Death From Simple Infections: Disorders of Neutrophils

White blood cells (WBC) are made in our bone marrow and are absolutely imperative to fight infection. Without WBCs, we would succumb to even the most benign viruses and bacteria (i.e. germs) in our environment and die at a very early age. Once WBCs are made, they are released into the blood to mix with the RBCs (cells that carry oxygen) and circulate around our body. Stem cells in the bone marrow give rise to multiple WBC types, namely lymphocytes (T cells and B cells), neutrophils, basophils, eosinophils, and monocytes. Each type of WBC has a specific function. Eosinophils, for example, are important when fighting parasitic infectious. Many people are familiar with the Human Immunodeficiency virus (HIV), a disorder of T cells which impairs the body's ability to fight life-threatening bacterial and fungal infections. Neutrophils play a major function in our first line of defense against bacteria and fungi, and problems with them can carry grave consequences.

Neutrophils are typically first to the scene of an infection or traumatic injury. They are very quick, and their lifespan is only a few days. They follow chemical trails left behind by inflammation and, when they arrive, they suck bacteria into the center of their cell where some sanitizing then takes place- trapped bacteria are basically bathed in hydrogen peroxide. Two things can go wrong in this fight against the bacteria: either the neutrophils fail to work correctly, or the numbers of neutrophils are far too low to overpower invaders. Mildly low levels lead to oral/vaginal/rectal ulcers, ear infections, and skin abscesses. Severely low levels lead to overwhelming infection and death.

Disorders of the FUNCTION of neutrophils:
Congenital Leukocyte Adhesion Deficiency 1. Neutrophil movement is affected, so they are slow and fail to arrive to the scene of the infection. Newborn infants have delayed separation of their umbilical cord or infection where the cord meets the belly (omphalitis)

Chronic Granulomatous Disease. The release of the hydrogen peroxide inside the cell ("respiratory burst") doesn't work properly. Children need lifetime antibiotics (bactrim)

Hyperimmunoglobulin E Syndrome. The neutrophils don't follow the chemical trail to the site of infection like they are supposed to. Levels of an immune globulin called IgE are very high, and children have recurrent "cold" (non-red, non-tender) staph abscesses.

Chediak-Higashi Syndrome. There is a problem bringing the bacteria into the cell to sanitize them. Children also have albinism and their condition is worsened by infection with Epstein-Barr virus (EBV)


Disorders of the NUMBER of neutrophils:
External factors. Neutropenia caused by viruses (some viruses "shock" the stem cells and cause them to stop functioning for a period of time) or cancer chemotherapy

Autoimmune disorders. Neonatal Isoimmune Neutropenia occurs briefly in infants, whereby their mothers release antibodies that cross the placenta and attack their neutrophils. The disorder will resolve in less than 3 months. After 3 months, the baby can make their own antibodies against neutrophils leading to autoimmune neutropenia of infancy or chronic benign neutropenia.

Genetic syndromes. Shwachman-Diamond and Kostman Syndrome are characterized by low levels of neutrophils. Another interesting disorder is termed cyclic neutropenia, characterized by 3 day periods of neutropenia occurring every 21 days.

Newborn Nursery

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Thinking about having a baby?

Ever wonder what happens in the newborn nursery?

Multiple factors affect the care of a newborn in the first 48 hours. Here are just a small number of scenarios encountered and managed by pediatricians in the nursery:

 

 Small for gestational age (SGA):  <10^th percentile for weight. If no apparent reason for the small weight (maternal hypertension or tobacco use), the urine is tested for infection (cytomegalovirus) and drugs. If the infant is below 2500 grams (5.5 pounds), a car seat evaluation is performed (to ensure infant can breathe well while in the car seat) and breastfeeding may be supplemented with a high-calorie formula. A blood test is performed to check hemoglobin levels.

Large for gestational age (LGA): >90^th percentile for weight. The biggest concern is polycythemia (or too much blood), so a blood test is performed to check the hematocrit. 

Preterm: Very premature infants go to the NICU for intensive care. The babies just under 37 weeks, however, can stay in the nursery. There, as with SGA , a car seat evaluation may be  performed  and breastfeeding may be supplemented with a high-calorie formula. A blood test is performed to check hemoglobin levels.

Meconium-stained amniotic fluid: The infant’s first stool is accidently passed into the amniotic fluid before delivery. The consistency ranges from thin to thick. This can be dangerous if the infant inhales the material during his or her first breath, resulting in respiratory distress known as meconium aspiration syndrome. A resuscitation team will be present in case this happens and will perform deep suctioning to remove it.

