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Types of Dementia and symptoms

Types of Dementia

Dementia is a general term for loss of memory and other mental abilities severe enough to interfere with daily life. It is caused by physical changes in the brain.

 

 

Alzheimer’s disease

Most common type of dementia; accounts for an estimated 60 to 80 percent of cases.

Symptoms: Difficulty remembering recent conversations, names or events is often an early clinical symptom; apathy and depression are also often early symptoms. Later symptoms include impaired communication, poor judgment, disorientation, confusion, behavior changes and difficulty speaking, swallowing and walking.

Revised criteria and guidelines for diagnosing Alzheimer’s were published in 2011 recommending that Alzheimer’s be considered a slowly progressive brain disease that begins well before symptoms emerge.

Brain changes: Hallmark abnormalities are deposits of the protein fragment beta-amyloid (plaques) and twisted strands of the protein tau (tangles) as well as evidence of nerve cell damage and death in the brain.

 

Vascular dementia:

Previously known as multi-infarct or post-stroke dementia, vascular dementia is less common as a sole cause of dementia than Alzheimer’s, accounting for about 10 percent of dementia cases.

Symptoms: Impaired judgment or ability to make decisions, plan or organize is more likely to be the initial symptom, as opposed to the memory loss often associated with the initial symptoms of Alzheimer’s. Occurs from blood vessel blockage or damage leading to infarcts (strokes) or bleeding in the brain. The location, number and size of the brain injury determines how the individual’s thinking and physical functioning are affected.

Brain changes: Brain imaging can often detect blood vessel problems implicated in vascular dementia. In the past, evidence for vascular dementia was used to exclude a diagnosis of Alzheimer’s disease (and vice versa). That practice is no longer considered consistent with pathologic evidence, which shows that the brain changes of several types of dementia can be present simultaneously. When any two or more types of dementia are present at the same time, the individual is considered to have “mixed dementia” (see entry below).

 

Dementia with Lewy bodies (DLB):

Symptoms: People with dementia with Lewy bodies often have memory loss and thinking problems common in Alzheimer’s, but are more likely than people with Alzheimer’s to have initial or early symptoms such as sleep disturbances, well-formed visual hallucinations, and slowness, gait imbalance or other parkinsonian movement features.

Brain changes: Lewy bodies are abnormal aggregations (or clumps) of the protein alpha-synuclein. When they develop in a part of the brain called the cortex, dementia can result. Alpha-synuclein also aggregates in the brains of people with Parkinson’s disease, but the aggregates may appear in a pattern that is different from dementia with Lewy bodies.

The brain changes of dementia with Lewy bodies alone can cause dementia, or they can be present at the same time as the brain changes of Alzheimer’s disease and/or vascular dementia, with each abnormality contributing to the development of dementia. When this happens, the individual is said to have “mixed dementia.”

 

Mixed dementia:

In mixed dementia abnormalities linked to more than one cause of dementia occur simultaneously in the brain. Recent studies suggest that mixed dementia is more common than previously thought.

Brain changes: Characterized by the hallmark abnormalities of more than one cause of dementia —most commonly, Alzheimer’s and vascular dementia, but also other types, such as dementia with Lewy bodies.

 

Parkinson’s disease:

As Parkinson’s disease progresses, it often results in a progressive dementia similar to dementia with Lewy bodies or Alzheimer’s.

Symptoms: Problems with movement are common symptoms of the disease. If dementia develops, symptoms are often similar to dementia with Lewy bodies.

Brain changes: Alpha-synuclein clumps are likely to begin in an area deep in the brain called the substantia nigra. These clumps are thought to cause degeneration of the nerve cells that produce dopamine.

 

Frontotemporal dementia:

Includes dementias such as behavioral variant FTD (bvFTD), primary progressive aphasia, Pick’s disease, corticobasal degeneration and progressive supranuclear palsy.

Symptoms: Typical symptoms include changes in personality and behavior and difficulty with language. Nerve cells in the front and side regions of the brain are especially affected.

Brain changes: No distinguishing microscopic abnormality is linked to all cases. People with FTD generally develop symptoms at a younger age (at about age 60) and survive for fewer years than those with Alzheimer’s.

 

Creutzfeldt-Jakob disease:

CJD is the most common human form of a group of rare, fatal brain disorders affecting people and certain other mammals. Variant CJD (“mad cow disease”) occurs in cattle, and has been transmitted to people under certain circumstances.

Symptoms: Rapidly fatal disorder that impairs memory and coordination and causes behavior changes.

Brain changes: Results from misfolded prion protein that causes a “domino effect” in which prion protein throughout the brain misfolds and thus malfunctions.

 

Normal pressure hydrocephalus:

Symptoms: Symptoms include difficulty walking, memory loss and inability to control urination.

Brain changes: Caused by the buildup of fluid in the brain. Can sometimes be corrected with surgical installation of a shunt in the brain to drain excess fluid.

 

Huntington’s Disease:

Huntington’s disease is a progressive brain disorder caused by a single defective gene on chromosome 4.

Symptoms: Include abnormal involuntary movements, a severe decline in thinking and reasoning skills, and irritability, depression and other mood changes.

Brain changes: The gene defect causes abnormalities in a brain protein that, over time, lead to worsening symptoms.

 

Wernicke-Korsakoff Syndrome:

Korsakoff syndrome is a chronic memory disorder caused by severe deficiency of thiamine (vitamin B-1). The most common cause is alcohol misuse.

Symptoms: Memory problems may be strikingly severe while other thinking and social skills seem relatively unaffected.

Brain changes: Thiamine helps brain cells produce energy from sugar. When thiamine levels fall too low, brain cells cannot generate enough energy to function properly.

Ultrasonic scaling and polishing in dental treatments

During a routine Scale and Polish at Smiles Dental, your hygienist will thoroughly clean all deposits and stains from teeth. They will scale away tartar build-up from tooth surfaces and polish your teeth using special dental instruments. You can feel tartar build up on the backs of your teeth with your tongue.

The ultrasonic scaling device removes tartar (calculus), plaque and bio film from the tooth surface and underneath the gum line. A manual instrument may be used next to remove the remainder. Root planing involves detailed scaling of the root surface to decrease inflammation of the gum tissue.

Ultrasonic scalers are used to remove calculus rapidly from the tooth surface. The scaling tip vibrates in the ultrasonic range of 20-45 kHz (i.e. 20,000 to 45,000 times per second), with an optimum frequency between 18 kHz and 32kHz.

What are dental cleanings (scale and polish) and why have them?

Dental cleanings involve removing plaque (soft, sticky, bacteria infested film) and tartar (calculus) deposits that have built up on the teeth over time. Your teeth are continually bathed in saliva which contains calcium and other substances which help strengthen and protect the teeth. While this is a good thing, it also means that we tend to get a build-up of calcium deposits on the teeth. This chalky substance will eventually build up over time, like limescale in a pipe or kettle. Usually it is tooth coloured and can easily be mistaken as part of the teeth, but it also can vary from brown to black in colour.

If the scale, or calculus (tartar, as dentists like to call it) is allowed to accumulate on the teeth it will unfortunately provide the right conditions for bacteria to thrive next to the gums. The purpose of the cleaning and polishing is basically to leave the surfaces of the teeth clean and smooth so that bacteria are unable to stick to them and you have a better chance of keeping the teeth clean during your regular home care.

