hyphema (see special populations below).
Finally, a review of systems focusing on nausea and vomiting should
be elicited, as valsava maneuvers can worsen bleeding. Somnolence is
common, especially in children, and it may be difficult to obtain a full
history from the child alone.2 When possible, additional history should be
obtained from the family or from witnesses. One must always consider
non-accidental trauma/abusive head trauma and involve social services as
needed. African American, Afro-Caribbean, and Hispanic patients should
be screened for sickle-cell disease through a sickle-cell preparation. If this
is positive, a hemoglobin electrophoresis can distinguish sickle-cell
anemia from trait.18 In patients with bleeding disorders, laboratory tests
such as prothrombin/partial thromboplastin time, platelet count, liver
function tests, and bleeding time should be ordered.
’
Examination
The initial examination must rule out an OGI and must then
carefully document the hyphema for comparison with subsequent
examinations. Visual acuity should be measured and documented.
Immediately after injury, acuity may be severely impaired because of
the suspension of blood in the AC. As the blood settles inferiorly, the
vision usually improves. The pupils and iris should be examined for
an afferent pupillary defect, anisocoria (often secondary to torn iris
sphincters), and iridodialysis. Once an OGI is ruled out, the IOP should
be measured and documented. This may be difficult in an unhappy
child, and special tonometers such as the Icare (Icare Finland Oy, Espoo,
Finland) and Perkins tonometer can be useful.
The anterior segment should be examined for eyelid abrasions or
lacerations, orbital trauma, conjunctival lacerations or hemorrhages,
corneal edema, corneal abrasions or foreign bodies, traumatic cataract,
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zonular dehiscence, and lens subluxation. A fundoscopic examination
should be performed to look for vitreous hemorrhage, choroidal
rupture, commotio retinae, retinal hemorrhages, and retinal breaks,
tears, or retinal dialyses. It is recommended that both scleral depression
and gonioscopy be deferred until at least 1 month after presentation to
prevent worsening bleeding or secondary hemorrhage.6
The initial examination may be limited as blood may obscure the view
of both the anterior and posterior segment. In these cases, B-scan
ultrasonography, ultrasound biomicroscopy, and magnetic resonance and
computed tomography imaging should be used judiciously to rule-out
posterior pathologies such as retinal detachments, OGIs, or foreign bodies.
There have been no studies investigating how frequently patients
should be seen in outpatient follow-up. However, most authors
recommend very frequent follow-ups (several times weekly or daily)
while a layered hyphema is still present to monitor for the development
of complications.2,19,20
’
Complications
Hyphema can lead to several complications including amblyopia,
corneal blood staining, secondary hemorrhages, elevated IOP, inflammatory changes, optic nerve damage, and long-term issues. In children,
there is a theoretical risk that the hyphema can cause vision deprivation,
which can lead to amblyopia. However, in a retrospective review of 316
children, only 2 patients developed amblyopia. Both of these children
had a traumatic cataract, which was felt to be the cause of the
amblyopia.21
Corneal blood staining occurs in approximately 5% of patients with
a hyphema and can also lead to amblyopia.2 With rare exceptions, these
patients have near-total or total hyphemas. Corneal blood staining is also
associated with secondary hemorrhage, prolonged clot, elevated IOP,
and preexisting endothelial dysfunction.1 On pathologic specimens,
hemoglobin and hemosiderin deposits have been found in the central
corneal stroma.22,23 There is also evidence that protoporphyrin, a blood
product, can photosensitize the endothelium, leading to its decompensation in ambient light.24 Because of this, some clinicians have recommended patching eyes with long-standing hyphemas.1,25 The first
clinical signs of corneal blood staining are tiny, yellow granules that
appear in the deep stroma. A lack of definition of the fibrillar structure of
the corneal stroma can also be seen.2 This process usually starts centrally
and moves peripherally; clearance typically occurs reciprocally, and it
may take months or years to clear completely.1 In these cases, one must
consider surgery to prevent corneal damage and eventual amblyopia,
depending on the age of the child.
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A second hemorrhage or rebleed is another complication that many
studies have shown to lead to a worse visual prognosis.26 Studies have
found that about 80% of patients with hyphemas ultimately achieve
visual acuities better than 20/50, whereas only 64% of patients who have
secondary hemorrhages achieve this level of vision.2 Further, patients
with secondary hemorrhages are more likely to need a surgical
intervention.27 The need for intervention and the poor prognosis with
rebleeds is one argument used for daily ophthalmological examinations.
