User:Ellenmcmahon/Watershed Stroke

A watershed stroke is defined an "ischemic lesion which is situated along the border zones between the territories of two major arteries."^[1] "Watershed” refers to those border zone regions in the brain supplied by the major cerebral arteries where blood supply is decreased.

In general, a stroke occurs when there is some form of interruption or occlusion of blood flow to or within the brain. This is typically categorized as a Cerebral Vascular Accident (CVA). Strokes can be classified into two major categories: ischemic and hemorrhagic. In ischemic strokes, blood flow to the brain is blocked by blood clots or fatty deposits called plaque in blood vessel linings. In hemorrhagic strokes, a blood vessel bursts in the brain.^[2] Specifically, watershed strokes are a type of ischemic stroke because they are characterized by reduced blood flow and not by blood vessel rupture. These events are localized to two primary regions of the brain and are referred to as cortical watersheds (CWS) or external borderzone infarcts and internal watersheds (IWS) or internal boarderzone infarcts.^[3]

Derivation and terminology

Simply, watershed strokes are named because they affect the distal watershed areas of the brain. The original terminology came from the German literature, which used the analogy of an irrigation system. The German scholars compared the blood flow in distal arterial territories of the brain to the last field on a farm, which was the area with the least supply of water and therefore most vulnerable to any reduction in flow.^[4] In a medical context, the term “watershed” refers to those areas of the brain that receive dual blood supply from the most distal branches of two large arteries.^[4]

Nonetheless, within the literature itself, there exists confusion over terminology used to describe cortical (outer brain) and subcortical (inner brain) infarcts located between two vascular regions. Besides watershed, border zone is another common term used to refer to areas of the brain between the farthest end branches of two adjacent vascular territories. Other less used terms include: borderland, end zone, boundary zone, and terminal zone. These varying terms have arisen from the considerable anatomic variability both in the cerebral vascular structure and the territories of the brain that they supply.^[4]

Facts and statistics

• Watershed infarcts make up approximately 10% of all ischemic stroke cases.However, because WS infarction is seldom fatal, this is probably an underestimate, and imaging studies in severe internal carotid artery (ICA) disease report an incidence ranging from 19% to 64% ^[3]

.

• Almost 40% of these watershed infarcts are attributed to carotid stenosis or occlusion ^[3]

.

Causes and risk factors

Watershed strokes are caused by ischemia or a lack a blood flow to the brain ^[1]. There are several causes of ischemia, including embolism and atherosclerosis. There are several conditions that can predispose someone to watershed stroke by increasing the likelihood that insufficient blood supply will be able to reach the brain. Patients with many different cardiovascular diseases have a higher likelihood of experiencing a clot or a plaque that impedes flow through a blood vessel ^[3]. Cardiovascular diseases that increase the risk of ischemia include:

• Congestive heart failure, which can lead to an ability to pump sufficient amounts of blood to the brain
• Atherosclerosis, which can cause a buildup of cholesterol plaques in the blood vessels, thereby decreasing the volume of blood that can flow through the vessel and reach the brain ^[3]
• Angiopathy, a disease of the blood vessels ^[5]
• Arterial hypotension, or low blood pressure in the arteries ^[1]
• Hypertension, or high blood pressure ^[6]
• Hyperlipidemia, or excessive cholesterol build up in the blood vessels ^[6]
• Diseases such as sickle cell anemia, which can lead to deformed red blood cells clogging blood vessels and impeding blood flow ^[7]
• Carotid artery stenosis, or narrowing of the carotid artery which can decrease the volume of blood flow to the brain ^[6]

Symptoms

Initial symptoms

Watershed stroke symptoms are due to the reduced blood flow to all parts of the body, specifically the brain, thus leading to brain damage. Initial symptoms, as promoted by the American Stoke Association, are FAST (stroke) which represents drooping of the face, drifting of the arm, impaired speech and quickly calling 911. ^[8]

Further symptoms

After the initial stroke, other symptoms depend on the area of the brain affected. If one of the three central nervous system pathways is affected symptoms could include, numbness, reduced sensory sensation, and hyperreflexia.