 

Also it leaves your teeth feeling lovely and smooth and clean, which is nice when you run your tongue around them. Actually, come to think of it, there’s nothing worse than someone you fancy running their tongue around your teeth and finding a piece of spinach or something! Still, if they’re hungry…

The professional cleaning of teeth is sometimes referred to as prophylaxis (orprophy for short). It’s a Greek word which means “to prevent beforehand” – in this case, it helps prevent gum disease.

How are dental cleanings done?

The dental hygienist or dentist uses specialized instruments to gently remove these deposits without harming the teeth. The instruments which may be used during your cleaning, and what they feel like, are described below.

Ultrasonic instrument

Commonly used first is an ultrasonic instrument which uses tickling vibrations to knock larger pieces of tartar loose. It also sprays acooling mist of water while it works to wash away debris and keep the area at a proper temperature. The device typically emits a humming or high pitched whistling sound. This may seem louder than it actually is because the sound may get amplified inside your head, just like when you put an electric toothbrush into your mouth.

The ultrasonic instrument tips are curved and rounded and are always kept in motion around the teeth. They are by no means sharp since their purpose is to knock tartar loose and not to cut into the teeth. It is best to inform the operator if the sensations are too strong or ticklish so that they can adjust the setting appropriately on the device or modify the pressure applied.

With larger deposits that have hardened on, it can take some time to remove these, just like trying to remove baked-on grime on a stove that has been left over a long time. So your cleaning may take longer than future cleanings. Imagine not cleaning a house for six months versus cleaning it every week. The six-month job is going to take longer than doing smaller weekly jobs.

Fine hand tools

Once the larger pieces of tartar are gone, the dental worker will switch to finer hand tools (called scalers and curettes in dental-speak) to remove smaller deposits and smoothen the tooth surfaces. These tools are curved and shaped to match the curves of the teeth. They allow smaller tartar deposits to be removed bycarefully scraping them off with a gentle to moderate amount of pressure. Just like taking a scrubbing brush to a soiled pot, the dental worker has to get the areas clean and smooth.

Polishing

Once all the surfaces are smooth, the dental worker may polish your teeth. Polishing is done using a slow speed handpiece with a soft rubber cup that spins on the end. Prophylaxis (short for prophy) paste – a special gritty toothpaste-like material – is scooped up like ice cream into the cup and spun around on the teeth to make them shiny smooth.

Fluoride


Your dentist may also apply fluoride. This is the final, and my favorite part of the dental cleaning! Fluoride comes in many different flavours such as chocolate, mint, strawberry, cherry, watermelon, pina colada and can be mixed and matched just like ice cream at a parlour for a great taste sensation! Make no mistake though, this in-office fluoride treatment is meant for topical use only on the surfaces of the teeth and swallowing excessive amounts can give a person a tummy ache as it is not meant to be ingested.

Fluoride foam or gel is then placed into small, flexible foam trays and placed over the teeth for 30 seconds. Afterwards the patient is directed to spit as much out as possible into a saliva ejector. The fluoride helps to strengthen the teeth since the acids from bacteria in dental tartar and plaque will have weakened the surfaces. It is best not to eat, drink or rinse for 30 minutes after the fluoride has been applied.

Is it going to be painful?

Most people find that cleanings are painless, and find the sensations described above – tickling vibrations, the cooling mist of water, and the feeling of pressure during “scraping” – do not cause discomfort. A lot of people even report that they enjoy cleanings and the lovely smooth feel of their teeth afterwards! There may be odd zingy sensations, but many people don’t mind as they only last a nanosecond.

Be sure to let your dentist/hygienist know if you find things are getting too uncomfortable for your liking. They can recommend various options to make the cleaning more enjoyable.

How Is Iron-Deficiency Anemia Treated?

Treatment for iron-deficiency anemia will depend on its cause and severity. Treatments may include dietary changes and supplements, medicines, and surgery.

Severe iron-deficiency anemia may require a blood transfusion, iron injections, or intravenous (IV) iron therapy. Treatment may need to be done in a hospital.

The goals of treating iron-deficiency anemia are to treat its underlying cause and restore normal levels of red blood cells, hemoglobin, and iron.

Dietary Changes and Supplements

Iron

You may need iron supplements to build up your iron levels as quickly as possible. Iron supplements can correct low iron levels within months. Supplements come in pill form or in drops for children.

Large amounts of iron can be harmful, so take iron supplements only as your doctor prescribes. Keep iron supplements out of reach from children. This will prevent them from taking an overdose of iron.

Iron supplements can cause side effects, such as dark stools, stomach irritation, and heartburn. Iron also can cause constipation, so your doctor may suggest that you use a stool softener.

Your doctor may advise you to eat more foods that are rich in iron. The best source of iron is red meat, especially beef and liver. Chicken, turkey, pork, fish, and shellfish also are good sources of iron.

The body tends to absorb iron from meat better than iron from nonmeat foods. However, some nonmeat foods also can help you raise your iron levels. Examples of nonmeat foods that are good sources of iron include:

  • Iron-fortified breads and cereals
  • Peas; lentils; white, red, and baked beans; soybeans; and chickpeas
  • Tofu
  • Dried fruits, such as prunes, raisins, and apricots
  • Spinach and other dark green leafy vegetables
  • Prune juice

The Nutrition Facts labels on packaged foods will show how much iron the items contain. The amount is given as a percentage of the total amount of iron you need every day.

Vitamin C

Vitamin C helps the body absorb iron. Good sources of vitamin C are vegetables and fruits, especially citrus fruits. Citrus fruits include oranges, grapefruits, tangerines, and similar fruits. Fresh and frozen fruits, vegetables, and juices usually have more vitamin C than canned ones.

If you’re taking medicines, ask your doctor or pharmacist whether you can eat grapefruit or drink grapefruit juice. Grapefruit can affect the strength of a few medicines and how well they work.

Other fruits rich in vitamin C include kiwi fruit, strawberries, and cantaloupes.

Vegetables rich in vitamin C include broccoli, peppers, Brussels sprouts, tomatoes, cabbage, potatoes, and leafy green vegetables like turnip greens and spinach.

Treatment To Stop Bleeding

If blood loss is causing iron-deficiency anemia, treatment will depend on the cause of the bleeding. For example, if you have a bleeding ulcer, your doctor may prescribe antibiotics and other medicines to treat the ulcer.

If a polyp or cancerous tumor in your intestine is causing bleeding, you may need surgery to remove the growth.

If you have heavy menstrual flow, your doctor may prescribe birth control pills to help reduce your monthly blood flow. In some cases, surgery may be advised.

Treatments for Severe Iron-Deficiency Anemia

Blood Transfusion

If your iron-deficiency anemia is severe, you may get a transfusion of red blood cells. A blood transfusion is a safe, common procedure in which blood is given to you through an IV line in one of your blood vessels. A transfusion requires careful matching of donated blood with the recipient’s blood.

A transfusion of red blood cells will treat your anemia right away. The red blood cells also give a source of iron that your body can reuse. However, a blood transfusion is only a short-term treatment. Your doctor will need to find and treat the cause of your anemia.

