STROKE

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View with images and charts Stroke: A sudden loss of Brain Functioning Chapter - 1

Introduction 1.1

Background of the study

Stroke is a sudden loss of brain function caused by the interruption of blood flow to the brain. Stroke is a leading cause of disability worldwide. Hippocrates first described the sudden paralysis that is often associated with stroke. The word stroke was used as a synonym for apoplectic seizure as early as 1599, and is a fairly literal translation of the Greek term. In 1658, in his Apoplexia, Johann Jacob Wepfer (1620–1695) identified the cause of hemorrhagic stroke when he suggested that people who had died of apoplexy had bleeding in their brains. Wepfer also identified the main arteries supplying the brain, the vertebral and carotid arteries, and identified the cause of ischemic stroke (also known as cerebral infarction) when he suggested that apoplexy might be caused by a blockage to those vessels. 1.2

Stroke

Stroke or cerebrovascular accident (CVA) also called brain attack, is a brain injury caused by a sudden interruption in the blood supply of the brain. It occurs when part of the brain does not receives the needed blood flow for one of two reasons: 1) either the blood supply to part


of the brain is suddenly interrupted, or 2) because a blood clot blocks a blood vessel or artery, or when a blood vessel in the brain ruptures and blood invades the surrounding areas. As a result, the affected area of the brain cannot function, which might result in an inability to move one or more limbs on one side of the body, inability to understand or formulate speech, or an inability to see one side of the visual field. A stroke is a medical emergency and can cause permanent neurological damage, complications, and death. The traditional definition of stroke, devised by the World Health Organization in the 1970s, is a "neurological deficit of cerebrovascular cause that persists beyond 24 hours or is interrupted by death within 24 hours" 1.3 Epidemiology of stroke Stroke is one of the leading causes of long term disability, and of death, in the developed world. Approximately 700,000 Americans per year experience a stroke. It is the third leading cause of death and the leading cause of long-term adult disability in the United States. According to the World Health Organization (WHO) 15 million people suffer from stroke worldwide each year. On average, a stroke occurs every 45 seconds and someone dies from a stroke every 3 minutes. Asymptomatic infarctions, usually lacunar, are present in 7% of MRI scans; 2% of scans detect incidental intracranial aneurysms. Risk factors for stroke include atherosclerosis, advanced age, hypertension (high blood pressure), diabetes mellitus, high cholesterol, cigarette smoking, atrial fibrillation, migraine headaches ethnic identity, and some blood clotting disorders. 1.4 Anatomy of stroke

Figure 1: This is an x-ray image of the head after a radio-opaque dye was injected into the arterial system; the image is called an angiogram. The brain is made out of nerve cells and supporting cells, it is covered by protective layers and it is moistened by the constant circulation of a pristine fluid called "cerebrospinal fluid" (CSF). Like all parts of the body, the brain has vessels that pump blood to it from the heart called arteries and vessels that collect the blood after circulating through the organ for return to the heart called veins. As in most organs of the body, the arteries to the brain carry blood loaded with oxygen and glucose (blood sugar) and the veins carry away blood that has


delivered these vital supplies to the cells of the brain and had their waste products dumped in it. There are special features of the vasculature to the brain that are protective since brain cells are more vulnerable to loss of oxygen and glucose than are the cells of any other portion of the body. One of these features is the circular design of the blood delivery system to the brain. This circle of arteries that joins blood pumped up from the front of the neck ( the carotid arteries) from blood pumped up from the back (the vertebral arteries). In most healthy young people, this system of blood flow is so good that even if one of the arteries is lost altogether (from an injury, for example), the others can make up for it and keep delivering a properly working circulation of fresh arterial blood, and no impairment to the brain cells occurs. 1.5 Classification of Stroke There are three types of stroke .Such as 1. Ischemic stroke. 2. Hemorrhagic infarct 3. Transient ischemic attack (TIA). Ischemic strokes are those that are caused by interruption of the blood supply. Ischemic stroke is the most common type of stroke, and it accounts for 83 percent of all strokes. An ischemic stroke occurs when the blood vessel (usually an artery) supplying blood to a part of the brain is blocked by fatty deposits or a blood clot. In an ischemic stroke, blood supply to part of the brain is decreased, leading to dysfunction of the brain tissue in that area. There are four reasons why this might happen:  Thrombosis (obstruction of a blood vessel by a blood clot forming locally)  A cerebral embolism (embolic stroke) -the blockage is caused by a blood clot, air bubble, or fat globule that forms in a blood vessel somewhere in the body, and it travels through the bloodstream into the brain.  Systemic hypo perfusion (general decrease in blood supply, e.g., in shock)  A blockage occurs in the tiny blood vessels deep within the brain.

Figure 2: A slice of brain from the autopsy of a person who suffered an acute middle cerebral artery (MCA) stroke


There are various classification systems for acute ischemic stroke. The Oxford Community Stroke Project classification (OCSP, also known as the Bamford or Oxford classification) relies primarily on the 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), lacunars 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. The TOAST (Trial of Org 10172 in Acute Stroke Treatment) classification is based on clinical symptoms as well as results of further investigations; on this basis, 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, (4) other determined cause, (5) undetermined cause (two possible causes, no cause identified, or incomplete investigation).

Figure 3: Hemorrhagic Stroke and Ischemic stroke


Hemorrhagic strokes are the ones which result from rupture of a blood vessel or an abnormal vascular structure. Hemorrhagic stroke is a less common type of stroke, and accounts for 17 percent of all strokes. A hemorrhagic stroke occurs when a blood vessel in the brain ruptures and the blood invades the surrounding areas. This type of stroke can be caused by –  An aneurism (a weakened region of a blood vessels balloons out, and left untreated can burst) or  An arteriovenous malformation (a cluster of abnormally formed blood vessels where one of the vessels bursts). There are two types of hemorrhagic strokes:  Intracerebral hemorrhage, the blood vessel ruptures within the brain.  Subarachnoid hemorrhage, the blood vessel bursts on the surface of the brain, and it bleeds into the area between the brain and the skull.

Figure 4: An intraparenchymal bleed (bottom arrow) with surrounding edema (top arrow) Intracranial hemorrhage is the accumulation of blood anywhere within the skull vault. A distinction is made between intra-axial hemorrhage (blood inside the brain) and extra-axial hemorrhage (blood inside the skull but outside the brain). Intra-axial hemorrhage is due to intraparenchymal hemorrhage or intraventricular hemorrhage (blood in the ventricular system). The main types of extra-axial hemorrhage are epidural hematoma (bleeding between the Dura mater and the skull), subdural hematoma (in the subdural space) and subarachnoid hemorrhage (between the arachnoids mater and pia mater). Most of the hemorrhagic stroke syndromes have specific symptoms (e.g., headache, previous head injury). Transient ischemic attack (TIA): Transient ischemic attack (TIA), also called ministroke, is a minor or warning stroke. It occurs when the blood supply to the brain is briefly interrupted. This stroke is similar with the ischemic stroke, but its symptoms tend to disappear within the next 24 hours. The obstruction (blood clot), that causes the transient ischemic attack, occurs for a short time and tends to resolve itself in time. A mini-stroke last


for a few minutes up to a day and, in some cases, it can be accompanied by typical stroke signs. Even if the symptoms disappear in a short time, a transient ischemic attack is a strong indicator of a possible major ischemic stroke to come.

1.6

Signs and Symptoms of a Stroke

A stroke often appears suddenly, without warning, and its effects on the body are immediate. The common symptoms of a stroke, which appear afterwards, include:  Sudden numbness, weakness, clumsiness, or paralysis on one side of the body. An example of this symptom can be a dropping arm or leg, eyelid, or dribbling mouth. This is one of the most common and recognizable stroke symptoms. This symptom affects only one side of the body and causes difficulties in controlling the arm or leg. In the worst cases, the weakness or paralysis is accompanied by muscle and joint stiffness.  Sudden confusion, slurred speech, trouble speaking, or understanding speech. This is another common symptom in patients that had a stroke. This symptom also includes difficulties reading and writing.  Sudden blurred vision or loss of sight in one or both eyes. The stroke can damage that part of the brain that receives, processes, and interprets the information sent by the eyes to the brain. This can lead to a variety of problems such as double vision, or losing half of the vision field.  Sudden trouble walking, dizziness, loss of balance, or loss of coordination.