The examiner should look for evidence of fresh blood around a dark,
central clot or an increase in the size of the hyphema. However, one must
distinguish fresh blood from clot degradation products, which change
the color of the clot.
The critical time for secondary hemorrhage is in the first 4 to 7 days
after injury, when the clot is still stabilizing.14,26 The rate of secondary
hemorrhage varies between 2% and 38%, depending on the population.1,4 Higher rates of secondary hemorrhage have been found among
African Americans.3,28,29 Spoor et al3 reported a secondary hemorrhage
rate of 24.2% for African Americans compared with 4.5% for whites. The
etiology for this finding is not known, but one hypothesis is that melanin
plays a role. Lai et al30 injected melanin into a rabbit eye and then induced
a hyphema with a neodymium-doped yttrium aluminium garnet
(ND:YAG) laser. The eyes with melanin had higher rates of secondary
hemorrhage and prolonged absorption. Rates are also significantly higher
for patients with sickle-cell disease or trait.18 Some studies have found that
younger patients also have higher rates of secondary hemorrhage.2 This
may be because pediatric patients have difficulty maintaining ‘‘limited
activity’’ restrictions. Finally, some studies,31,32 but not all,33 have found
that ingestion of aspirin leads to higher rates of secondary hemorrhage. It
is generally recommended that patients avoid aspirin or nonsteroidal antiinflammatory drugs when being treated for hyphema.
Fluctuations in IOP are another complication associated with acute
hyphemas. In the first 24 hours, 32% of patients have IOPs>22.2 The
mechanism is thought to be plugging of the trabecular meshwork by
erythrocytes and fibrin.4 This is sometimes followed by a period of low
IOP secondary to reduced aqueous production and uveitis. As the ciliary
body recovers, the pressure can rise again. Rarely, an occult cyclodialysis
cleft can cause low IOP in the setting of hyphema and should be
considered. High pressures are more common with larger hyphemas.34
In total hyphemas, the incidence of elevated IOP is >95%.20 Large
collar-button clots that involve both the anterior and posterior chamber
can produce pupillary block.
The inflammation associated with hyphema can lead to synechiae:
posterior synechiae (adhesions between the iris and the lens) and
peripheral anterior synechiae (PAS; adhesions between the iris and
cornea). Both are seen more frequently in hyphemas that last for >1
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Pediatric Traumatic Hyphema
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week.1 Accommodation may also be impaired. This is seen in as many as
7% of patients after traumatic hyphema.35
Optic atrophy, which presents as pallor without glaucomatous cupping,
is seen in approximately 6% of hyphema patients.1 It is most frequently
seen with acute elevated pressures and in patients with sickle-cell disease.
’
Long-term Issues
Damage to the iris through synechiae and iris sphincter tears can
result in an abnormal pupil. Traumatic mydriasis is observed when the
pupil is abnormally dilated. Physicians should describe these findings to
patients and families and note if anisocoria is present. This knowledge
can spare a patient a work up for anisocoria in the future.
Glaucoma is a lifelong risk factor for patients with hyphema. Children
and their parents should be educated on this and instructed to have at
least yearly eye examinations. Angle recession, defined as a separation of
the longitudinal fibers from the circular fibers of the ciliary body, occurs
in up to 85% of patients with hyphema.21,36 Glaucoma is more frequently
seen when >180 degrees of the iris is involved.37 The risk of angle
recession glaucoma ranges from 0% to 20%.2 In a cohort study using the
United States Eye Injury Registry, the risk of developing posttraumatic
glaucoma after an ocular contusion (blunt injury) was 3.39% within 6
months of follow-up. Longer follow-up was not evaluated. Glaucoma was
independently associated with both hyphema (relative risk = 2.23) and
angle recession (relative risk = 1.71).38 Gonioscopy should be performed
at 1 month to document the presence and extent of angle recession. The
patient’s IOP should then be monitored regularly. Further studies are
needed to investigate the long-term risk of glaucoma after hyphema.