Most often, the side of the brain damaged results in body defects on the opposite side. Furthermore, since the cranial nerves are located within the brainstem, damage to this area can lead to defects in the function of these nerves. Symptoms could include, altered breathing, problems with balance, drooping of eyelids, and decreased sensation in the face. ^[9]

Damage to the cerebral cortex may lead to aphasia or confusion and damage to the cerebellum may lead to lack of motor movement. ^[10]

Diagnosis

Diagnosis of a cerebral vascular accident begins with a general neurological examination, used to identify specific areas of resulting injury. A CT scan of the brain is then used to identify any cerebral hemorrhaging. An MRI with special sequences called diffusion-weighted MR imaging (DWI), is very sensitive for locating areas of an ischemic based stroke, such as a watershed stroke.

Further diagnosis and evaluation of a stroke includes evaluation of the blood vessels in the neck using either Doppler ultrasound, MR-angiography or CT-angiography, or formal angiography. An echocardiogram may be performed looking for a cardiac source of emboli. Blood tests for risk factors also may be ordered, including cholesterol levels, triglyceride levels, homocysteine levels, and blood coagulation tests.

Classification systems

• The Oxfordshire Community Stroke Project classification (OCSP, also known as the Bamford or Oxford classification) relies primarily on the patient's initial symptoms. Based on the extent of the symptoms, the stroke episode is classified as total anterior circulation infarct (TACI), partial anterior circulation infarct (PACI), lacunar infarct (LACI) or posterior circulation infarct (POCI). These four entities predict the extent of the stroke, the area of the brain affected, the underlying cause, and the prognosis.^[11][12]

• The TOAST (Trial of Org 10172 in Acute Stroke Treatment) classification is based on clinical symptoms as well as results of further investigations. In this diagnostic system, a stroke is classified as being due to

1. Thrombosis or embolism due to atherosclerosis of a large artery
2. Embolism of cardiac origin
3. Occlusion of a small blood vessel^[13]

Pathophysiology

Although many imaging techniques are used to document watershed strokes, their pathogenesis remains controversial. It may involve various mechanisms such as systemic hypotension, microemboli, severe arterial stenosis or ICA occlusion or a combination of these.^[3]

Hypotension

A sharp drop in blood pressure is the most frequent cause of watershed infarcts. The most frequent location for a watershed stroke is the region between the anterior and middle cerebral arteries. These events caused by hypotension are normally not hemorrhagic.^[1]

Microemboli

Microemboli have not been experimentally proven to cause watershed strokes. It is unclear whether they are a cause or an effect of a watershed stroke. ^[14] With watershed strokes, platelet aggregates block the small meningeal arteries in watershed regions creating a microembolism. This process is referred to as atherosclerosis. Microemboli usually form as thrombi, and can occlude arteries outright. On the other hand, they often detach, move into the circulation and eventually occlude smaller downstream branches causing a thromboembolism. Generally, emboli travel as far distally as their size permits along the vascular tree of the brain. Using this hypothesis, microemboli are viewed as the cause of the infarct rather than secondary events. Nevertheless, secondary thrombi do form after infarcts, and therefore it has been difficult to distinguish between emboli and thrombi in watershed locations.^[1] The best supporting evidence is correlative; patients display subcortical abnormalities on CT scans and present more microembolic signals during an carotidendarterectomy.^[14]

Microemboli can be common in some high-risk patients, such as those with carotid stenosis. However, in healthier patients strokes do not usually result from microemboli.^[14]

ICA occlusions

Thrombi at the split of the carotid artery in the neck may cause watershed infarcts between the territories of the anterior and the middle cerebral arteries. The resulting watershed infarcts in carotid occlusions have mostly been considered to be due to a reduced blood flow, similar to that of hypotnesion.^[1]