 Sudden severe headache with no known cause.  Loss of balance or unsteadiness. This can be the result of damage in the part of the brain responsible with the body's balance, or as a result of paralysis when the muscles become weak.  Dysphasia or difficulties swallowing is another common symptom in patients with stroke. About 50 percent of those that have a stroke have swallowing problems.  Perception and interpretation difficulties. People that suffered a stroke have difficulties recognizing familiar objects or knowing how to use them.  Mental processes impairment. After a stroke, the person can have problems thinking, learning, remembering, concentrating, making decisions, reasoning, and planning. 

Incontinence (difficulties controlling the bladder and bowel) can be common right after a stroke, but the problem resolves itself over.

 Mood swings. People that suffer a stroke experience emotional ups and downs. They can become depressed, sad, angry, anxious, experience low self-esteem and low confidence. Associated symptoms

1.7

 Loss of consciousness,  Headache, and 

Vomiting usually occurs more often in hemorrhagic stroke than in thrombosis because of the increased intracranial pressure from the leaking blood compressing the brain.

 If symptoms are maximal at onset, the cause is more likely to be a subarachnoid hemorrhage or an embolic stroke. 1.8

Causes of stroke


There are many different causes of stroke, but whenever a stroke occurs, there has been an interruption of the normal blood supply to brain cells that has gone on long enough to cause death to at least some of them. If the loss is so brief that the brain tissue can quickly recover, and does not die, then a Transient Ischemic Attack (TIA) has occurred, rather than a stroke. The symptoms and signs of a stroke are highly dependent upon the number of cells that are affected, and exactly where these cells are located in the brain. Accordingly, strokes can have many different clinical presentations - ranging from deep coma with the loss of the ability to breathe; to very limited deficits in the ability to move a part of the body, or changes in sensory perception like partial blindness from a restriction in visual field, without any associated problems with movement. Ordinarily, at least some brain tissue is injured by a stroke - yet not killed. The injury to these cells is reversible. That's one reason why the amount of recovery during the initial time period after a stroke is difficult to predict, and also why treatment at that time can influence the course of recovery. If the stroke patient survives the stroke, some brain cells may actually recover in time if the injury was not too great. Ten causes of stroke identified by researchers. Scientists have found ten key health problems that cause almost all strokes. ďƒ˜ High blood pressure,


 Smoking,  A fat stomach,  Poor diet,  Lack of physical activity,  High levels of bad cholesterol,  Diabetes,  Drinking too much,  Stress and depression and  Heart disorders accounted for 90 per cent of strokes. The research conducted by a team at McMaster University on Ontario, Canada, is one of the most comprehensive looking into the causes of stroke. The factor with the strongest link was high blood pressure which more than doubled the risk of a stroke, they said. Around 150,000 people in Britain each year suffer a stroke and there are 67,000 deaths. It is a leading cause of disability. The study published in The Lancet and presented at The World Congress of Cardiology in Beijing looked at 3,000 people who had a stroke and 3,000 similar people who had not suffered a stroke. They were questioned about:  Their lifestyle,  Including how much they drank,  Who much exercise they did and  Their diets given a score according to how healthy they were and tests and measurements were carried out by professionals. Alcohol intake was categorized as never or former drinker, moderate drinker of between one and 30 drinks a month, more than 30 drinks a month and binge drinker who had more than five drinks in one day in the last month. They were classed as physically active if they were involved in walking, cycling, gardening, jogging, football or vigorous swimming for four hours a week or more. The findings showed that current smokers doubled their risk of stroke, poor diet increased the risk by 35 per cent, 30 or more drinks a month or binge drinking increased the risk by half, stress raised the risk by 30 percent and depression by 35 per cent. Being active reduced the risk by about 30 per cent. Martin O'Donnell, lead author said: "Our findings suggest that ten simple risk factors are associated with 90% of the risk of ischemic and intracerebral hemorrhagic stroke worldwide.”Targeted interventions that reduce blood pressure and smoking, and promote physical activity and a healthy diet, could substantially reduce the global burden of stroke."Andrea Lane, Spokesperson for The Stroke Association said: "Over the years there have been a number of research studies into the causes of stroke, which have identified a number of major risk factors.”This is an extensive and in-depth study


and so it's great to see that the findings support previous research and reflect the preventative advice provided by The Stroke Association."

1.9

Effects of Strokes

The most common problems in daily life are likely to be caused by:  Weakness or lack of movement (paralysis) in legs and/or arms  Shoulder pain.  Trouble swallowing  Changes to way things are seen or felt (perceptual problems)  Changes to the way things are felt when touched (sensory problems)  Problems thinking or remembering (cognitive problems)  Trouble speaking, reading or writing,  Incontinence,  Feeling depressed,  Problems controlling feelings,  Tiredness The specific abilities that will be lost or affected by stroke depend on the extent of the brain damage and, most importantly, where, in the brain, the stroke occurred: the right hemisphere (or half), the left hemisphere, the cerebellum or the brain stem. Each stroke is different and each person that experiences a stroke is affected differently. Some stroke survivors experience mild symptoms, while other faces severe and lasting damage. Once the stroke occurs, the brain immediately undergoes changes. Without the blood supply which provides the brain with nutrients and oxygen, the brain cells are damaged and can die. Once dead, the


cells cannot return to life, but the surrounding areas can recover and take over or substitute some of the lost functions. Usually, the recovery process happens in the first few months that follows the stoke, but in some cases can continue for several years. The disability level differs from patient to patient, and depends on the type of stroke suffered, the area affected, the location of the affected area, and the extent of the damage. A stroke can occur in any part of the brain causing damages according to those functions controlled by that area. Each part of the brain is involved in different essential functions for the body. Usually, the stroke symptoms and signs occur on the opposite side of the body to the stroke side of the brain. The human brain is divided in four main parts: (1) the right hemisphere, (2) the left hemisphere, (3) the cerebellum, and (4) the brain stem. In most people, the right hemisphere is responsible for perceptual and spatial skills, the left hemisphere is responsible for language, the cerebellum controls balance and coordination, while the brain stem controls those body functions that do not require conscious control (such as breathing rate, blood pressure, heart rate, eye movement, hearing, speech, and swallowing). The effects of a stroke can be divided into two main categories: (1) Body functions. (2) Cognitive functions. Effects of Right Hemisphere Strokes

The right hemisphere of the brain controls the movement of the left side of the body so stroke in the right hemisphere often causes paralysis in the left side of the body. This is known as left hemiplegic. Survivors of right-hemisphere strokes may also have problems with their spatial and perceptual abilities. This may cause them to misjudge distances (leading to a fall) or be unable to guide their hands to pick up an object, button a shirt or tie their shoes. They may even be unable to tell right side up from upside-down when trying to read. Along with these physical effects, survivors of right-hemisphere strokes often have judgment difficulties


that show up in their behaviour. They often act impulsively, unaware of their impairments and certain of their ability to perform the same tasks as before the stroke. This can be extremely dangerous. It may lead them to try to walk without aid or to try to drive a car. Survivors of right-hemisphere strokes may also experience left-sided neglect. This is a result of visual difficulties that cause them to "forget" or "ignore" objects or people on their left side. Some survivors of right-hemisphere strokes will experience problems with short-term memory. Although they may be able to recall a visit to the seashore that took place 30 years ago, they may be unable to remember what they ate for breakfast that morning. Effects of Left Hemisphere Strokes The left hemisphere of the brain controls the movement of the right side of the body. It also controls speech and language abilities for most people. A left-hemisphere stroke often causes paralysis of the right side of the body. This is known as right hemiplegic. Someone who has had a left-hemisphere stroke may also develop aphasia. Aphasia is a catch all term used to describe a wide range of speech and language problems. These problems can be highly specific, affecting only one part of the patient's ability to communicate, such as the ability to move their speech-related muscles to talk properly. The same patient may be completely unimpaired when it comes to writing, reading or understanding speech. In contrast to survivors of right-hemisphere stroke, patients who have had a left-hemisphere stroke often develop a slow and cautious behaviour. They may need frequent instruction and feedback to finish tasks. Patients with left-hemisphere stroke may develop memory problems similar to those of right-hemisphere stroke survivors. These problems can include shortened retention spans, difficulty in learning new information and problems in conceptualizing and generalizing. Effects of Brain Stem Strokes

Strokes that occur in the brain stem are especially devastating. The brain stem is the area of the brain that controls all of our involuntary functions, such as breathing rate, blood pressure and heart beat. The brain stem also controls abilities such as eye movements, hearing, speech and swallowing. Since impulses generated in the brain's hemispheres must travel through the brain stem on their way to the arms and legs, patients with a brain stem stroke may also develop paralysis in one or both sides of the body. Effects of Cerebellum Strokes