Blood transfusions are usually reserved for people whose anemia puts them at a higher risk for heart problems or other severe health issues.

For more information, go to the Health Topics Blood Transfusion article.

Iron Therapy

If you have severe anemia, your doctor may recommend iron therapy. For this treatment, iron is injected into a muscle or an IV line in one of your blood vessels.

IV iron therapy presents some safety concerns. It must be done in a hospital or clinic by experienced staff. Iron therapy usually is given to people who need iron long-term but can’t take iron supplements by mouth. This therapy also is given to people who need immediate treatment for iron-deficiency anemia.

 

How Can Iron-Deficiency Anemia Be Prevented?

Eating a well-balanced diet that includes iron-rich foods may help you prevent iron-deficiency anemia.

Taking iron supplements also may lower your risk for the condition if you’re not able to get enough iron from food. Large amounts of iron can be harmful, so take iron supplements only as your doctor prescribes.

For more information about diet and supplements, go to “How Is Iron-Deficiency Anemia Treated?”

Infants and young children and women are the two groups at highest risk for iron-deficiency anemia. Special measures can help prevent the condition in these groups.

Infants and Young Children

A baby’s diet can affect his or her risk for iron-deficiency anemia. For example, cow’s milk is low in iron. For this and other reasons, cow’s milk isn’t recommended for babies in their first year. After the first year, you may need to limit the amount of cow’s milk your baby drinks.

Also, babies need more iron as they grow and begin to eat solid foods. Talk with your child’s doctor about a healthy diet and food choices that will help your child get enough iron.

Your child’s doctor may recommend iron drops. However, giving a child too much iron can be harmful. Follow the doctor’s instructions and keep iron supplements and vitamins away from children. Asking for child-proof packages for supplements can help prevent overdosing in children.

Because recent research supports concerns that iron deficiency during infancy and childhood can have long-lasting, negative effects on brain health, the American Academy of Pediatrics recommends testing all infants for anemia at 1 year of age.

Women and Girls

Women of childbearing age may be tested for iron-deficiency anemia, especially if they have:

  • A history of iron-deficiency anemia
  • Heavy blood loss during their monthly periods
  • Other risk factors for iron-deficiency anemia

The Centers for Disease Control and Prevention (CDC) has developed guidelines for who should be screened for iron deficiency, and how often:

  • Girls aged 12 to 18 and women of childbearing age who are not pregnant: Every 5 to 10 years.
  • Women who have risk factors for iron deficiency: Once a year.
  • Pregnant women: At the first prenatal visit.

For pregnant women, medical care during pregnancy usually includes screening for anemia. Also, your doctor may prescribe iron supplements or advise you to eat more iron-rich foods. This not only will help you avoid iron-deficiency anemia, but also may lower your risk of having a low-birth-weight baby.

Living With Iron-Deficiency Anemia

If you have iron-deficiency anemia, get ongoing care to make sure your iron levels are improving. At your checkups, your doctor may change your medicines or supplements. He or she also may suggest ways to improve your diet.

Take iron supplements only with your doctor’s approval, and only as he or she prescribes. It’s possible to have too much iron in your body (a condition called iron overload). Too much iron in your body can damage your organs.

You may have fatigue (tiredness) and other symptoms of iron-deficiency anemia until your iron levels return to normal, which can take months. Tell your doctor if you have any new symptoms or if your symptoms get worse.

Bile duct cancer: Symptoms, Causes& Treatments

Bile duct cancer starts in the bile duct. Cancers can develop in any part of the bile duct and, based on their location, are classified into three types:

  • Intrahepatic bile duct cancers
  • Perihilar (also called hilar) bile duct cancers
  • Distal bile duct cancers

Cancers in these different areas may cause different symptoms.

Intrahepatic Bile Duct Cancers – These cancers develop in the smaller bile duct branches inside the liver. They can sometimes be confused with cancers that start in the liver cells, which are called hepatocellular carcinomas, and are often treated the same way. Only about 1 in 10 bile duct cancers are intra-hepatic.

Perihilar Bile Duct Cancers – These cancers develop at the hilum, where the hepatic ducts join and consequently leave the liver. They are also called Klatskin tumours. These are the most common type of bile duct cancers, making up 6 or 7 of every 10 bile duct cancers. These cancers are grouped with distal bile duct cancers as extrahepatic bile duct cancers.

Distal bile duct cancers – These bile duct cancers are found further down the bile duct, closer to the small intestine. Because these bile ducts are outside the liver, these cancers are grouped with perihilar cancers as extrahepatic bile duct cancers. Distal bile duct cancers make up 2 to 3 of every 10 bile duct cancers.

Symptoms:

Signs and symptoms may not be present until the later stages of bile duct cancer, but in some cases they may lead to an early diagnosis. The following are some symptoms associated with bile duct cancer:

  • Jaundice
  • Itching
  • Light-coloured stools
  • Dark urine
  • Abdominal pain
  • Loss of appetite
  • Weight loss
  • Fever
  • Nausea and vomiting

Bile duct cancer is uncommon. However, certain factors and conditions may put you at greater risk for developing this type of cancer.

Long-standing Inflammation
Long-standing inflammation is a key risk factor in developing bile duct cancer. Conditions that are associated with this kind of inflammation include:

  • Sclerosing cholangitis, which causes inflammation, scarring and sometimes destruction of the bile ducts
  • Ulcerative colitis, which causes ulcers in the rectum lining and colon
  • Bile duct stones
  • Cirrhosis, which is progressive scarring of the liver and is most often caused by alcohol abuse and infections such as hepatitis C and B

Age
Nearly 60% who develop bile duct cancer are over the age of 65.

Liver Fluke Infection
Flukes are parasitic worms that can enter your body if you eat undercooked freshwater fish that contains parasites. Once they have entered the body, liver flukes go and inhabit the bile ducts. The species of fluke connected to bile duct cancer is mostly found in Southeast Asia.

Other Risk Factors:
Family history of bile duct cancer, smoking, diabetes and pancreatitis may also play a role.

 Treatments:

Most cases of bile duct cancer cannot be cured. Instead, treatment is most commonly used to relieve symptoms. The treatment plan will be determined by the stage the cancer has reached.

In \ stage 1 and stage 2 cases of bile duct cancer, a cure may be possible by surgically removing the affected part of the bile duct, and possibly some of the liver or gallbladder.

In a stage 3 case, the chances of achieving a successful cure will depend on how many lymph nodes have been affected. A cure may be possible if only a few nodes have cancerous cells in them or it may be possible to slow the spread of the cancer by surgically removing the lymph nodes.

In cases of stage 4 bile duct cancer, achieving a successful cure is highly unlikely. However, chemotherapy, radiotherapy and surgery can often be used to help relieve symptoms.

Surgery:
If it is possible to cure bile duct cancer, surgery will be needed to remove any cancerous tissue. Depending on the extent of the cancer, it may be necessary to remove:

  • the part of your bile duct that contains cancerous cells
  • your gallbladder
  • nearby lymph nodes
  • part of your liver

Unfortunately, due to the aggressive nature of bile duct cancer, fewer than one-third of patients are suitable for surgery. After surgery, it is usually possible to reconstruct what remains of the bile duct so that bile can still flow into the intestine.

