Open-angle Glaucoma Clinical Trial
Official title:
Non-invasive Absolute Intracranial Pressure (ICP) Measurement in Patients With Open-angle Glaucoma and Papilledema
Glaucoma remains a disease with an unclear and complex underlying pathophysiology. Recently,
researchers have emphasized not only intraocular pressure (IOP) or vascular dysregulation,
but also translaminar pressure's (TPG) role in glaucoma (TPG=IOP-ICP). A higher TPG may lead
to abnormal function and optic nerve damage due to changes in axonal transportation,
deformation of the lamina cribrosa, altered blood flow, or a combination thereof leading to
glaucomatous damage. However only invasive ICP measurements are available within the
contemporary medicine. The ideas for non-invasive ICP measurement have been approached since
about 1980. Most of the proposed technologies were based on ultrasound and were capable of
monitoring blood flow in intracranial or intraocular vessels, cranium diameter, or acoustic
properties of the cranium. Broad research has extended into sonography of optic nerve sheath
and its relation with elevated ICP. However, most of these correlation-based methods had the
same problem—the need of individual patient specific calibration. Seeking to measure
absolute ICP values, researchers from Kaunas University of Technology created a non-invasive
method, which does not need a patient specific calibration. The method is based on direct
comparison of ICP value with the value of pressure Pe that is externally applied to the
tissues surrounding the eyeball. Intracranial segment of ophthalmic artery (OA) is used as a
natural sensor of ICP and extracranial segment of OA is used as a sensor of Pe. The special
two depth transcranial Doppler (TCD) device is used as a pressure balance indicator when ICP
= Pe.
The aim of our study is to assess TPG in patients with primary open open-angle glaucoma
(POAG). In addition the investigators want to measure ICP in patients with papilledema (PE)
in order to compare them with glaucoma patients.
Glaucoma is a progressive optic neuropathy leading to the retinal ganglion cell death and
typical optic nerve head (ONH) damage [1]. It remains a disease with an unclear and complex
underlying pathophysiology. Intraocular pressure (IOP) is the main and only modifiable risk
factor for glaucoma [2]. Although lowering IOP helps to decelerate or stabilize the disease,
a vast number of patients still show signs of glaucoma despite an IOP within normal range.
Clearly other pathogenetic mechanisms beyond IOP are involved in the pathogenesis of
glaucoma for certain individuals. Non-IOP factors such as lower systolic ocular perfusion
pressure (OPP), reduced ocular blood flow, cardiovascular disease, and low systolic blood
pressure (BP) have been identified as risk factors for primary open-open-angle glaucoma
(POAG) [3-6]. Evidence shows that non-IOP factors can impact the apoptotic process
associated with glaucoma [7].
Recently, researchers have emphasized not only IOP or vascular dysregulation, but also
intracranial pressure's (ICP) role in glaucoma [8-10]. The optic nerve is exposed not only
to IOP in the eye, but also to ICP as it is surrounded by cerebrospinal fluid (CSF) in the
subarachnoid space. Because the lamina cribrosa separates these two pressurized regions
[11], the decrease in pressure that occurs across the lamina cribrosa (IOP-ICP) is known as
the translaminar pressure gradient (TPG). A higher TPG may lead to abnormal function and
optic nerve damage due to changes in axonal transportation, deformation of the lamina
cribrosa, altered blood flow, or a combination thereof leading to glaucomatous damage.
Besides, TPG may be the primarily pressure-related parameter for glaucoma [12-15], since the
ONH is located at the junction between the intraocular space and the orbital retrobulbar
space.
However, the role of TPG still remains unknown, because only invasive ICP measurements are
available within the contemporary medicine (lumbar puncture or punction of brain
ventricles—for patients with severe brain injury). The ideas for noninvasive ICP measurement
have been appearing since about 1980. Numerous methods for finding the objects or
physiological characteristics of cerebrospinal system that would be related to the ICP and
its monitoring have been sought by many authors. Most of the proposed technologies were
based on ultrasound and were capable of monitoring blood flow in intracranial or intraocular
vessels, cranium diameter, or acoustic properties of the cranium [16]. Broad research has
extended into sonography of optic nerve sheath and its relation with elevated ICP [17].
However, most of these correlation-based methods had the same problem—the need of individual
patient specific calibration. Seeking to measure absolute ICP values, researchers from
Kaunas University of Technology created a noninvasive method, which does not need a patient
specific calibration [18, 19]. The method is based on direct comparison of ICP value with
the value of pressure Pe that is externally applied to the tissues surrounding the eyeball.
Intracranial segment of ophthalmic artery (OA) is used as a natural sensor of ICP and
extracranial segment of OA is used as a sensor of Pe. A special two depth transcranial
Doppler (TCD) device [18, 19] is used as a pressure balance indicator when ICP = Pe.
Accuracy, precision, sensitivity, specificity, and diagnostic value of this method were
proven with healthy subjects and patients with neurological diseases. This device has not
yet been used in clinical studies to investigate TPG significance in glaucoma. The aim of
our study is to assess TPG in patients with primary open open-angle glaucoma (POAG). In
addition the investigators want to measure ICP in patients with papilledema (PE) in order to
compare them with glaucoma patients.
The non-invasive ICP measurement using two deeps TCD device allows us to get ICP values from
immediate vicinity of optic nerve, which in turn very important in term of understanding the
pathophysiology of such conditions like PE and POAG.
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Allocation: Non-Randomized, Endpoint Classification: Efficacy Study, Intervention Model: Parallel Assignment, Masking: Open Label, Primary Purpose: Diagnostic
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