However, a different possible explanation has emerged. Alternatively, the vascular blockages could be the result of microemboli resulting from the carotid thrombi before the lumen becomes completely blocked.^[1] The wall of internal carotid artery just distal to the bifurcation (split) is a common site of atherosclerosis because of the unique hemodynamic effects caused by the flow divider. As a result, thrombi formation is more prevalent there.^[14] In general, researches have observed that this microembolization is a frequent phenomenon during the build-up of cerebral thrombi.^[1] The resulting emboli are pieces of calcified plaque. If these microemboli are 0.1 mm in diameter, they might pass into the small branches of the vascular system. There they may be destroyed by protective cellular defenses, or they may cause a stroke.^[14] Altogether, these considerations suggest that the watershed infarcts in carotid thrombosis are caused by microembolization from mural thrombi, thrombi adherent to the vessel wall, rather than by blood flow disturbances.^[1]

Treatment

Carotid endarterectomy

Often considered one of the safest ways to treat symptomatic carotid stenosis, carotid endarterectomy is a procedure by which a surgeon gently removes atherosclerotic plaque. Blood flow hopefully then returns to normal, increasing oxygen concentration to normal amounts in watershed areas of the brain.

There is the potential for complications, including disturbing portions of the plaque leading to a stroke or heart attack during or after surgery. Small risks of bleeding and infection exist as well.

Percutaneous treatments of carotid stenosis

In this type of procedure, a narrowed blood vessel is expanded via angioplasty or stenting. A thin angiography catheter is inserted in a large groin blood vessel and advanced to the stenosis. Percutaneous treatment is less invasive than endarterectomy, usually requiring only local anesthesia. Endarterectomy is still considered safer though, as percutaneous treatments can lead to accidental dislodging of plaque or even arterial rupturing.

Carotid angioplasty

During carotid angioplasty, an angiography cather with a small deflated balloon attached on the tip is advanced to a carotid stenosis. The ballon is then inflated slowly, forcing the narrowed portion of the vessel to expand.

Carotid stenting

Carotid stenting follows a similar procedure. Rather than using a balloon, a stent (metal mesh-like tube) is placed over the atherosclerotic plaque in the hopes of stabilizing it and allowing for increased blood flow to watershed portions of the brain.

Long-term care and rehabilitation

Watershed strokes are seldom fatal, but they can lead to neuromuscular degeneration, as well as dementia ^[3]. This degeneration at the watershed regions of the brain can lead to difficulties with movement and motor coordination, as well as speech. Long-term care is focused around three areas: rehabilitative therapy, surgical interventions, and prevention of future watershed strokes.

Rehabilitative therapies

Long-term rehabilitative therapy for watershed stroke patients involves physical, occupational, and speech and language therapies. Physical therapy can be used to enhance motor function in the legs and arms that has been impacted by stroke ^[15]. Occupational therapies can be provided to help to alleviate cognitive impairments that result from watershed stroke ^[16], as well as to improve fine motor function that was damaged as a result of the stroke ^[17]. Stroke can also cause impairments in speech production secondary to neurocognitive and neuromuscular impairments, and therefore speech and language therapies are often a component of long-term care for stroke patients. Intensive speech and language therapy has been shown to improve speech deficits associated with aphasia resulting from stroke ^[18].

Surgical interventions

Endovascular interventions, including surgical revascularization, can increase blood flow in the area of the stroke, thereby decreasing the likelihood that insufficient blood flow to the watershed regions of the brain will result in subsequent strokes ^[19]. Neuroscientists are currently researching stem cell transplantation therapies to improve recovery of cebreral tissue in affected areas of the brain post-stroke. Should this intervention be proven effective, it will greatly increase the number of neurons in the brain that can recover from a stroke ^[20].

Prevention of future strokes

There are several interventions that are often used to help prevent the recurrence of a watershed stroke; namely, nutritional interventions, as well as antiplatelet, anticoagulant, and statin drug use. Nutritional interventions, including increased consumption of certain amino acids, antioxidants, B-group vitamins, and zinc, have been shown to increase the recovery of neurocognitive function after a stroke ^[21]. Antiplatelet drugs, such as aspirin, as well as anticoagulants, are used to help prevent blood clots and therefore embolisms, which can cause watershed strokes. Statin drugs are also used to control hypertension, another risk factor for watershed stroke.

Current and future research

Stem cell transplantation

Ischemic stroke is still a major health concern and studies are being conducted to determine the pathway in which brain damage occurs to identify targets for intervention. Stem cell transplantation may help in intervention to improve cell recovery and regeneration. ^[22].