Unblocking The Bile Duct:
If the bile duct becomes blocked as a result of cancer, a treatment to unblock the duct is recommended. This will help resolve symptoms such as:

  • jaundice
  • itchy skin
  • abdominal tummy) pain

Unblocking the bile duct is sometimes necessary if the flow of bile back into your liver starts to affect the normal functioning of your liver. The bile duct can be unblocked in several ways. The first is to use a variation of the Endoscopic Retrograde Cholangiopancreatography (ERCP) procedure.

During the procedure, a surgeon will guide a long, flexible tube with a light and video camera on the end (endoscope) into the bile duct and pass down a small metal or plastic tube called a stent. The stent is used to widen the bile duct, which should help to get the bile flowing again.
Alternatively, a stent can be placed in the bile duct using a variation of the Percutaneous Transhepatic Cholangiography (PTC) procedure. This involves placing the stent in the bile duct through a small incision in the stomach.

Radiotherapy:
Radiotherapy cannot cure bile duct cancer but can help to relieve the symptoms, slow the spread of cancer and prolong life. Two types of radiotherapy are used to treat bile duct cancer:

  • External beam radiotherapy – a machine is used to target radioactive beams at your bile duct
  • Internal radiotherapy (brachytherapy) – a radioactive wire is placed inside your bile duct next to the tumour

Radiotherapy works by damaging cancerous cells. However, it can also damage healthy cells and cause side effects. Side effects of radiotherapy include:

  • nausea
  • vomiting
  • fatigue

Chemotherapy:
Chemotherapy is used in a way similar to radiotherapy to relieve the symptoms of cancer, slow down the rate at which it spreads and prolong life. It is sometimes used in combination with radiotherapy.
As with radiotherapy, medicines used in chemotherapy can sometimes damage healthy tissue as well as cancerous tissue, and adverse side effects are common. Side effects of chemotherapy can include:

  • nausea
  • vomiting
  • fatigue
  • hair loss

However, these side effects should stop once the course of treatment has finished.

Photodynamic Therapy (PDT):
Photodynamic Therapy is a new technique that can help to control – but not cure – the symptoms of bile duct cancer. A special chemical is injected into the bile duct, which makes the cancerous cells more sensitive to light. A laser is then passed through an endoscope and used to shrink the tumour.

 

Brain Stem glicomas : Symptoms, diagnosis and Treatments

Brain stem tumors are perhaps the most dreaded cancers in pediatric oncology, owing to their historically poor prognosis, yet they remain an area of intense research.  Brain stem tumors account for about 10 to 15% of childhood brain tumors.  Peak incidence for these tumors occurs around age 6 to 9 years.  The term brain stem glioma is often used interchangeably with brain stem tumor.  More precisely, glioma encompasses tumor pathology types such as ganglioglioma, pilcytic astrocytoma, diffuse astrocytoma, anaplastic astrocytoma, and glioblastoma multiforme.

Rarely, other tumor pathologies such as atypical teratoid/rhabdoid tumor (ATRT), primitive neuroectodermal tumor (PNET)/embryonal tumor, and hemangioblastoma occur at the brain stem. These entities are quite different from brain stem gliomas, and the following comments do not apply.

Classification:   Brain stem gliomas have been grouped in the past according to their pathology and location within the brain stem. Terms found in the medical literature include diffuse intrinsic gliomas, midbrain tumors, tectal gliomas, pencil gliomas, dorsal exophytic brain stem tumors, cervicomedullary tumors, focal gliomas, and cystic tumors.  A simpler way to classify these tumors is by two categories: diffuse intrinsic pontine glioma and focal brain stem glioma.
Symptoms:  Children with DIPG present with ataxia (clumsiness or wobbliness), weakness of a leg and/or arm, double vision, and sometimes headaches, vomiting, tilting of the head, or facial weakness. Double vision (diplopia) is the most common presenting symptom for these tumors.  Symptoms are usually present for 6 months or less at time of diagnosis.  Patients with focal brain stem gliomas may display some of the same symptoms, although not the usual combination of ataxia, weakness, and double vision. Duration of symptoms is often greater than 6 months before the focal brain stem tumor is diagnosed.

Diagnosis:  Throughout the United States, brain magnetic resonance imaging (MRI), with and without gadolinium contrast, remains the “gold standard” for diagnosis of brain stem gliomas.  Biopsy is seldom performed outside specialized biomedical research protocols for DIPG, unless the diagnosis of this tumor is in doubt.  Biopsy may be indicated for brain stem tumors that are focal or atypical, especially when the tumor is progressive or when surgical excision may be possible.

Diffuse intrinsic pontine gliomas (DIPG) insinuate diffusely throughout the normal structures of the pons (the middle portion of the brain stem), sometimes spreading to the midbrain (the upper portion of the brain stem) or the medulla (the bottom portion of the brain stem).  The term diffuse intrinsic glioma is synonymous.  By pathology, these tumors are most often a diffuse (sometimes referred to as fibrillary) astrocytoma (World Health Organization [WHO] grade II) or its higher-grade counterparts, anaplastic astrocytoma (WHO III) and glioblastoma multiforme (WHO IV).  Very rarely these tumors start in the medulla or midbrain.

Focal brain stem gliomas–perhaps 20% or more of brain stem gliomas–include tumors that are more circumscribed, focal, or contained at the brain stem.  These tumors may have cysts or grow out from the brain stem (i.e., exophytic).  These tumors more often arise in the midbrain or medulla, rather than the pons. Pathology for these tumors is frequently pilocytic astrocytoma (WHO I) or ganglioglioma (WHO I), although rarely diffuse astrocytoma (WHO II).


Treatment:
  Since brain stem gliomas are relatively uncommon and require complex management, children with such tumors deserve evaluation in a comprehensive cancer center where the coordinated services of dedicated pediatric neurosurgeons, child neurologists, pediatric oncologists, radiation oncologists, neuropathologists, and neuroradiologists are available. In particular, for DIPG, because of its rarity and poor prognosis, children and their families should be encouraged to participate in clinical trials attempting to improve survival with innovative therapy.

Neurosurgery Surgery to attempt tumor removal is usually not possible or advisable for DIPG. By their very nature, these tumors invade diffusely throughout the brain stem, growing between normal nerve cells. Aggressive surgery would cause severe damage to neural structures vital for arm and leg movement, eye movement, swallowing, breathing, and even consciousness.

Surgery with less than total removal can be performed for many focal brain stem gliomas.  Such surgery often results in quality long-term survival, without administering chemotherapy or radiotherapy immediately after surgery, even when a child has residual tumor.  Surgery is particularly useful for tumors that grow out (exophytic) from the brain stem.

Focal brain stem tumors that arise at the top back of the midbrain (tectal gliomas) should be managed conservatively, without surgical removal. Nevertheless, shunt placement or ventriculostomy for hydrocephalus (see below) is frequently necessary. These tumors have been described to be stable for many years or decades without any intervention other than shunting.