In addition to angle recession, glaucoma can result from destruction and
fibrosis of the trabecular meshwork, siderosis of the trabecular endothelium,
PAS, and secondary angle-closure glaucoma or ghost-cell glaucoma. Ghostcell glaucoma occurs when there is an associated vitreous hemorrhage and
can be seen 2 weeks to 3 months after the onset of bleeding.39
’
Prevention
As the majority of hyphemas occur in children and in sports injuries,
children should be encouraged to wear safety goggles.40
’
Treatment
In the acute setting, the goals of treatment are to triage associated
injuries, provide comfort, prevent secondary hemorrhage, and treat
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elevated IOP. Whether treatment should occur in the outpatient or
inpatient setting is a source of long-standing debate. The advantages of
the inpatient setting are that activities can be monitored and restricted,
medication administration can be ensured, and patients can be assisted
should they receive bilateral patching. A major disadvantage of hospitalization is the cost. Further, several studies have found no significant
benefit of treating hyphemas at home as compared with those being
treated on an inpatient basis.2,26,36,41,42 In 1 retrospective review, the
secondary hemorrhage rate for outpatients was 4.5% compared with
5.0% for inpatients.19 Historically, children have been admitted, as they
are more likely to be active and rebleed. In fidgety children, sedation
with benzodiazepines has even been utilized.43 However, studies have
again found no difference in secondary hemorrhage rates or final visual
outcome in patients admitted versus those discharged home, and
children have done quite well when discharged with strict instructions
for medication and activity.34 It is now more common to discharge
patients with daily follow-up. Hospital admission may be beneficial for
higher-risk patients (Table 2).
Regardless of whether or not the patient is admitted, most clinicians
recommend ‘‘limited activity’’ to prevent secondary hemorrhage. This is
usually enforced until the hyphema clears. Patients are also encouraged
to elevate the head of the bed to at least 30 to 45 degrees, which allows
the blood to settle inferiorly, facilitating the examination and preventing
PAS. Most physicians also recommend a protective shield. This can be
worn either at night only or for the entire day. In young patients, a clear
plastic shield is preferable to an opaque one as it minimizes the risk of
occlusive amblyopia. In the past, physicians would use bilateral patches
to limit eye movement. A Cochrane review, however, found no difference in single versus bilateral patching or ambulation versus complete
bed rest on the risk of secondary hemorrhage or on the visual acuity
outcome.26 Some authors have recommended refraining from reading,
as accommodation can theoretically stress injured vessels,14 although this
has not been formerly studied. As mentioned above, most authors
recommend against aspirin or nonsteroidal anti-inflammatory drugs,
although studies have found mixed results in terms of rates of
rebleeding.32,33 For pain management, acetominophen and, if necessary,
opiates can be used instead.
Table 2. Patients for Whom Hospitalization Should be Considered.2
Secondary hemorrhages (rebleed)
Penetrating ocular trauma
Hyphemas >50%
Noncompliant patients or parents
Suspected abuse
Patients with sickle-cell anemia/trait
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Medical Management
Elevated IOP is seen in one third of hyphema patients at presentation and should be treated as necessary. The first-line treatment is a
topical aqueous suppressant—for example, b-blockers.4 Carbonic anhydrase inhibitors are sometimes used, but care must be taken in sickle-cell
patients (see below). Prostaglandins and miotics are typically avoided as
they can lead to increased inflammation.1 a-Adrenergic agonists are used
in adults but should be avoided in very young children as they can cause
central nervous system and respiratory depression.44 When topical
therapy is insufficient, oral therapy with acetazolamide or methazolamide can be used. Again, these therapies are typically avoided in sicklecell patients because they can produce metabolic acidosis and volume
depletion, which worsens sickling.6
Cycloplegics are used both for comfort and also for iris muscle
paralysis, which can theoretically prevent secondary hemorrhage.
Dilation of the iris may also prevent the formation of posterior
synechiae. Topical atropine, cyclopentolate, or scopolamine is commonly
used for this. In children, atropine has the advantage of less frequent
drop administration. There is little evidence for this practice. As
mentioned above, miotics are typically avoided. One study reported a
longer time to resolution of a hyphema among patients treated with
pilocarpine compared with atropine.45
Both topical and systemic steroids have been used to treat hyphemas.