Deep watershed infarcts

Hemodynamic impairment is thought to be the cause of deep watershed infarcts, characterized by a rosary-like pattern. However new studies have shown that microembolism might also contribute to the development of deep watershed infarcts. The dual contribution of hemodynamic impairment and microembolism would result in different treatment for patients with these specific infarcts. ^[23]

Basilar artery (BA) stenting

While intracranial artery stenting is used for same side stoke prevention, basilar artery stenting may help to improve parallel, accessory blood flow. The stent may also lead to termination of recurrent middle cerebral artery (MCA) strokes. ^[24]

Penumbra imaging

The area around the damaged ischemia is known as the penumbra. This viable area has the ability to regenerate with the help of pharmacological treatment however most patients with penumbra are left untreated. New research is being conducted in metabolic suppression, direct energy delivery, and selective drug delivery to help salvage this area of the brain after a stroke. ^[25]

*CLEVSRKNC Peptide This new drug has been shown to home to ischemic stroke tissue as well as apoptotic neuronal cells of the penumbra region. This discovery may help in creating selective drug delivery for stroke patients. ^[26]

*Liposomal Drug Delivery Nanoliposomes are currently being researched for specific drug delivery due to their ph-sensitive and high BBB diffusion characteristics. Many advantages of these drugs include:

1. Drugs can be maintained in the active state while encapsulated.
2. Being encapsulated provides direct access to target tissue
3. Prevention of non-specific binding
4. Allows for a high concentration of drug

Due to the fact that acidic environment and low blood flow are prominent characteristic of the penumbra area, liposomal drugs seem to be well suited. ^[27]