Radiotherapy:  Conventional radiotherapy, limited to the involved area of tumor, is the mainstay of treatment for DIPG.  A total radiation dosage ranging from 5400 to 6000 cGy, administered in daily fractions of 150 to 200 cGy over 6 weeks, is standard.  Hyperfractionated (twice-daily) radiotherapy was used previously to deliver higher irradiation dosages, but such did not lead to improved survival.  Radiosurgery (e.g., gamma knife, Cyberknife) has no role in the treatment of DIPG.

Chemotherapy and other drug therapies:  The role of chemotherapy in DIPG remains unclear.  Studies to date with chemotherapy have shown little improvement in survival, although efforts (see below) through the Children’s Oncology Group (COG), Pediatric Brain Tumor Consortium (PBTC), and others are underway to explore further the use of chemotherapy and other drugs.  Drugs utilized to increase the effect of radiotherapy (radiosensitizers) have thus far shown no added benefit, but promising new agents are under investigation.  Immunotherapy with beta-interferon and other drugs to modify biologic response have shown disappointing results.  Intensive or high-dose chemotherapy with autologous bone marrow transplant or peripheral blood stem cell rescue has not demonstrated any effectiveness in brain stem gliomas and is not recommended.  Future clinical trials may incorporate medicines to interfere with cellular pathways (signal transfer inhibitors) or other approaches that alter the tumor or its environment.  For more information and a listing of the most up-to date trials, the reader is encouraged to check the websites of the National Institutes of Health clinical trials registry , the National Childhood Cancer Foundation/COG, and the PBTC .

In focal brain stem gliomas, chemotherapy, such as carboplatin/vincristine,  procarbazine/CCNU/vincristine, or temozolomide, may be useful in children whose tumors are progressive and not surgically accessible.  In children younger than age 3 years, chemotherapy may be preferable to radiotherapy because of the effects of irradiation on the developing brain.

Recurrent or Progressive Brain Stem Gliomas: Regrettably, DIPG has a high rate of recurrence or progression. At relapse, a variety of Phase I and Phase II drug trials are available through the national research consortiums COG and PBTC, as well as through individual pediatric institutions. Oral etoposide, temozolomide, and cyclophosphamide are drug options sometimes utilized outside a study.

Prognosis:  DIPG often follows an inexorable course of progression, despite therapy. A large majority of children die within a year of diagnosis. Focal brain stem glioma, however, can carry an exceptional prognosis, with long-term survivals frequently reported.

Other Management Issues:  Shunts: Less than half of children with brain stem tumors will develop obstructive hydrocephalus, requiring a shunt or ventriculostomy, at some time during the course of their illness.  Shunts are simple mechanical tubing devices that divert cerebrospinal fluid trapped in the brain’s ventricles above the tumor to another location in the body, typically the abdomen (peritoneum), as in a ventriculoperitoneal shunt.  A ventriculostomy is the surgical creation of an internal channel, often from the third ventricle to a lower portion of the brain, to allow cerebrospinal fluid to drain beyond the tumor.

Steroids:  Dexamethasone (brand name Decadron) is a steroid drug frequently administered to brain stem tumor patients for the swelling and “tightness” of their tumor at the base of their skull. Dexamethasone must be used sparingly!  Dexamethasone should never be prescribed prophylactically or “just in case.” That is, this steroid is an extremely effective medicine for symptomatic swelling associated with treatment of a brain stem glioma, particularly with radiotherapy.  However, dexamethasone is not necessary unless a child has symptomatic swelling.  Dexamethasone has a number of side effects which include mood changes, insomnia, weight gain, fluid retention, glucose instability, high blood pressure, and increased susceptibility to infection.

Hyperthermia : Symptoms, Advantages & Treatments

Hyperthermia therapy is a type of medical treatment in which body tissue is exposed to slightly higher temperatures to damage and kill cancer cells or to make cancer cells more sensitive to the effects of radiation and certain anti-cancer drugs. When combined with radiation therapy, it is called thermoradiotherapy. Whole-body hyperthermia has also been found to be helpful for depression.

Local hyperthermia has shown to be effective when combined with chemotherapy or radiation therapy for cancers such as breast, cervical, prostate, head and neck, melanoma, soft-tissue sarcoma and rectal cancer, among others. Whole-body hyperthermia is generally considered to be a promising experimental cancer treatment, but requires close medical monitoring of the patient, as side effects can be serious.

Hyperthermia is considered the “fourth leg” of cancer treatment. It was historically was reserved for the most severe or recurrent cases of cancer. However, there is more evidence to support its use as a primary treatment. Hyperthermia is most effective when used alongside other therapies, so it is almost always used as an adjuvant therapy.

Hyperthermia Symptoms and Signs
  • Coma.
  • Confusion.
  • Dizziness.
  • Elevated Heart Rate.
  • Fainting.
  • Fever.
  • Headache.
  • Muscle Cramps.

Advantages:

Hyperthermia on its own is generally ineffective but the use of hyperthermia may significantly increase the effectiveness of other treatments.

When combined with radiation, hyperthermia is particularly effective at increasing the damage to acidic, poorly oxygenated parts of a tumor, and cells that are preparing to divide. Hyperthermia treatment is most effective when provided at the same time, or within an hour, of the radiation.

Whole-body hyperthermia cannot safely reach the temperatures necessary to improve the effectiveness of radiation, and thus is not used with radiation, but it may be useful for chemotherapy and immunotherapy.

The purpose of overheating the tumor cells is to create a lack of oxygen so that the heated tumor cells become over acidified, which leads to a lack of nutrients in the tumor. This in turn disrupts the metabolism of the cells so that cell death can set in. In certain cases chemotherapy or radiation that has previously not had any effect can be made effective. Because Hyperthermia alters the cell walls by means of so-called heat shock proteins, cancer cells then react very much more effectively to the cytostatics and radiation. If hyperthermia is used conscientiously it has no serious side effects.

Treatments:

The following are the various types of treatment that are given during the hyperthermia treatment method:

Local Hyperthermia

In local hyperthermia, heat is applied to a small area, such as a tumor, using various techniques that deliver energy to heat the tumor. Different types of energy may be used to apply heat, including microwave, radiofrequency, and ultrasound. Depending on the tumor location, there are several approaches to local hyperthermia:

  • External approaches are used to treat tumors that are in or just below the skin. External applicators are positioned around or near the appropriate region, and energy is focused on the tumor to raise its temperature.
  • Intraluminal or endocavitary methods may be used to treat tumors within or near body cavities, such as the esophagus or rectum. Probes are placed inside the cavity and inserted into the tumor to deliver energy and heat the area directly.
  • Interstitial techniques are used to treat tumors deep within the body, such as brain tumors. This technique allows the tumor to be heated to higher temperatures than external techniques. Under anesthesia, probes or needles are inserted into the tumor. Imaging techniques, such as ultrasound, may be used to make sure the probe is properly positioned within the tumor. The heat source is then inserted into the probe. Radiofrequency ablation (RFA) is a type of interstitial hyperthermia that uses radio waves to heat and kill cancer cells.

Regional Hyperthermia

In regional hyperthermia, various approaches may be used to heat large areas of tissue, such as a body cavity, organ, or limb.