The cerebellum controls many of our reflexes and much of our balance and coordination. A stroke that takes place in the cerebellum can cause abnormal reflexes of the head and torso, coordination and balance problems, dizziness, nausea and vomiting. Effect of stroke on vision

Visual problems are more common in people who have suffered a stroke affecting the right side of their brain. The damage the stroke does in the brain impacts the visual pathways of the eye which can result in visual field loss, blurry vision, double vision and moving images. When stroke affects the areas of the brain that processes the information we see, it can cause 'visual neglect' (lack of awareness to one half of the body or space) as well as difficulties with judging depth and movement. In a few cases, visual problems caused by stroke can improve on their own with time. Some of the vision problems that occur as a result of a stroke include loss of part of vision or loss of visual field. Visual field is the term used to describe the whole of our vision, from the centre to the periphery. It refers to everything we can see in the periphery (around the edges of our vision) as well as what we are directly looking at (central vision). Strokes can cause whole sections of the visual field to be missing. Other visual problems that may occur as a result of stroke include eye muscle and nerve problems which can result in double vision and moving images as well as other effects such as sensitivity to light.


Other Effects of Stroke Depression is very common amongst people who have had a stroke. It can be quite severe, affecting both the survivor and his/her family. A depressed person may refuse or neglect to take medications, may not be motivated to take part in physical rehabilitation or may be irritable with others. This in turn makes it difficult for those who wish to help, and tends to deprive the survivor of valuable social contacts that could help dispel the depression. In time the depression may lift gradually, but counseling and appropriate medication may be necessary. In the past, researchers speculated that some of the older anti-depressant drugs might interfere with a person's mental performance but recent studies suggest that anything that can effectively treat post-stroke depression, whether an old or new treatment, may also improve mental ability and enhance rehabilitation. Sudden laughing or crying for no apparent reason and difficulty controlling emotional responses also affects many stroke survivors. There may be little happiness or sadness involved, and the excessive emotional display will end as quickly as it started. Apparent changes in personality following a stroke may be very disturbing to the survivor’s family. Stroke affected people may not seem the same person as before. The way in which they think, feel and react may be altered. Problems and activities once tackled easily may be difficult or impossible, while other tasks are unaffected. The way in which the person affected by stroke reacts to these changes will affect their personality, and may cause changes in control of emotions and behaviour. People affected by stroke may become confused, self-centered, uncooperative and irritable, and may have rapid changes in mood. They may not be able to adjust easily to anything new and may become anxious, annoyed or tearful over seemingly small matters. 1.10 Complications after Stroke Common complications of a stroke: • Edema - brain swelling • Seizu Breathing food into the airway (aspiration) •

Dementia

Falls

Loss of mobility

Loss of movement or feeling in one or more parts of the body

Muscle spasticityres - abnormal electrical activity in the brain, which causes convulsions

Clinical depression - a treatable illness that causes uncontrollable emotional and physical reactions to changes and losses

Bedsores - ulcers that result from a decreased ability to move


Limb contractures - shortened muscles in arms or legs that are caused by a reduced range of motion or lack of exercise

Shoulder pain - a consequence of lack of support or exercise of the arm

Blood vessel problems - formation of blood clots in the veins

Urinary tract infection and bladder control - urgency and incontinence

Pneumonia - results in breathing problems.

Poor nutrition

Pressure sores

Problems speaking and understanding

Problems thinking or focusing.

Chapter - 2 Risk factors for stroke

Stroke risk factors are medical conditions or behaviors or traits that make you more likely to develop a stroke. Having one or more risk factors does not mean that you definitely will have a stroke, only that you are more likely to do so. More than 750 thousand people suffer from stroke in the U.S. each year, but up to 50% of strokes could be prevented. In the case of stroke, many of the risk factors can be treated, modified or controlled. However, some risk factors for stroke cannot be changed. Knowing ones risk factors is the first step in preventing stroke. One can change or treat some risk factors, but others can’t. By having regular medical checkups and knowing the risk, one can focus on what can change and lower risk of stroke. 2.1 Risk factors of stroke that can't control  Age: The risk of stroke increases with advancing age.  Ethnicity: People of First Nations, African, Hispanic, and South Asian descent have greater rates of high blood pressure and diabetes. These conditions increase the risk of stroke.


 Family history: The risk of stroke may be higher if a parent or sibling has had a stroke before the age of 65.  Gender: In most age groups, more men than women have stroke, but more women die from stroke. Men have a higher risk of stroke than women who have not reached menopause.  Heredity and race: People whose close blood relations have had a stroke have a higher risk of stroke. African Americans have a higher risk of death and disability from stroke than whites, because they have high blood pressure more often. Hispanic Americans are also at higher risk of stroke.  Prior stroke or transient ischemic attack (TIA): Someone who has had a stroke is at higher risk of having another one. Up to one-third of people who survive a first stroke or TIA will have another stroke within 5 years. 2.2 Risk factors of stroke that can control  Hypertension (High blood pressure).  Atrial fibrillation( an abnormal heart rhythm)  Cigarette smoking.  Excessive alcohol intake  Obesity, unhealthy diet  High cholesterol  Diabetes.  Physical inactivity.  Stress.

Hypertension (High Blood Pressure)


High blood pressure is the most important modifiable risk factor for stroke. The risk of stroke increases 4 to 6 times when the person has high blood pressure. The blood pressure measures the force of blood pushing against the walls of the arteries. When the blood pressure is high, the heart has to pump harder to move the blood through the body, which leads to weak blood vessels and damage to major organs in the body. Normal blood pressure is 120/80 or below, whiles a blood pressure reading of 140/90 and above is considered high blood pressure (or hypertension). Atrial fibrillation (an abnormal heart rhythm)

Atrial Fibrillation (AF) is a medical condition where the heart beats irregularly because the two upper chambers of the heart beat rapidly and unpredictably. Atrial fibrillation increases the risk of stroke up to 6 times because the heart does not fully pump the blood out, which pools in the heart. When the blood pools in the heart, the risk of blood clots forming is high. Once formed, these blood clots will travel through the bloodstream into the brain obstructing a blood vessel.

Cigarette Smoking


Tobacco use damages blood vessels. Don’t smoke and avoid second-hand smoke. This can contribute to atherosclerosis and can also cause the blood vessels to constrict, which leads to restrictions in blood flow. Smoking increases the heart rate and blood pressure. The associated risk increases with the number of cigarettes smoked per day, and passive smoking also increases this risk. Excessive alcohol intake

It is thought that excessive alcohol intake may also increase the risk of ischemic stroke by bringing about a rise in blood pressure. However, although drinking too much alcohol is known to inflate the risk, people who consume moderate amounts (less than 3 units per day) actually have a lower risk than those who do not drink at all. This may be because moderate alcohol intake can improve blood lipid levels, and so protect against vascular diseases such as stroke. Obesity, unhealthy diet


Being obese or overweight increases the risk of high blood pressure, high cholesterol, diabetes, heart disease, which all increase the risk for stroke. Unhealthy diet (including a low fruit and vegetable intake and a high salt intake). High cholesterol

Cholesterol is a waxy, fat-like substance produced by the liver and is used in different functions essential for the body. If present in high amounts, cholesterol builds up in the veins and clogs them (a condition called atherosclerosis). The build-up of plaque inside the artery causes the walls to lose their elasticity and become weak and hard.

Figure 5: Image of High Cholesterol


Diabetes

Diabetes is a medical condition where the body either does not produce enough insulin, or the insulin is not properly used. This disease is another major cause of stroke because the body can't properly process sugar (the basic fuel of the body's cells) and fats. Diabetes also leads to other medical complications such as high blood pressure, high cholesterol, atherosclerosis, and obesity or excessive weight. Diabetes interferes with the body's ability to break down blood clots, which leads to an increased risk of ischemic strokes. In general, those that suffer from diabetes have a 2 to 4 times the risk of stroke than the non-diabetic population. Physical Inactivity

In epidemiological studies comparing highly active to sedentary individuals, physical activities are observed to reduce the risk of both ischemic and hemorrhagic strokes. The 2008 Physical Activity Guidelines for Americans concur in recommending regular physical activity to reduce adverse health outcomes. In this guideline, most health benefits occur with at least 150 minutes a week of moderate intensity, or 75 minutes a week of vigorous intensity of aerobic physical activity. When adults with disabilities are not able to meet these guidelines, they should engage in regular physical activity according to their abilities, and they should avoid inactivity. Exercise reduces blood pressure, decreases body weight, and improves other risk factors, including metabolic syndrome the role of the health provider is important and the physician’s advice regarding physical activity to patients can significantly modify exercise and diet style, including those with a prior stroke. One recent observation of note is associated with the onset of stroke with physical activity. There might be an increased risk of stroke occurrence within 1 hour of moderate or vigorous physical activity.