The mechanism of action is thought to be 3-fold: (1) stabilization of
the blood ocular barrier; (2) inhibition of fibrinolysis to prevent secondary hemorrhage; and (3) reduced inflammation.14,46 Several studies have
shown significantly decreased rates of secondary hemorrhage among
patients treated with topical steroids compared with those without.1,47,48
However, a recent Cochrane review concluded that there are no significance differences in terms of the resolution of primary hemorrhage, risk of
secondary hemorrhage, or risk of increased IOP in patients treated with
topical steroids compared with controls.26 In any case, topical steroids are
also beneficial in that they reduce inflammation and can therefore provide
comfort and prevent PAS formation, although this has not formerly been
studied. However, caution should be exercised in the long-term use of
steroids in children because of the risk for cataracts and glaucoma.49,50
There has been a wealth of literature on the use of antifibrinolytic
agents in the prevention of secondary hemorrhage.43,51–53 In the United
States, E-aminocaproic acid (Amicar; Xanodyne Pharmaceuticals, Newport, KY) is most commonly used. Plasmin usually binds to lysine
molecules in a clot. h-Aminocaproic acid resembles lysine and competitively occupies the binding site on plasmin thus inhibiting fibrin clot
digestion.1 Multiple studies including a Cochrane meta-analysis have
found decreased rates of secondary hemorrhage in patients who have
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Trief et al
been treated with Amicar compared with controls.26 Historically,
h-aminocaproic acid was administered intravenously, but more recently
topical preparations have been created and have been found to have
similar efficacy to the intravenous preparations.54 h-Aminocaproic acid
has been used safely in children,53 although h-aminocaproic acid does
carry a risk of clotting and is contraindicated in patients with active
intravascular thrombosis. Relative contraindications include pregnancy
and renal, hepatic, or cardiac disease.1 It has a high side-effect profile
including nausea, vomiting, and postural hypotension. Discontinuation
of h-aminocaproic acid can lead to secondary hemorrhage.51 Systemic
and local side effects can also be seen for the topical preparation.54
Patients using h-aminocaproic acid take a significantly longer time to
clear the clot compared with those without it.51,52 As a large clot can
obstruct vision, authors have recommended against the use of haminocaproic acid for clots >50% of the AC.2
Another antifibrinolytic agent, tranexamic acid, also a lysine analog, is
more commonly used outside the United States. Tranexamic acid has also
has been shown to prevent secondary hemorrhage.26,55–57 Tranexamic acid
has been studied in children and found to be safe.58,59 In vitro, it is 5 to
10 more potent than Amicar, and there are less gastric side effects.26
Several other experimental treatments have been used. Conjugated
estrogen (Premarin) was hypothesized to decrease secondary hemorrhages by increasing prothrombin concentration and decreasing antithrombin activity. A case series showed promising results, but the rates of
secondary hemorrhage were not significant in a prospective randomized
control trial.60,61 Intracameral tissue plasminogen activator (t-PA) has
been used to break up persistent clots; however, use of t-PA does carry
the risk for hemorrhage. In a case series of 3 eyes with persistent total
hyphemas, t-PA led to the resolution of all 3 hyphemas; however,
1 patient developed a vitreous hemorrhage.62
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Surgical Management
Hyphemas are largely treated medically, but approximately 5% of
patients ultimately require surgical intervention.1 The indications for
surgery are outlined in Table 3.
Table 3. Patients for Whom Surgery Should be Considered.4,14
Uncontrolled IOP
>50 mm Hg for 5 d or 35 mm Hg for 7 d
In sickle-cell patients >25 mm Hg for >24 h
Corneal blood staining
Total hyphemas that persist for >5 d
Large clots that persist for >10 d to avoid posterior synechiae
IOP indicates intraocular pressure.
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The purpose of surgery is to clear blood from the AC to prevent corneal
blood staining and/or elevated IOP. This can be performed by irrigationaspiration through a single incision, ‘‘hyphemectomy’’ using a microvitrectomy cutting-aspiration system, limbal clot delivery (most effective after
clot consolidation, which occurs 4 to 7 days after injury), or trabeculectomy
with AC wash out.1,4,6 One risk of surgical evacuation of the clot is rebleeding.