  • Deep tissue approaches may be used to treat cancers within the body, such as cervical or bladder cancer. External applicators are positioned around the body cavity or organ to be treated, and microwave or radiofrequency energy is focused on the area to raise its temperature.
  • Regional perfusion techniques can be used to treat cancers in the arms and legs, such as melanoma, or cancer in some organs, such as the liver or lung. In this procedure, some of the patient’s blood is removed, heated, and then pumped (perfused) back into the limb or organ. Anticancer drugs are commonly given during this treatment.
  • Continuous hyperthermic peritoneal perfusion (CHPP) is a technique used to treat cancers within the peritoneal cavity (the space within the abdomen that contains the intestines, stomach, and liver), including primary peritoneal mesothelioma and stomach cancer. During surgery, heated anticancer drugs flow from a warming device through the peritoneal cavity. The peritoneal cavity temperature reaches 106–108°F.

Whole body hyperthermia

Whole-body hyperthermia is used to treat metastatic cancer that has spread throughout the body. This can be accomplished by several techniques that raise the body temperature to 107–108°F, including the use of thermal chambers (similar to large incubators) or hot water blankets.

The effectiveness of hyperthermia treatment is related to the temperature achieved during the treatment, as well as the length of treatment and cell and tissue characteristics. To ensure that the desired temperature is reached, but not exceeded, the temperature of the tumor and surrounding tissue is monitored throughout hyperthermia treatment. Using local anesthesia, the doctor inserts small needles or tubes with tiny thermometers into the treatment area to monitor the temperature. Imaging techniques, such as CT, may be used to make sure the probes are properly positioned.

Brachytherapy: Advantages & Treatments

Brachytherapy is a form of radiotherapy where a radiation source is placed inside or next to the area requiring treatment. Brachytherapy is commonly used as an effective treatment for cervical, prostate, breast, and skin cancer and can also be used to treat tumours in many other body sites.

Brachytherapy can be used alone or in combination with other therapies such as surgery, External Beam Radiotherapy (EBRT) and chemotherapy.

A course of brachytherapy can be completed in less time than other radiotherapy techniques. This can help reduce the chance of surviving cancer cells dividing and growing in the intervals between each radiotherapy dose. Patients typically have to make fewer visits to the radiotherapy clinic compared with EBRT, and the treatment is often performed on an outpatient basis. This makes treatment accessible and convenient for many patients. These features of brachytherapy reflect that most patients are able to tolerate the brachytherapy procedure very well.

Brachytherapy represents an effective treatment option for many types of cancer. Treatment results have demonstrated that the cancer cure rates of brachytherapy are either comparable to surgery and EBRT, or are improved when used in combination with these techniques. In addition, brachytherapy is associated with a low risk of serious adverse side effects.

Types of Brachytheraphy

Different types of brachytherapy can be defined according to

  • The placement of the radiation sources in the target treatment area
  • The rate or ‘intensity’ of the irradiation dose delivered to the tumour,
  • The duration of dose delivery

Source placement

The two main types of brachytherapy treatment in terms of the placement of the radioactive source are interstitial and contact.

  • In the case of interstitial brachytherapy, the sources are placed directly in the target tissue of the affected site, such as the prostate or breast.
  • Contact brachytherapy involves placement of the radiation source in a space next to the target tissue. This space may be a body cavity (intracavitary brachytherapy) such as the cervix, uterus or vagina; a body lumen (intraluminal brachytherapy) such as the trachea or oesophagus; or externally (surface brachytherapy) such as the skin. A radiation source can also be placed in blood vessels (intravascular brachytherapy) for the treatment of coronary in-stent restenosis.

Dose rate

  • Medium-dose rate (MDR) brachytherapy is characterized by a medium rate of dose delivery, ranging between 2 Gy·h−1 to 12 Gy·h−1.
  • High-dose rate (HDR) brachytherapy is when the rate of dose delivery exceeds 12 Gy·h−1. The most common applications of HDR brachytherapy are in tumours of the cervix, esophagus, lungs, breasts and prostate. Most HDR treatments are performed on an outpatient basis, but this is dependent on the treatment site.

Duration of dose delivery

The placement of radiation sources in the target area can be temporary or permanent.

  • Temporary brachytherapy involves placement of radiation sources for a set duration before being withdrawn. The specific treatment duration will depend on many different factors, including the required rate of dose delivery and the type, size and location of the cancer. In LDR and PDR brachytherapy, the source typically stays in place up to 24 hours before being removed, while in HDR brachytherapy this time is typically a few minutes.
  • Permanent brachytherapy, also known as seed implantation, involves placing small LDR radioactive seeds or pellets in the tumour or treatment site and leaving them there permanently to gradually decay. Over a period of weeks or months, the level of radiation emitted by the sources will decline to almost zero. The inactive seeds then remain in the treatment site with no lasting effect. Permanent brachytherapy is most commonly used in the treatment of prostate cancer.

 

Advantages:

Brachytherapy is a highly successful treatment for many types of cancer including prostate, cervix, endometrium, breast, skin, bronchus, esophagus, and head and neck, as well as soft tissue sarcomas and several other types of cancer.

Brachytherapy benefits include:

  • Is very effective in treating cancer as the radiation is delivered a high level of accuracy
  • Highly targeted conformal treatment for increased efficacy and improved sparing of healthy tissue.
  • Reduced treatment duration for certain cancer types.
  • Potential to avoid prostatectomy
  • An alternative treatment for challenging cases
  • Simplified palliative treatment option.
  • Minimizes risk of side effects
  • Minimally invasive
  • Short treatment time coupled with short recovery time. It also enables fewer visits to the hospital.

 Treatments:

Brachytherapy is commonly used to treat cancers of the cervix, prostate, breast, and skin.

Brachytherapy can also be used in the treatment of tumours of the brain, eye, head and neck region, respiratory tract, digestive tract, urinary tract, female reproductive tract, and soft tissues.

As the radiation sources can be precisely positioned at the tumour treatment site, brachytherapy enables a high dose of radiation to be applied to a small area. Furthermore, because the radiation sources are placed in or next to the target tumour, the sources maintain their position in relation to the tumour when the patient moves or if there is any movement of the tumour within the body. Therefore, the radiation sources remain accurately targeted. This enables clinicians to achieve a high level of dose conformity – i.e. ensuring the whole of the tumour receives an optimal level of radiation. It also reduces the risk of damage to healthy tissue, organs or structures around the tumour, thus enhancing the chance of cure and preservation of organ function.

Brachytherapy can be used with the aim of curing the cancer in cases of small or locally advanced tumours, provided the cancer has not metastasized (spread to other parts of the body). In appropriately selected cases, brachytherapy for primary tumours often represents a comparable approach to surgery, achieving the same probability of cure and with similar side effects. However, in locally advanced tumours, surgery may not routinely provide the best chance of cure and is often not technically feasible to perform. In these cases radiotherapy, including brachytherapy, offers the only chance of cure. In more advanced disease stages, brachytherapy can be used as palliative treatment for symptom relief from pain and bleeding.