Drug abuse (certain kinds)

Intravenous drug abuse carries a high risk of stroke from cerebral embolisms (blood clots). Cocaine use has been closely related to strokes, heart attacks, and a variety of other cardiovascular complications. Some of them, even among first-time cocaine users, have been fatal. Cardiac structural abnormalities

Damaged heart valves can cause chronic heart damage, which can ultimately increase the risk of developing stroke. This is known as valvular heart disease. New evidence shows that heart structure abnormalities including patent foramen ovale and atrial septal defect may possibly increase risk for embolic stroke. 2.3 Risk factors for Ischemic stroke In general, the risk factors for having an ischemic stroke - a stroke that is caused by a blockage in an artery supplying the brain - may be divided into those that can be modified (improved upon), and those that cannot, as discussed below.Although some risk factors cannot be changed - for example, a person's gender or age - it is still important to be aware of them. This is because people who have a number of unmodifiable risk factors may benefit from making a greater effort to improve those risk factors that can be modified.In addition to these risk factors, which are often classed as 'traditional', we are also starting to learn about more recently identified risk factors.


Modifiable risk factors for Ischemic stroke Fortunately, we do have control over many of the risk factors for ischemic strokes. These include the following: • •

High blood pressure - the most important modifiable risk factor for stroke Smoking - this can contribute to atherosclerosis and can also cause the blood vessels to constrict, which leads to restrictions in blood flow. The associated risk increases with the number of cigarettes smoked per day, and passive smoking also increases this risk

Excessive alcohol intake

Obesity, unhealthy diet (including a low fruit and vegetable intake and a high salt intake)

Physical inactivity

Abnormal lipid levels (dyslipidaemia)

Diabetes mellitus (associated with stroke and other forms of vascular disease at a younger than average age) and metabolic syndrome

Carotid artery disease

Atrial fibrillation, an abnormal heart rhythm

Patent foramen oval (otherwise known as a 'hole in heart') - present in around 25 per cent of the general population, compared with 40 per cent of people who have had a stroke where no other cause is found

Heart failure, endocarditis and other forms of heart disease

Oral contraceptives - thought to increase the likelihood of the blood to clot

Polycythaemia, a condition in which the red blood cell count is increased

Sleep apnoea, which causes interruptions in breathing while a person sleeps and appears to be associated with a higher risk of stroke and other cardiovascular diseases

Sickle cell disease, an inherited condition that results in the formation of abnormal, sickle-shaped red blood cells that can block small blood vessels, increasing the risk of an ischemic stroke. There is insufficient evidence to support the suggestion that sickle cell trait - a milder version of the disease - might also increase the risk.

It is thought that excessive alcohol intake may also increase the risk of ischemic stroke by bringing about a rise in blood pressure. However, although drinking too much alcohol is known to inflate the risk, people who consume moderate amounts (less than 3 units per day) actually have a lower risk than those who do not drink at all. This may be because moderate alcohol intake can improve blood lipid levels, and so protect against vascular diseases such as stroke.


Non-modifiable risk factors for Ischemic stroke Risk factors for stroke that cannot be modified include the following: • •

Male gender Older age

Family history

Past heart attack or stroke

Ethnicity.

It has also been suggested that migraine may increase the risk of an ischemic stroke, particularly in women under the age of 35. Migraine with aura (in other words, migraine accompanied by additional symptoms such as visual disturbance and numbness or tingling) is associated with reduced blood flow to the brain and inflammation. Transient ischemic attack, or TIA, is often referred to as a 'mini-stroke'. Like a stroke, it is a disturbance in the function of the nervous system that is caused by a problem with the blood supply to the brain. However, unlike stroke, the symptoms of TIA settle down within 24 hours. People who have had a TIA are known to have a higher risk of a stroke in the future. The chance of someone who's had a TIA having a stroke within 3 months has been estimated to be between 15 and 20 per cent. Conditions that increase the likelihood of the blood to clot also increase the risk of stroke; examples include Factor V Leiden mutation and Hughes syndrome (also known as anti phospholipid syndrome), although these risks may be reduced by taking anticoagulant treatment. Recently identified risk markers Additional markers (indicators) associated with an increased risk of ischemic stroke include elevated levels in the blood of: • •

Homocysteine (a marker that is associated with early-onset atherosclerosis) Lipoprotein(a) (a type of lipid in the bloodstream that is similar to LDL-cholesterol)

High-sensitivity C-reactive protein (CRP; a protein in the blood that suggests inflammation)

High blood levels of fibrinogen (a protein that helps the blood to clot)

Apolipoprotein B (APOB; the protein part of low-density lipoprotein (LDL).

2.4 Risk factors for Hemorrhagic stroke


Some of the risk factors for a hemorrhagic stroke - a stroke caused by a bleed - differ from those of an ischemic stroke and so are looked at separately. Modifiable risk factors for Hemorrhagic stroke Those risk factors for hemorrhagic stroke that we can improve upon include: • •

High blood pressure - one of the most important modifiable risk factors for stroke Impaired ability of the blood to clot due to medication ('anti-clotting' drugs, anticoagulants; or 'clot-busting' drugs, thrombolytic)

Smoking, excess alcohol intake and substance misuse (for example, amphetamines and cocaine)

Lipid levels. Unlike ischemic strokes, it seems that reducing cholesterol levels actually increases the risk of hemorrhagic strokes

Vascular malformations. These may include arteriovenous malformations, cavernous haemangiomas and aneurysms (an aneurysm is an abnormal dilation, or bulge, in the wall of an artery.) Vascular malformations are prone to rupture. Fortunately, they can sometimes be treated with surgery to reduce the risk.

Conditions that interfere with blood clotting, for example, blood dyscrasia (an abnormality in the balance of the different components of the blood). Treatment may lower the risk.

Non-modifiable risk factors for Hemorrhagic stroke The risk factors for hemorrhagic stroke that cannot be modified include the following: •

Increasing age. This may be partly because older age is associated with small blood vessel disease, which can increase the risk of blood vessel rupture. Increasing age also increases the likelihood of the condition amyloid angiopathy, which leads to protein build-up in the arteries of the brain, increasing the risk of bleeding. Ethnicity.

Symptoms similar to a stroke can also sometimes arise as a result of damage to blood vessels in the brain following a head injury. 2.5 Other risk factors that can lead to a stroke  Other factors such as oral contraceptive use


 Hormone replacement therapy or 

Pregnancy and childbirth in women with pre-existing medical conditions may increase the risk of stroke in specific cases.

 Other medical conditions such as amyloid angiopathy and antiphospholipid antibody syndrome  Use of illicit drugs such as cocaine or LSD.  Some medications, such as tamoxifen, phenylpropanolamine, and thrombolytic. In general, the risk factors for having an ischaemic stroke - a stroke that is caused by a blockage in an artery supplying the brain - may be divided into those that can be modified (improved upon), and those that cannot, as discussed below. Although some risk factors cannot be changed - for example, a person's gender or age - it is still important to be aware of them. This is because people who have a number of unmodifiable risk factors may benefit from making a greater effort to improve those risk factors that can be modified.In addition to these risk factors, which are often classed as 'traditional', we are also starting to learn about more recently identified risk factors. Some of the risk factors for a hemorrhagic stroke - a stroke caused by a bleed - differ from those of an ischemic stroke and so are looked at separately. 2.6 Self Assessment Chart of Stroke Risk This is just a guide, but it demonstrates measures that can take to decrease your risk of stroke.