’
Special Populations
Patients with sickle-cell anemia or sickle-cell trait who have hyphemas are at higher risk for elevated IOP, optic atrophy, secondary
hemorrhage, and visual impairment.1,63,64 The irregular, ‘‘sickled’’
erythrocytes are more likely to clog the trabecular meshwork thereby
decreasing outflow and leading to higher IOP. As IOP rises, hypoxia,
acidosis, and hypercapnea in the AC produce further sickling. Patients
with sickle-cell anemia and trait are also predisposed to optic nerve
damage and central retinal artery occlusion. Even at IOP measurements
in the mid 20s to 30s, these patients can experience permanent optic
nerve damage.2 Rebleeding rates are also higher for sickle-cell patients.
In 1 retrospective study of 99 children, 9 experienced secondary
hemorrhage, all of whom were sickle-cell trait positive.63 In addition,
as mentioned above, care must be taken with medical therapies as
medications such as topical and oral carbonic anhydrase inhibitors can
lead to hemo-concentration and systemic acidosis, thereby worsening
sickling. Surgery should be considered earlier and at a lower IOP in
patients with sickle-cell anemia (Table 3). Approximately 10% of African
Americans carry the sickle-cell trait, and all African American patients
who present with a hyphema without a known history of sickle-cell
anemia should be screened by laboratory tests.
Patients with bleeding dyscrasias like hemophilia can have spontaneous
hyphemas or may develop hyphema after minor trauma, and they are also
more prone to rebleed.65 Blood factors (eg, factor VIII in hemophilia A)
should be maintained at normal levels, or antifibrinolytics should be used to
prevent secondary hemorrhage.66 Patients and parents should be asked
about a history of bleeding problems, and if there is concern, a compete
blood count and coagulation tests should be performed.
’
Conclusions
Although the majority of patients with traumatic hyphemas ultimately regain excellent visual acuity, complications such as secondary
hemorrhage, corneal blood staining, and glaucoma can be sight threatening. Thus, these complications need to be monitored and detected
early. In addition, the majority of hyphema patients are children, and
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Trief et al
Ocular trauma +
hyphema
History or family
history of blood
dyscrasias?
yes
no
Follow up q3
months for 2
visits than q6
months for 1
year, then
yearly if IOP is
normal.
yes
yes
no
History of sickle
cell?
Open-globe
injury?
no
unsure
Open-globe
injury?
Sedated exam
unsure
yes
Sickle cell
preparation and if
positive hemoglobin
electrophoresis.
Sickle cell or trait?
Check PT, PTT,
CBC, and
depending on
history, blood
factors, replete
factors as
necessary,
consider starting
antifibrinolytics
Repair open
globe
yes
yes
Consider
admission to
yes
hospital if IOP >
25
Start topical beta
blocker; avoid
carbonic anhydrase
inhibitors
IOP > 25 at 24
hours?
yes
no
Yearly
follow
up
no
Angle recession?
1 month follow
up: gonioscopy
and scleral
depression
Start atropine,
topical
prednisolone,
head of bed
elevated 30 -45
degrees, clear fox
shield, Tylenol for
pain (avoid ASA
and NSAIDS)
If sickle cell
Consider antifibrinolytics
Start topical beta blocker,
carbonic anhydrase
inhibitors (if not sickle
cell), avoid alpha
adrenergic agonist in
young children
yes
IOP > 25?
Surgery
IOP > 50 for 5
days or > 35 for
7 days?
yes
Rebleed?
no
yes
Consider admission,
start anti -fibrinolytics
no
Daily follow up until gross
hyphema clears
Large clot persists greater
than 10 days OR
Total hyphema persists
greater than 5 days OR
Corneal blood staining
Hyphema
resolves
Figure 1. Algorithm for the management of pediatric traumatic hyphema. The purple boxes
represent a standard course without complications. The orange boxes represent complications or
predisposing conditions to complications.
therefore special care must be taken by a good history taking, tailored
treatment, and long-term follow-up. Patients should be asked about
blood dyscrasias, and African American patients should be screened for
sickle-cell disease as these conditions may alter management. Treatment
should be aimed at clearing the hyphema while maintaining good IOPs.
If this is not possible through medical management, surgery is
recommended. Given this information, we suggest the use of the
algorithm shown in Figure 1.
There are still many unanswered questions in the management of
hyphemas: What is the ultimate rate of glaucoma? How frequently
should patients be seen in the acute setting and in long-term follow-up?
Should medical regiments be tailored for specific populations such as
sickle-cell patients, pediatric patients, and adult patients? Future studies
may address these unresolved issues.
The authors declare that they have no conflicts of interest to disclose.
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