Types of Rectal cancers &Treatments

Rectal Cancer Treatment by Stage,
Stage 0 Rectal Cancer
Stage I Rectal Cancer
Stage II Rectal Cancer
Stage III Rectal Cancer
Stage IV Rectal Cancer
Recurrent Rectal Cancer
Rectal cancer is staged much the same way as is colon cancer, but because the tumor is much lower down in the large intestine, the treatment options may vary. Surgery to remove the cancer is almost always the first treatment.

Stage 0 Rectal Cancer :

In Stage 0 rectal cancer, the tumor is located only on the inner lining of the rectum. To treat this early stage cancer, surgery can be performed to remove the tumor or a small section of the rectum where the cancer is located can be removed. Radiation treatment, given either externally (beamed in from the outside) or internally (radioactive beads are placed inside the rectum) may be considered.

Stage I Rectal Cancer:

Stage I rectal cancer is another early form or limited form of cancer. The tumor has broken through the inner lining of the rectum but has not made it past the muscular wall. Treatment usually involves:

Surgery to remove the tumor
If the tumor is small or you are very old or sick, radiation alone can be used to treat the tumor. This hasn’t proven to be as effective as surgery. Chemotherapy can also be added to heighten the effect of radiation.
Stage II Rectal Cancer:
Stage II rectal cancer is a little more advanced. The tumor has penetrated all the way through the bowel wall and may have invaded other organs, like the bladder, uterus, or prostate gland. However, lymph nodes are not involved at this stage. Treatment includes:

Surgery to remove all the organs involved with the cancer (wide-resection)
Radiation with chemotherapy is given before surgery, or after surgery; chemotherapy alone is given for 4 months after surgery.
Stage III Rectal Cancer:
In Stage III rectal cancer, the tumor has spread to the lymph nodes (small structures that are found throughout the body that produce and store cells that fight infection). Treatment includes:

Surgery to remove the tumor
Radiation with chemotherapy before or after surgery
Chemotherapy, if elected, after surgery

Stage IV Rectal Cancer:
In Stage IV rectal cancer, the tumor has spread to distant parts of the body (metastasized), often to the liver and lung. The tumor can be any size and sometimes is not that large.

The mainstay of treatment is chemotherapy, but surgery to remove the tumor may also be recommended. Surgery, when performed, is often used to relieve or prevent blockage of the rectum or to prevent rectal bleeding. It is not generally considered a curative procedure. Surgeries of this type can also help a patient with stage IV rectal cancer live longer.

If there are only one or two liver tumors, they can be removed surgically. Other options include freezing the tumors (cryosurgery) or destroying them with microwaves or heat (radio frequency ablation). Other nonsurgical directed therapies include giving chemotherapy directly into the liver using radioactive isotopes (radio-embolization) or cutting off the blood supply to the tumor in the liver (embolization). Often, chemotherapy directly into the liver is used with embolization (chemo embolization).

Recurrent Rectal Cancer:
Recurrent rectal cancer means the cancer has come back after treatment. The cancer can recur near the site of the original cancer in the rectum (local recurrence) or in distant organs. Treatment includes:

Surgery to remove local recurrences; studies show that this can help patients live longer.
If surgery can’t remove all of the recurrences, many experts recommend chemotherapy with or without radiation. This can sometimes shrink the tumor enough to allow surgical removal of the tumor afterwards.

Anemia in womens: Symptoms , Causes and Treatments

What Is Anemia?

Anemia is a condition that develops when your blood lacks enough healthy red blood cells or hemoglobin. Hemoglobin is a main part of redblood cells and binds oxygen. If you have too few or abnormal red blood cells, or your hemoglobin is abnormal or low, the cells in your body will not get enough oxygen. Symptoms of anemia — like fatigue — occur because organs aren’t getting what they need to function properly.

  • Certain forms of anemia are hereditary and infants may be affected from the time of birth.
  • Women in the childbearing years are particularly susceptible to iron-deficiency anemia because of the blood loss from menstruationand the increased blood supply demands during pregnancy.
  • Older adults also may have a greater risk of developing anemia because of poor diet and other medical conditions.

There are many types of anemia. All are very different in their causes and treatments. Iron-deficiency anemia, the most common type, is very treatable with diet changes and iron supplements. Some forms of anemia — like the anemia that develops during pregnancy — are even considered normal. However, some types of anemia may present lifelong health problems.

What Causes Anemia?

There are more than 400 types of anemia, which are divided into three groups:

  • Anemia caused by blood loss
  • Anemia caused by decreased or faulty red blood cell production
  • Anemia caused by destruction of red blood cells

Anemia Caused by Blood Loss

Red blood cells can be lost through bleeding, which often can occur slowly over a long period of time, and can go undetected. This kind of chronic bleeding commonly results from the following:

Anemia Caused by Decreased or Faulty Red Blood Cell Production

With this type of anemia, the body may produce too few blood cells or the blood cells may not function correctly. In either case, anemia can result. Red blood cells may be faulty or decreased due to abnormal red blood cells or a lack of minerals and vitamins needed for red blood cells to work properly. Conditions associated with these causes of anemia include the following:

  • Sickle cell anemia
  • Iron-deficiency anemia
  • Vitamin deficiency
  • Bone marrow and stem cell problems
  • Other health conditions

Sickle cell anemia is an inherited disorder that, in the U.S. affects mainly African-Americans and Hispanic Americans. Red blood cells become crescent-shaped because of a genetic defect. They break down rapidly, so oxygen does not get to the body’s organs, causing anemia. The crescent-shaped red blood cells can also get stuck in tiny blood vessels, causing pain.

Iron-deficiency anemia occurs because of a lack of the mineral iron in the body. Bone marrow in the center of the bone needs iron to make hemoglobin, the part of the red blood cell that transports oxygen to the body’s organs. Without adequate iron, the body cannot produce enough hemoglobin for red blood cells. The result is iron-deficiency anemia. This type of anemia can be caused by:

  • An iron-poor diet, especially in infants, children, teens, vegans, and vegetarians
  • The metabolic demands of pregnancy and breastfeeding that deplete a woman’s iron stores
  • Menstruation
  • Frequent blood donation
  • Endurance training
  • Digestive conditions such as Crohn’s disease or surgical removal of part of the stomach or small intestine
  • Certain drugs, foods, and caffeinated drinks

Vitamin-deficiency anemia may occur when vitamin B12 and folate are deficient. These two vitamins are needed to make red blood cells. Conditions leading to anemia caused by vitamin deficiency include:

  • Megaloblastic anemia: Vitamin B12 or folate or both are deficient
  • Pernicious anemia: Poor vitamin B12 absorption caused by conditions such as Crohn’s disease, an intestinal parasite infection, surgical removal of part of the stomach or intestine, or infection with HIV
  • Dietary deficiency: Eating little or no meat may cause a lack of vitamin B12, while overcooking or eating too few vegetables may cause a folate deficiency.
  • Other causes of vitamin deficiency: pregnancy, certain medications,alcohol abuse, intestinal diseases such as tropical sprue and celiac disease

During early pregnancy, sufficient folic acid can help prevent the fetus from developing neural tube defects such asspina bifida.