Risk Factors

0

1

2

3

Smoking

quit after current current smoking for never smoked smoker less smoker more less than 5 than 20/day than 20/day years

Exercise

1 hour strenuous very active moderately very little activity at once or twice active once or physical least 3 times a week twice a week activity per week

Diabetes

none known

n/a

Blood Pressure

normal

moderate high mild high blood pressure severe high blood pressure blood pressure

Age

0 - 44

45 - 64

Alcohol (male)

0-4 standard up to drinks/week drinks/day

family history diabetic

65 - 74

75 +

more than 4 more than 6 4 drinks a day 2 drinks, 4 or or more days a more days a week week

more than two more than 4 Alcohol (female) 0-2 standard up to 2 drinks drinks a day, 2 drinks, 4 or drinks a week a day or more days a more days a week week Weight

about average slightly for height overweight

moderately overweight

Family History

a relative has several no strokes a relative has had a stroke relatives have known had a stroke while younger suffered from than 65 stroke

Cholesterol

below average average

moderately raised

obese

severely raised

Score


Chapter - 3 3.1 Mechanisms of Stroke 3.1.1 Biophysical Mechanisms of Stroke Although the consequences of both ischemic and hemorrhagic stroke are similar in that a vessel obstruction and the resultant reduced blood flow to the brain may lead to neurological deficits and possibly death, the biophysical and hemodynamic mechanisms behind the obstruction of blood flow are different. Biophysical mechanisms for the development of obstructions that ultimately lead to stroke can arise by six distinct processes: atherosclerosis, embolus, thrombus, reduced systemic pressure, hemorrhage, and vasospasm. Atherosclerosis Atherosclerosis, commonly referred to as “hardening of the arteries,” is a pathological process in which calcified lipid or fatty deposits from the flowing blood accumulate circumferentially along the innermost intimal layer of the vessel wall (Fig 1⇓). Atherosclerotic plaques are found almost exclusively at the outer wall (hip) of one or both daughter vessels at major bifurcations, including the carotid. Atherosclerosis and the development of arterial plaques are the product of a host of independent biochemical processes including the oxidation of low-density lipoproteins, formation of fatty streaks, and the proliferation of smooth muscle cells. As the plaques form, the walls become thick, fibrotic, and calcified, and the lumen narrows, reducing the flow of blood to the tissues the artery supplies. .

Figure 6 : Schematic diagram of the distribution of atherosclerotic plaque along the inner wall of the carotid artery bifurcation. Atherosclerotic deposits promote the development of blood clots or the process of thrombosis due in part to flow obstruction and to high shear stresses exerted on the vessel wall by the blood. High wall shear stress might mechanically damage the inner wall of the artery, initiating a lesion. On the other hand, low wall shear stress might encourage the deposition of particles on the artery wall, promoting the accumulation of plaque. Turbulence has also been implicated in atherosclerotic disease both because it can increase the kinetic energy deposited in the vessel walls and because it can lead to areas of stasis, or stagnant blood flow, that


promote clotting. In addition, the presence of atherosclerotic lesions introduces an irregular vessel surface that, as a result of turbulent blood flow, can cause the dislodgment of plaques of varying size into the bloodstream until the plaque lodges into a vessel of smaller size, preventing further passage of blood flow. Atherosclerotic thrombosis accounts for 33% of all stroke cases. Embolus An embolus represents gaseous or particulate (eg, atheromata) matter that acts as traveling “clots.” A common example of emboli is a platelet aggregate dislodged from an atherosclerotic lesion. The dislodged platelet aggregate is transported by the bloodstream through the cerebrovasculature until it reaches vessels too small for further propagation. The clot has nowhere to go and remains there, clogging the vessel and preventing blood flow from entering the distal vasculature. Although our discussion at the present is focused primarily on the carotid arteries and associated cerebrovasculature, emboli can originate from distant sources such as the heart, lungs, and peripheral circulation, which could eventually travel within the cerebral blood vessels, obstructing flow and causing stroke. Other sources of emboli include atrial fibrillation and valvular disease. The severity of stroke depends on the size of the embolus and the location of the obstruction. The bigger the embolus and the larger the vessel obstruction, the larger the territory of brain at risk. Approximately 31% of all stroke cases are attributed to emboli. Thrombus Thrombosis is an internal physiological mechanism responsible for the clotting of blood. A thrombus is a blood clot, an aggregation of platelets and fibrin formed in response either to an atherosclerotic lesion or to vessel injury. In response to vessel or tissue injury, the blood coagulation system is activated, which initiates the following cascade of processes transforming prothrombin and resulting in a fibrin clot: Prothrombin⇒Thrombin⇒Fibrinogen⇒ Fibrin⇒Fibrin Clot Although a host of mechanisms and causes are responsible for vessel injury, vessel injury can occur as a result of forces (shear stresses)7 coupled with the excess energy created by the turbulent flow8 9 10 exerted against the inner (intimal) lining of the vessel wall, particularly an atherosclerotic vessel wall. Approximately 33% of all stroke cases are attributed to thrombi. Reduced Systemic Pressure The previously described mechanisms of blood flow obstruction leading to stroke occur along localized regions of the cerebral arteries. It is assumed in this instance that the heart is functioning normally under proper systemic pressure. Cardiovascular diseases such as atrial fibrillation and myocardial infarction weaken the cardiac wall and introduce abnormalities in the physiological function of the heartbeat, which ultimately result in reduced systemic pressure and conditions of ischemia. Hemorrhage Blood vessels are typically structurally adept to withstand the dynamic quantities required to maintain circulatory function. For reasons that are not entirely understood, the vessel wall can


become fatigued and abnormally weak and possibly rupture. With vessel rupture, hemorrhage occurs with blood seeping into the surrounding brain tissue. As the blood accumulates within the brain, the displaced volume causes the blood, now thrombosed, to ultimately compress the surrounding vessels. The compression of vessels translates into a reduced vessel diameter and a corresponding reduction in flow to surrounding tissue, thereby enlarging the insult. Among the vascular lesions that can lead to hemorrhagic strokes are aneurysms and arteriovenous malformations (AVMs). Brain Aneurysms A brain aneurysm, shown in Fig 2⇓, is a form of cerebrovascular disease that manifests itself as a pouching or ballooning of the vessel wall. The vascular dilatation develops at a diseased site along the arterial wall into a distended sac of stressed and thinned arterial tissue. The fully developed cerebral aneurysm typically ranges in size from a few millimeters to 15 mm but can attain sizes greater than 2.5 cm. If left untreated; the aneurysm may continue to expand until it ruptures, causing hemorrhage, severe neurological complications and deficits, and possibly death. In the United States, approximately 28 000 aneurysms rupture each year; approximately 50% of these patients die or become permanently disabled as a result of the initial hemorrhage, and another 25% to 35% die of a future hemorrhage. Blood flow in most aneurysms is regular and predictable primarily according to the geometric relationship between the aneurysm and its parent artery. As blood flows within the parent artery with an aneurysm, divergence of blood flow, as occurs at the inlet of the aneurysm, leads to dynamic disturbances with a Bernoulli Effect, producing increased lateral pressure and retrograde vortices that are easily converted to turbulence. 13 Blood flow proceeds from the parent vessel into the aneurysm at the distal or downstream extent of the aneurysm neck, circulates around the periphery along the aneurysm wall from the neck to the top of the fundus (downstream to upstream), returning in a type of “isotropic shower� along the aneurysm wall toward the neck region, and exits the proximal or closest extent of the aneurysm neck into the parent vessel. As flow persists, areas of stagnation or vortices develop within a central zone of the aneurysm. These rotating vortices, formed at the entrance to the aneurysm at each systole and then circulated around the aneurysm, are caused by the slipstreams or regions of recirculating flow rolling upon themselves when they enter the aneurysm at its downstream wall during systole. The stagnant vortex zone occurs in the center and at the fundus or upper portion of the aneurysm and becomes more pronounced in larger aneurysms. It is this stagnant zone that is believed to promote the formation of thrombi or blood clots, particularly in giant aneurysms. Brain Arteriovenous Malformations The normal human circulation originates from the heart and consists of a branching arrangement of arteries of continually decreasing size until they feed into a capillary bed before exiting the bed through small veins that increase in size before returning to the heart. The capillary bed serves an important purpose in that its vascular resistance slows the flow of blood considerably to allow perfusion of oxygen and nutrients to surrounding tissue and removal of cellular waste. In one form of cerebrovascular disease, AVMs, the vessels constituting the capillary bed of the brain become malformed during embryonic development and prohibit the opportunity for blood to properly perfuse into the surrounding tissue.