References

1. Torvik, A. (1984). "The pathogenesis of watershed infarcts in the brain". Stroke. 15 (2): 221–223. doi:10.1161/01.str.15.2.221. PMID 6701929.
2. Centers for Disease Control and Prevention. "Types of Stroke". Retrieved October 27 2011. {{cite web}}: Check date values in: |accessdate= (help)
3. Momjian-Mayor, Isabelle; Baron, Jean-Claude (2005). "The Pathophysiology of Watershed Infarction in Internal Carotid Artery Disease: Review of Cerebral Perfusion Studies". Stroke. 36 (3): 567–577. doi:10.1161/01.STR.0000155727.82242.e1. PMID 15692123.
4. Bladin, CF; Chambers, BR; Donnan, GA (1993). "Confusing stroke terminology: Watershed or borderzone infarction?". Stroke. 24 (3): 477–478. doi:10.1161/01.STR.24.3.477. PMID 8446987.
5. Miklossey J., "Cerebral hypoperfusion induces cortical watershed microinfarcts which may further aggravate cognitive decline in Alzheimer's disease.", "Journal of Neurology Research", 2003 Sep 25
6. Donnan GA, Fisher M, Macleod M, Davis SM (May 2008). "Stroke". Lancet. 371 (9624): 1612–23. doi:10.1016/S0140-6736(08)60694-7. PMID 18468545.
7. Verduzco LA, Nathan DG, "Sickle cell disease and stroke", "Journal of the American Society of Hematology", 2009 Dec 10
8. Harbison J, Massey A, Barnett L, Hodge D, Ford GA (June 1999). "Rapid ambulance protocol for acute stroke". Lancet. 353 (9168): 1935. doi:10.1016/S0140-6736(99)00966-6. PMID 10371574.
9. Martini, F., Nath, J., [“Anatomy & Physiology.”] Boston: Pearson, 2010
10. Martini, F., Nath, J., [“Anatomy & Physiology.”] Boston: Pearson, 2010
11. Bamford J, Sandercock P, Dennis M, Burn J, Warlow C (June 1991). "Classification and natural history of clinically identifiable subtypes of cerebral infarction". Lancet. 337 (8756): 1521–6. doi:10.1016/0140-6736(91)93206-O. PMID 1675378. Later publications distinguish between "syndrome" and "infarct", based on evidence from imaging. "Syndrome" may be replaced by "hemorrhage" if imaging demonstrates a bleed. See Internet Stroke Center. "Oxford Stroke Scale". Retrieved 2008-11-14.
12. Bamford JM (2000). "The role of the clinical examination in the subclassification of stroke". Cerebrovasc. Dis. 10 (Suppl 4): 2–4. doi:10.1159/000047582. PMID 11070389.
13. Adams HP, Bendixen BH, Kappelle LJ; et al. (January 1993). "Classification of subtype of acute ischemic stroke. Definitions for use in a multicenter clinical trial. TOAST. Trial of Org 10172 in Acute Stroke Treatment" (PDF). Stroke. 24 (1): 35–41. doi:10.1161/01.STR.24.1.35. PMID 7678184. {{cite journal}}: Explicit use of et al. in: |author= (help)
14. Grotta, James; Alexandrov, Andrei (2001). "Preventing Stroke: Is Preventing Microemboli Enough?". Circulation. 103 (19): 2321–2322. doi:10.1161/01.CIR.103.19.2321. PMID 11352876.
15. Winter, Jackie; Hunter, Susan; Sim, Julius; Crome, Peter "Hands-on therapy interventions for upper limb motor dysfunction following stroke", "The Cochrane Stroke Group", 23 Aug 2010
16. Hoffmann, T.; Bennett, S.; Koh, CL; McKenna, KT., "Occupational therapy for cognitive impairment in stroke patients.", "Cochrane Stroke Group", 8 Sep 2010
17. Legg, L., Drummond, A., Leonardi-Bee, J., Gladman, J., Corr, S., Donkervoort, M., Edmans, J., Gilbertson, L., Jongbloed, L., Logan, P., Sackley, C., Walker, M., Langhorne, P., "Occupational therapy for patients with problems in personal activities of daily living after stroke: systematic review of randomised trials", "British Medical Journal", 3 Nov 2007
18. Kelly, H., Brady, M., Enderby, P., "Speech and language therapy for aphasia following stroke", "Cochrane Stroke Group", 12 May 2010
19. Mathews, M., Sharma, J., Snyder, K., Natarajan, S., Siddiqui, A., Hopkins, L., Levy, E., "Safety, effectiveness, and practicality of endovascular therapy within the first 3 hours of acute ischemic stroke onset.", "Neurosurgery", Nov 2009
20. Jablonska, A., Lukomska, B., "Stroke induced brain changes: Implications for stem cell transplantation.", "Acta Neurobiologiae Experimentalis", 2011
21. Aquilani, R., Sessaregom P., Iadarola, P., Barbieri, A., Boschi, F., "Nutrition for brain recovery after ischemic stroke: an added value to rehabilitation", "Nutrition in Clinical Practice", June 2011
22. Jablonska, A., Lukomska, B., "Stroke induced brain changes: Implications for stem cell transplantation.", "Acta Neurobiologiae Experimentalis", 2011. PMID 21499328
23. Moustafa, R., Momjian-Mayor, I., Jones, P., Morbelli, S., Day, D., Aigbirhio, F., Fyer, T., Warburton, E., Baron, J., "Microembolism Versus Hemodynamic Impairment in Rosary-Like Deep Watershed Infarcts.", "Stoke ", 2011 May 19
24. Titsworth, W., Civelek, A., Abou-Chebi, A., “Use of far field basilar artery stenting for recurrent middle cerebral artery ischemia.”, “Journal of the Society of NeuroInterventional Surgery”, 2010 October 4
25. Liu, S., Levine, S., Winn, H., “Targeting ischemic penumbra: part I from pathophysiology to therapeutic strategy.” “National Institute of Health,” 2010 July 2
26. Hong, HY., Choi, JS., Kim, YJ., Lee, HY., Kwak, W., Yoo, J., Lee, JT., Kwon, TH., Kim, IS., Han, HS., Lee, BH., “Detection of apoptosis in a rat model of focal cerebral ischemia using a homing peptide selected from in vivo phage display,” PMID: 18692101 2008 July 19
27. Liu, S., Levine, S., Winn, H., “Targeting ischemic penumbra: part II: selective drug delivery using liposome technologies.” “National Institute of Health,” 2011 September 7

Division of Work Load

We will each take two or three main points, research them on our own, and add to the page. We will also plan times to meet up and work on the page as a group.