Bone marrow and stem cell problems may prevent the body from producing enough red blood cells. Some of the stem cells found in bone marrow develop into red blood cells. If stem cells are too few, defective, or replaced by other cells such as metastatic cancer cells, anemia may result. Anemia resulting from bone marrow or stem cell problems include:

  • Aplastic anemia occurs when there’s a marked reduction in the number of stem cells or absence of these cells. Aplastic anemia can be inherited, can occur without apparent cause, or can occur when the bone marrow is injured by medications, radiation,chemotherapy, or infection.
  • Thalassemia occurs when the red cells can’t mature and grow properly. Thalassemia is an inherited condition that typically affects people of Mediterranean, African, Middle Eastern, and Southeast Asian descent. This condition can range in severity from mild to life-threatening; the most severe form is called Cooley’s anemia.
  • Lead exposure is toxic to the bone marrow, leading to fewer red blood cells. Lead poisoning occurs in adults from work-related exposure and in children who eat paint chips, for example. Improperly glazed pottery can also taint food and liquids with lead.

Anemia associated with other conditions usually occurs when there are too few hormones necessary for red blood cell production. Conditions causing this type of anemia include the following:

Anemia Caused by Destruction of Red Blood Cells

When red blood cells are fragile and cannot withstand the routine stress of the circulatory system, they may rupture prematurely, causing hemolytic anemia. Hemolytic anemia can be present at birth or develop later. Sometimes there is no known cause. Known causes of hemolytic anemia may include:

  • Inherited conditions, such as sickle cell anemia and thalassemia
  • Stressors such as infections, drugs, snake or spider venom, or certain foods
  • Toxins from advanced liver or kidney disease
  • Inappropriate attack by the immune system (called hemolytic disease of the newborn when it occurs in the fetus of a pregnant woman)
  • Vascular grafts, prosthetic heart valves, tumors, severe burns, exposure to certain chemicals, severe hypertension, and clotting disorders
  • In rare cases, an enlarged spleen can trap red blood cells and destroy them before their circulating time is up.

Diabetes mellitus: Symptoms , Causes and Treatments

Diabetes mellitus (or diabetes) is a chronic, lifelong condition that affects your body’s ability to use the energy found in food. There are three major types of diabetes: type 1 diabetes, type 2 diabetes, and gestational diabetes.

All types of diabetes mellitus have something in common. Normally, your body breaks down the sugars and carbohydrates you eat into a special sugar called glucose. Glucose fuels the cells in your body. But the cells need insulin, a hormone, in your bloodstream in order to take in the glucose and use it for energy. With diabetes mellitus, either your body doesn’t make enough insulin, it can’t use the insulin it does produce, or a combination of both.

Since the cells can’t take in the glucose, it builds up in your blood. High levels of blood glucose can damage the tiny blood vessels in yourkidneys, heart, eyes, or nervous system. That’s why diabetes — especially if left untreated — can eventually cause heart disease, stroke,kidney disease, blindness, and nerve damage to nerves in the feet.

Types of Diabetes Mellitus :

1. Type 1 Diabetes
2. Type 2 Diabetes
3. Gestational Diabetes
4. Other Forms of Diabetes

Type 1 Diabetes:

Type 1 diabetes is also called insulin-dependent diabetes. It used to be called juvenile-onset diabetes, because it often begins in childhood.

Type 1 diabetes is an autoimmune condition. It’s caused by the body attacking its own pancreas with antibodies. In people with type 1 diabetes, the damaged pancreas doesn’t make insulin.

This type of diabetes may be caused by a genetic predisposition. It could also be the result of faulty beta cells in the pancreas that normally produce insulin.

A number of medical risks are associated with type 1 diabetes. Many of them stem from damage to the tiny blood vessels in your eyes (called diabetic retinopathy), nerves (diabetic neuropathy), and kidneys (diabetic nephropathy). Even more serious is the increased risk of heart disease and stroke.

Treatment for type 1 diabetes involves taking insulin, which needs to be injected through the skin into the fatty tissue below. The methods of injecting insulin include:

1. Syringes
2. Insulin pens that use pre-filled cartridges and a fine needle
3. Jet injectors that use high pressure air to send a spray of insulin through the skin
4. Insulin pumps that dispense insulin through flexible tubing to a catheter under the skin of the abdomen

Type 2 Diabetes:

By far, the most common form of diabetes is type 2 diabetes, accounting for 95% of diabetes cases in adults. Some 26 million American adults have been diagnosed with the disease.

Type 2 diabetes used to be called adult-onset diabetes, but with the epidemic of obese and overweight kids, more teenagers are now developing type 2 diabetes. Type 2 diabetes was also called non-insulin-dependent diabetes.

Type 2 diabetes is often a milder form of diabetes than type 1. Nevertheless, type 2 diabetes can still cause major health complications, particularly in the smallest blood vessels in the body that nourish the kidneys, nerves, and eyes. Type 2 diabetes also increases your risk of heart disease and stroke.

With Type 2 diabetes, the pancreas usually produces some insulin. But either the amount produced is not enough for the body’s needs, or the body’s cells are resistant to it. Insulin resistance, or lack of sensitivity to insulin, happens primarily in fat, liver, and muscle cells.

People who are obese — more than 20% over their ideal body weight for their height — are at particularly high risk of developing type 2 diabetes and its related medical problems. Obese people have insulin resistance. With insulin resistance, the pancreas has to work overly hard to produce more insulin. But even then, there is not enough insulin to keep sugars normal.

There is no cure for diabetes. Type 2 diabetes can, however, be controlled with weight management, nutrition, and exercise. Unfortunately, type 2 diabetes tends to progress, and diabetes medications are often needed.

An A1C test is a blood test that estimates average glucose levels in your blood over the previous three months. Periodic A1C testing may be advised to see how well diet, exercise, and medications are working to control blood sugar and prevent organ damage. The A1C test is typically done a few times a year.

 Gestational Diabetes:

Diabetes that’s triggered by pregnancyis called gestational diabetes (pregnancy, to some degree, leads to insulin resistance). It is often diagnosed in middle or late pregnancy. Because high blood sugar levels in a mother are circulated through the placenta to the baby, gestational diabetes must be controlled to protect the baby’s growth and development.

According to the National Institutes of Health, the reported rate of gestational diabetes is between 2% to 10% of pregnancies. Gestational diabetes usually resolves itself after pregnancy. Having gestational diabetes does, however, put mothers at risk for developing type 2 diabetes later in life. Up to 10% of women with gestational diabetes develop type 2 diabetes. It can occur anywhere from a few weeks after delivery to months or years later.

With gestational diabetes, risks to the unborn baby are even greater than risks to the mother. Risks to the baby include abnormal weight gain before birth, breathing problems at birth, and higher obesity and diabetes risk later in life. Risks to the mother include needing acesarean section due to an overly large baby, as well as damage to heart, kidney, nerves, and eye.

Treatment during pregnancy includes working closely with your health care team and 

  • Careful meal planning to ensure adequate pregnancy nutrients without excess fat and calories
  • Daily exercise
  • Controlling pregnancy weight gain
  • Taking diabetes insulin to control blood sugar levels if needed.

Other Forms of Diabetes:

A few rare kinds of diabetes can result from specific conditions. For example, diseases of the pancreas, certain surgeries and medications, or infections can cause diabetes. These types of diabetes account for only 1% to 5% of all cases of diabetes.

 
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