AVMs, shown in Fig 3⇓, are congenital vascular lesions that occur as a result of capillary maldevelopment between the arterial and venous systems. Approximately 0.14% of the United States population has an intracranial AVM that poses a significant risk and represents a major life threat, particularly to persons under the age of 50 years. The vessels constituting the AVM are weak and enlarged and serve as direct shunts for blood flow between the highpressure arterial system and the low-pressure venous system, corresponding to a large pressure gradient and small vascular resistance. The abnormal low-resistance, high-flow shunting of blood within the brain AVM without an intervening capillary bed causes the fragile dilated vessels in the nidus to become structurally abnormal and fatigued, to further enlarge, and possibly to rupture.

Figure 7: A, MR angiogram of a human arteriovenous malformation. B, Schematic diagram of a brain arteriovenous malformation, depicting the structural and angioarchitectural components. The abnormal microvessels of an AVM serve as passive conduits for blood flow from the arterial circulation directly to the venous circulation, bypassing their normal physiological function of brain tissue perfusion. The hemodynamic consequences of an AVM occur as a result of two interdependent circulatory mechanisms involved in the shunting of blood between artery and vein. In the normal cerebral circulation, blood flows under a high cerebrovascular resistance and high cerebral perfusion pressure. However, the presence of a brain AVM in the normal circulation introduces a second abnormal circuit of cerebral blood flow where the blood flow is continuously shunted under a high perfusion pressure through the AVM, possessing a low cerebrovascular resistance and low venous pressure. The clinical consequence of the abnormal shunt is a significant increase in blood returning to the heart (≈4 to 5 times the original amount, depending on the diameter and size of the shunt), resulting in a dangerous overload of the heart and possible cardiac failure. Volumetric blood flow through an AVM ranges from 200 mL/min to 800 mL/min and increases according to nidus size. The abnormal shunting of blood flow by brain AVMs rapidly removes or “steals” blood from the normal cerebral circulation and substantially reduces the volume of blood reaching the surrounding normal brain tissue. This phenomenon, known as cerebrovascular steal, depends on the size of the AVM and is the most plausible explanation for the development of progressive neurological deficits. Cerebrovascular steal could translate into additional neurological complications developed as a result of cerebral ischemia or stroke in neuronal territories adjacent to an AVM.


Vasospasm When bleeding occurs in the subarachnoid space, the arteries in the subarachnoid space can become spastic with a muscular contraction, known as cerebral vasospasm. The contraction from vasospasm can produce a focal constriction of sufficient severity to cause total occlusion. The length of time that the vessel is contracted during vasospasm varies from hours to days. However, regardless of the duration of vessel constriction during vasospasm, reduction of blood flow induces cerebral ischemia, thought to be reversible within the first 6 hours and irreversible thereafter. It has been shown that vasospasm is maximal between 5 and 10 days after subarachnoid hemorrhage and can occur up to 2 weeks after subarachnoid hemorrhage. The resultant damage to brain tissue can be minimized with the administration of pharmacological agents such as the vasodilator papaverine. 3.1.2 Inflammatory Mechanisms of Stroke

Basic and clinical research provides evidence that inflammatory mechanisms play a central role in the pathogenesis and progression of atherosclerosis, plaque rupture, thrombosis, and stroke. Inflammatory biomarkers such as high-sensitivity C-reactive protein have been identified as predictors of first stroke and prognosis after stroke. The value of high-sensitivity C-reactive protein and other markers may depend on the characteristics of the study population; their utility may be less among populations with high vascular risk. A recent randomized, clinical trial suggests that the use of rosuvastatin therapy in otherwise healthy patients with high-sensitivity C-reactive protein >2 mg/dL can reduce the risk of a first stroke by 50%. The prognostic role of high-sensitivity C-reactive protein among patients after stroke, however, is less clear, and other biomarkers, including lipoprotein-associated phospholipase A2, may provide complementary information about the risk of stroke recurrence. Infections, moreover, may contribute to inflammation and stroke risk. Although no single infectious organism is likely to be identified as the direct cause of atherosclerosis, summary measures of multiple chronic infectious exposures, or “infectious burden,� have been associated with the risk of stroke and atherosclerosis affecting the carotid arteries. Acute infections have also been found to serve as stroke triggers in epidemiologic studies. Recommendations to vaccinate patients with cardiovascular disease against influenza represent the first specific anti-infective strategy to be used in vascular prophylaxis. Further studies are needed to determine the role of treatment of inflammation and infection in stroke prevention.


3.1.3 Mechanisms of cardio embolic stroke Cardiac embolism is often involved as a mechanism for embolic stroke, and may be implicated in many strokes that have traditionally been considered of unknown origin (cryptogenic strokes). In recent years, significant advancements have been made in understanding and reducing the risk of stroke from long-known cardio embolic sources (atrial fibrillation, intracardiac thrombus or tumor, infective endocarditic). Also, improved cardiac imaging, especially transesophageal echocardiography, has allowed the identification of newer embolic sources of stroke (aortic atheromas, patent foramen ovale, atrial septal aneurysm). This article reviews the current understanding of cardiac embolism as a mechanism for stroke, and the preventive options that are currently adopted to decrease the stroke risk. 3.1.4 Mechanism of stroke complicating cardiopulmonary bypass surgery Stroke is a devastating complication of cardiopulmonary bypass (CPB) surgery which occurs in 1 to 5% of cases. Strategies to reduce its incidence require knowledge of the underlying pathology and etiology. To determine the incidence, pathology and etiology of stroke complicating CPB. Prospective review of clinical, operative and cranial CT scan findings in all cases of stroke complicating CPB procedures in our institution over an 18 month period. Twenty-one (1.6%, 95% CI 0.9-2.3%) cases of stroke were identified from 1336 CPB procedures. Cranial CT scan, performed in all but one patient, was normal in three patients or consistent with ischemic stroke in 17 patients. There were no cases of hemorrhagic infarction or intracerebral haemorrhage. It was difficult to differentiate embolic and borderzone infarcts in two cases. After considering the clinical, operative and CT scan features together, 12 (57%, 95% CI 36-78%) of the cases were felt to be embolic in origin and nine (43%, 95% CI 22-64%) due to hypoperfusion in a borderzone. This study demonstrates that stroke remains an important complication of CPB procedures with an incidence in our series of 1.6%. The pathologic type of stroke is predominantly ischaemic in nature due to either cerebral embolism or borderzone infarction. Strategies for stroke prevention in patients undergoing CPB should be targeted primarily at these two mechanisms. 3.2 Prevention of Stroke Strokes are usually the result of a combination of factors that have been present or developing for a long period of time. If someone has two or more of the risk factors below, stroke risk is dramatically increased. Anyone who is high risk should see their doctor who will usually assess each risk factor for stroke (and heart disease) before deciding on necessary treatments. Here are some simple rules to reduce stroke risk: Get blood pressure checked


Because it is one of the greatest stroke risk factors, failure to detect and control high blood pressure is the number one cause of avoidable strokes. A person with high blood pressure is up to seven times more likely to have a stroke than someone with normal or low blood pressure. High blood pressure puts too much pressure and stress on the walls of blood vessels and increases the risk of both hemorrhages’ and blood clots. Stop smoking

Smoking quadruples stroke risk. Chemicals and gases in tobacco smoke speed up the process of atherosclerosis (hardening of the arteries) and make blood vessels throughout the body tighten, reducing blood flow. Smoking also makes the blood more likely to clot, especially inside damaged blood vessels. Note: If one smoke and have high blood pressure you are 18 times more likely to have a stroke than someone the same age that doesn’t smoke and has normal blood pressure. Exercise regularly


People who are physically inactive have greater stroke risk than those who keep active. Being physically inactive over a long period is linked to high blood pressure, a leading cause of strokes. Limit the amount of alcohol drink

Studies now show that drinking up to two small alcoholic drinks a day can reduce stroke risk – but drinking any more than that increases stroke risk by as much as three times. A drinking binge creates as much as five times greater risk. Regular heavy drinking increases stroke risk because it can raise blood pressure and increase the risk of hemorrhage in the brain. Eat a healthy diet and reduce salt intake


Cutting down on fat and salt should lower a person's blood pressure and cholesterol levels. Too much fat in a diet can cause silting of the arteries (atherosclerosis), which can cause strokes. Too much salt can raise blood pressure and this also can cause strokes. Lower cholesterol

Cholesterol is essential to the body’s cells and normally the body will produce all the cholesterol it requires. Consuming foods high in cholesterol and saturated fats may accelerate atherosclerosis. Keep on top of cholesterol levels by having a blood test and by being prepared to change your eating habits. If necessary, a doctor might also prescribe a cholesterol lowering drug (called lipid-lowering agents, usually a ‘statin’). Find out atrial fibrillation Atrial fibrillation is a type of irregular heartbeat. People with this condition have a five times greater stroke risk because the irregular heartbeat may lead to blood clots forming in the heart. These can then break off and travel though the blood vessels to the brain where they may cut off blood supply, causing a stroke. If someone suspects they have atrial fibrillation, it is important to see a doctor. The doctor might prescribe tablets to make the blood less sticky and less likely to form clots (warfarin) and make the heartbeat more regular. Control weight

Being overweight strains the entire circulatory system and creates higher cholesterol levels, high blood pressure and diabetes – all of which increase stroke risk. 3.3 The goals of stroke treatment


 Quickly restore blood flow to the brain (in those people with an ischemic stroke) or

stop the bleeding (in those people with hemorrhagic stroke) .  Continuously monitor vital signs to detect and treat stroke complications .  Make lifelong changes to reduce the chances of another stroke. Depending on the situation and the type of stroke treatment options for a stroke may include :  Medications, such as thrombolytic ("clot-busting") drugs  Surgery  Stroke rehabilitation and lifestyle changes.

For people who have had an ischemic stroke, it may involve the use of thrombolytic ("clot-busting") drugs to dissolve blood clots that are blocking blood flow to the brain. Other medicine that doctors may use to treat a stroke may include anticoagulants and antiplatelets. After a stroke survivor has left the hospital, treatment often continues in the form of rehabilitation. Lifestyle changes are often part of longterm treatment following a stroke. Risk factor modification, medications and, in some cases, surgery can help to minimize the risk of having a stroke. 3.4 Treatment of Stroke Regular medical supervision, medication and lifestyle changes Medical advice will be given on continuing care for stroke survivors and may include: Regular medical supervision  Regular checks of blood pressure and cholesterol levels leading to appropriate medication.  Carotid surgery -one in ten stroke patients have a very narrow artery in the front of the neck on one side (the carotid artery) that restricts the flow of blood to the brain. Surgery to open and clear the artery or to place a small cylinder (stent) in it will increase the flow.  Medication – two kinds of tablets are prescribed: “clot-busters” and blood-thinners . 

Anti-clotting (antiplatelet) medication, such as aspirin, probably in combination with another drug such as clopidogrel or dipyridamole (for those patients who have had an ischaemic stroke caused by a clot forming on an area of hardening of the arteries).

Anti-coagulant medication (such as warfarin) where an ischaemic stroke has been caused by a blood clot forming in the heart, breaking off and lodging in the brain. These drugs are very powerful, may have significant side effects and must be carefully supervised by the doctor.

 Changes to lifestyle


Attention to diet, which should be varied, but low in saturated fat, alcohol, and salt, and high in fiber, fruit and vegetables.

Avoidance of smoking - this is absolutely essential.

Stress management - stress in life is unavoidable but can be reduced by various strategies including exercise, changing attitudes to work, meditation and relaxation.

Regular exercise – which will help to regulate weight and improve circulation.

There are various techniques that can be used to try to help or compensate for the various visual effects of stroke. These include glasses, prisms, patching, magnifiers and scanning information to name a few. The focus in working with stroke sufferers is on rehabilitation and that also applies with vision related problems. Orthoptists and Low Vision Specialists can assess and work with people with visual training with or without optical aids; the stroke team, GP or Ophthalmologist can refer people for an orthoptic assessment and / or to the Low Vision Clinic. Some people may see some improvement in their vision up to four months following a stroke. Again, this is highly dependent on where the damage in the brain occurred as well as the type of stroke suffered and other existing health problems. Unfortunately for many people, especially those with loss of visual field, sight loss may be permanent. 3.5 Recovery from Stroke Recovery from stroke takes time. Recovery from stroke can be remarkable and inexplicable. Recovery and Rehabilitation Much is still not known about how the brain compensates for the damage caused by stroke. Some brain cells may be only temporarily damaged, not killed, and may resume functioning. In some cases, the brain can reorganize its own functioning: another part of the brain ‘takes over’ for a damaged part. Stroke survivors sometimes experience remarkable and unanticipated recoveries that can't be explained. Recovery after stroke takes time. It is greatest in the first few months, and gradually plateaus, although small gains may be made for the next 1 to 2 years. The rate of recovery will vary greatly amongst patients. Rehabilitation starts in the hospital as soon as possible after the stroke. In patients who are stable, rehabilitation may begin two days after the stroke has occurred, and should be continued as necessary after release from the hospital. Before discharge a conference with hospital staff regarding future care, supervision and rehabilitation is essential. Depending on the severity of the effects of the stroke, rehabilitation options include: • •

A rehabilitation unit in the hospital A rehabilitation hospital

Home therapy

Home with outpatient therapy


A long-term care facility that provides therapy and skilled nursing care.

3.6 Life after Stroke Patients are generally encouraged to return to their normal lives - depending on the effects persisting from stroke. Some aspects of life after stroke include: •

Resuming work

How soon this is possible depends partly on remaining disability, the type of work involved, and the feelings about returning to work. Some people feel quite tired after a stroke, and have difficulty carrying out any kind of physical activity for any length of time. Part-time work at least in the early stages may be a good idea. Unless the stroke has reduced awareness of impairment, it is probable that the person who had the stroke is the best judge of when to return to work. •

Driving

Even someone who appears to have made a full recovery after stroke should not drive a car for at least a month as the risk of another stroke is greatest at this time. To drive again involves being cleared by the doctor (who will be aware of relevant government regulations) as the stroke may have left subtle impairments, not always apparent, such as poor coordination, lack of awareness on one side, difficulties in judging distance, changes in vision, difficulties in concentration and confusion between left and right. •

Sexual activity

Resumption of sexual activity after stroke is encouraged. Most couples experience some difficulty in their sex life after stroke, but this is usually due to psychological factors rather than any disability caused by stroke. A doctor can advise on any difficulty such as erectile problems in men. •

Sport and Exercise

Resumption of physical activity and hobbies is an important part of rehabilitation- normal activity should be resumed as soon as physically possible. •

Drinking Alcohol

The intake of excessive amounts of alcohol should be avoided after stroke as it may interact adversely with medication, raise blood pressure, and affect judgement resulting in injury. Moderate consumption (two standard drinks per day) should not cause any problem.


Other vision problems associated with stroke

A common effect of stroke-related vision problems is an increased sensitivity to light. The brain seems to have difficulty adjusting to different levels of light. Tinted glasses or sunglasses may be helpful in reducing the discomfort some people experience. Another problem which can follow stroke is dry eye. The rate of blinking may slow following a stroke and /or there may be incomplete eye closure with a partial blink which will cause a part of the cornea to dry resulting in the eye feeling uncomfortable. Artificial tears, and reminding the person to try to blink completely and often, may be a possible solution for dry eyes.

Chapter - 4 4.1 Literature Review A Stroke is a ‘Brain attack’ that occurs when blood flow to the brain is interrupted and oxygen does not get to an area of the brain . When this happens, brain cells begin to die and brain damage occurs. There are two types of stroke, hemorrhagic and ischemic. Ischemic strokes can be further broken down into two types-embolic and thrombotic. Of all strokes, 87% are ischemic. Embolic strokes are caused by a traveling atherosclerotic clot. Atherosclerosis is a condition in which fatty material is deposited along the walls of arteries. This fatty material thickens, hardens and may eventually block the arteries. Thrombotic strokes are caused by blockages in the arteries providing blood flow to the brain. About 700,000 Americans each year suffer a new or recurrent stroke. That means, on average, a stroke occurs every 45 seconds. Stroke kills more than 150,000 people a year. That’s about 1 of every 16 deaths. It’s the No.3 cause of death behind diseases of the heart and cancer. On average, every 3 to 4 minutes someone dies of stroke. Of every 5 deaths from stroke,2 occur in men and 3 in women. Stroke is a leading cause of serious, long term disability in the United States. The 2004 stroke death rates per 100,000 population for specific groups were 48.1 for white males, 47.4 for white females,73.9 for black males and 64.9 for black females. About 15% of all strokes are heralded by Transient Ischemic Attacks (TIA).In person’s ages 45-64 years old, 8-12% of ischemic strokes result in death in 30 days. Stroke is a major cause of mortality in the UK, accounting for around 53,000 deaths every year. In those aged under 75, around one in twenty deaths are from stroke, making it a major cause of premature mortality. Stroke mortality rates for men and women are now at about a third of the level they were in 1968. There is a north-south gradient in stroke mortality with rates in Scotland around 50% higher than in London. Social inequalities in stroke are persistent and premature death rates in the most deprived areas are around three times higher than in the least deprived. The stroke mortality rate for men born in Bangladesh is three times higher than those born in England and Wales and this gap has increased since the early 1980s. Using the most recent measures of stroke incidence rates, we estimate that there are around 111,000 first strokes in the UK every year. The prevalence of stroke among those aged over 75 is increasing in England. For men, the prevalence in this age group has increased from 9% in 1994 to 13% in 2006. There are over 21,000 surgical procedures related to stroke every year in England, with a similar number performed on men and women. Nearly 40% men and more than 30%women in England have high blood pressure, a key risk factor for stroke. Half of people with high blood pressure are not receiving treatment. The


prevalence of obesity in England in 2006 was around 50% higher than in 1994. Stroke is a major health issue for women, particularly for women. The length of time to recover from a stroke depends on its severity. Carotid artery blockages are the major contributor to the most common type of stroke. Effects of a left-sided stroke include paralysis, speech/ language problems, a slow, cautious behavioral style and memory loss. The effects of stroke on the right hand side of the body will include paralysis, vision problems, a quick, inquisitive behavioral style and memory loss. Stroke risk factors that can not be changed include being over age 55, family history of stroke, being of African-American race and male gender. Factors that can be modified include high blood pressure, high cholesterol, smoking, diabetes and atrial fibrillation (a heart rhythm disorder). Stroke is an important medical issue in a woman's life. In general, a stroke is seen as a medical problem more common among men. In reality, stroke accounts for a higher proportion of death among women than men. A stroke can strike at any age, and despite the fact that it is perceived as an elderly problem, more than 30 percent of all strokes occur in women under the age of 65. A new study published in 2007 found that more women than men appear to have middle age strokes. The risk of stroke is higher in this age group (35-64) because women tend to have more complications from obesity than men, and experience higher blood pressure and high cholesterol problems. Statistics show that in developing countries, half of all deaths in women over the age of 50 are due to heart diseases and stroke. According to the American Stroke Association, stroke is the third leading cause of death among American women. In the United States, one in 2.5 women die of heart disease, stroke or other cardiovascular disorders, compared with one in 30 who dies of breast cancer. Studies also show that women who survived a stroke have a higher risk than men to undergo a poor recovery. Today, more than 2 million American women live with the consequences of a stroke. Unfortunately, only 13 percent of the adult women know that heart problems and stroke are the greatest threats to their health. Recognizing the symptoms of a stroke is essential for receiving treatment, reducing the risk of disability and death. Unfortunately, women are more likely to delay receiving treatment than men. Studies also show that women take up to 46 percent longer to get to the hospital than men after the first stroke symptoms occur. One of the reason for delaying treatment is that only a reduced number of women can properly recognize stroke symptoms. The common stroke symptoms include: (1) Sudden numbness, weakness, clumsiness, or paralysis on one side of the body. (2) Sudden confusion, slurred speech, trouble speaking, or understanding speech. (3) Sudden blurred vision or loss of sight in one or both eyes. (4) Sudden trouble walking, dizziness, loss of balance or coordination. (5) Sudden severe headache with no known cause. (6) Loss of balance or unsteadiness.


However, the new research has discovered that women are less likely to experience the traditional stroke symptoms. This can be one of the reasons why women delay treatment. Some of the additional symptoms experienced by women include: (1) Loss of consciousness or fainting. (2) Shortness of breathing. (3) Sudden face, chest and limb pain. (4) Sudden hiccups (5) Sudden nausea (6) Seizure (7) Sudden tiredness or general weakness. 8) Sudden pounding and racing heartbeat (or palpitations). Women and men share similar risk factors, but women also face gender related risk. Some of the following risk factors are important for women under the age of 55. The Healthy People 2010 target for coronary heart disease is to reduce deaths to less than 166 per 100,000 people. In 2003, the death rate in Colorado was 118.6, surpassing the target by 28.5 percent. Although the target was reached, programmatic efforts to maintain and further decrease the death rate for coronary heart disease will be important in Colorado, as it remains our number one public health problem. The Healthy People 2010 target for stroke is to reduce deaths to less than 48 per 100,000 people. In 2003, the death rate in Colorado was 51.3. By 2010, the stroke death rate needs to decrease by 6.9 percent. A recommendation is to focus programmatic efforts on health disparities since the biggest decrease (28.7 percent) is needed among Blacks while an 8.7 percent decrease is necessary for Whites to reach the 2010 target. Furthermore, a 7.5 percent decrease is needed for females while a 3.8 percent decrease is needed for males. Primary prevention is one major strategy to reduce the development of cardiovascular disease and stroke, specifically through lifestyle interventions that promote heart-healthy behaviors. High cholesterol is one of the major risk factors that can be modified. To prevent or lower cholesterol, lifestyle changes include eating a diet low in saturated fat and cholesterol, increasing physical activity, and reducing excess weight. The Healthy People 2010 target is to reduce the proportion of adults with high cholesterol to 17 percent. This presents a major challenge as 31.9 percent of Colorado adults had high cholesterol during 2003 and the data from 1995 to 2003 indicate an increasing trend. A decrease of 46.7 percent from the 2003 percentage needs to occur to reach the target. High blood pressure is another major risk factor for heart disease and stroke. The Healthy People 2010 target is to reduce the proportion of adults with high blood pressure to 16 percent. In 2003, this percentage was 19.8 among Coloradans. A 19.2 percent decrease from the 2003 percentage is necessary to reach the target.


Chapter 5 Conclusion and recommendations Recent advances in the treatment of stroke are based on increasing knowledge of its underlying biophysical mechanisms, as well as on better-publicized advances in imaging instrumentation and procedures for the management and treatment of patients. Identification of risk factors is the only way to achieve this goal. Implementation of screening programme in community to identify risk factors and educate people about primary prevention should be initiated in this regard. This way, we can reduce morbidity and mortality among stroke patients and alleviate the burden of stroke. Management of risk factors is critical to prevent stroke. Not only pharmacological treatment, but also life-style modification including diet and exercise are recommended. Evidence-based recommendations found in treatment guidelines are useful, especially for hypertension, dyslipidemia, and atrial fibrillation in which the clinical trial evidence is rich. Yet there are many established and less-established risk factors lacking scientific evidence for screening and treatment. Although science seeks independent contribution of each risk factor to disease, management to one can bring additional improvement of other factors in practice and the accumulation of each improvement will finally decrease the stroke risk. Further investigations are much needed to establish the best management of important and common risk factors. Screening for conventional cardiovascular risk factors remains the most important considering the high percentage of cardiovascular risk factors in patients under age 50. These high frequencies also indicate optimal secondary prevention strategies. Based on the low laboratory yield of thrombophilia- and auto-immune search, it is not indicated to do this complete laboratory search in all patients under 50, especially not when there is no history related to these diseases. Furthermore in most cases a positive thrombophilic factor has no therapeutic consequences, such as switching of type of anticoagulation or duration of anticoagulation. Thrombophilia and auto-immune research is only indicated in specific cases. Because of the low number of abnormalities found in TTE, TEE seems preferable instead. Disadvantage of the transesophageal technique is its more invasive nature. Another possibility is the use of TEE in selected young patients, without other risk factors for ischemic stroke. The ECG should be used to exclude atrial fibrillation. It is cheap and simple. The use of duplex ultrasound of the extra cranial arteries should be continued. It is a noninvasive test and gives information about the presence of atherosclerosis or dissection in the carotid arteries. Is has a sensitivity of 86% and specificity of 87% .History taking remains important in detecting risk factors. Characteristics of auto-immune diseases could be specifically interrogated. References Andraws R, Berger JS, Brown DL (Jun 2005). "Effects of antibiotic therapy on outcomes of patients with coronary artery disease: a meta-analysis of randomized controlled trials". JAMA 293 (21): 2641–7. Doi: 10.1001/jama.293.21.2641. PMID 15928286. 2. Berger, JS; Lala, A, Krantz, MJ, Baker, GS, Hiatt, WR (2011 Jul). "Aspirin for the prevention of cardiovascular events in patients without clinical cardiovascular disease: a meta-analysis of randomized trials.". American heart journal 162 (1): 11524.e2. PMID 21742097. 1.


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ANNEX


Figure : Different types stroke


Stroke: Classification

Stroke: Etiology

Image of city scan


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