Chorioamnionitis: Infection of the amniotic fluid that the fetus lives in. A maternal infection, defined as fever of 100.4 degrees or greater along with other signs, could cause this fluid to get infected, which is potentially deadly for the infant. Blood tests are drawn to check for signs of infection in the baby. Antibiotics are started prophylactically. The tests are repeated at 36 hours of life.​ 

Breastfeeding is always encouraged in infants. Most babies turn out just fine, but it's good to always be prepared.

Ear Infection in Children

Ear infections are one of the most common disease processes seen by pediatricians. It is estimated that up to 85% of children suffer from at least one episode of ear infection before the age of 3.

The typical age range during which ear infections are seen is from 6 to 15 months old. Symptoms range from mild pain to hearing loss and brain abscess. There are three areas that become infected in the ear, and to understand this requires some knowledge of the anatomy:

The external or outer ear is where otitis externa (OE), also known as swimmer's ear, occurs. This is  is the only infection that causes pain with manipulation of the ear. The outer ear will usually be red and tender the the touch. The most common cause of this is a bacteria called pseudomonas, which thrives in wet conditions. The treatement for this, therefore, is over the counter ear drops that dry out the ear canal and make the area uninhabitable for the bacteria.

The middle ear is behind the eardrum or tympanic membrane. It is the space that houses the ear ossicles, the bones which transmit sound from the eardrum to the cochlea of the inner ear. This area is connected to the back of the nose (pharynx) via a hollow tube known as the eustachian tube.  An infection of this space is known as otitis media (OM). There are different types of OM, depending on the length of time it has persisted and whether or not fluid (effusion) is present.

Acute otitis media (AOM) typically occurs in <2 years old, usually caused by viruses such as RSV, cytomegalovirus (CMV) and Haemophilus influenzae (Hflu) but can also be due to bacteria. Mucosal congestion caused by the upper respiratory infection (URI) is aspirated up into the middle ear where inflammation occurs.
Treatment: If younger than 2 years old, an antibiotic such as amoxicillin will be prescribed. If older than 2 years old, doctors may choose to wait 48 hours to see if symptoms improve on their own before deciding to add an antibiotic. This is because studies have shown spontaneous resolution (without treatment) in up to 80% of this age group in 2-14 days.

Otitis media with effusion (OME) occurs when bacteria gets into the middle ear and fills it with pus. In growing children less than 7, the eustachian tube is often short and less vertical, so pus cannot drain properly and begins to back up. This growing pocket of fluid causes a large amount of pressure and pain to the child. The doctor will use a pneumatic otoscope to blow a burst of air at this ear drum. Normally the ear drum will move but in the case of OME, no movement occurs. Tympanometry may also be used to determine this. Long term OME (>3 episodes in 6 months or >4 episdoes in 12 months) may lead to hearing and language problems, so treatment is often indicated.
Treatment: myringotomy (hole is cut into the ear drum) with tympanostomy tube insertion is surgically performed. This allows fluid to freely drain out of the ear instead of backing up. It also alows antibiotic drops to be placed in the ear, which move through the tube and into the middle ear space to treat bacterial infections. Parents are instructed to apply the drops for 10 days whenever they see pus draining from the ears, which allows them to treat infections at home.

Reference

American Academy of Family Physicians, American Academy of Otolaryngology-Head and Neck Surgery, American Academy of Pediatrics Subcommittee on Otitis Media with Effusion. Otitis media with effusion. Pediatrics 2004; 113(5): 1412-29.

Heart Attacks in Children? The Kawasaki Disease Epidemic

A recent study out of Australia published in the Journal of Pediatrics revealed that cases of the potentially deadly Kawasaki Disease are steadily increasing. Kawasaki Disease (KD) is a poorly understood condition known as vasculitis, which is the inflammation of small blood vessels. The disease is known for attacking the coronary arteries of children, the vital blood vessels supplying the heart muscle with oxygen and other nutrients. The child suffers from an acute fever and severe pain, essentially symptoms of both infection and a heart attack.

Doctors do not know the cause of KD, but they believe it may be infectious in origin because most cases occur between the winter and spring, and epidemics occur frequently.  KD most commonly affects Japanese children and those of Japanese ancestry: the incidence in Japan has been steadily increasing, from 102 per every 100,000 children <5 years old to 188 in 2006.  In the United States, it is 17.1 per 100,000 children <5 years old, but clinicians fear this number will continue to increase.

85% of children suffering from KD are <5 years old, and the median age is 2 years old. The symptoms begin with a high fever that lasts a minimum of 5 days and lasts as long as 4 weeks. The child typically experiences redness and swelling of his or her hands and feet and a morbilliform rash of the face and extremities. The lips and mouth will typically dry out, crack and blister.

Meanwhile, inside the coronary arteries, the body is attacking the vascular smooth muscle and causing inflammation that will lead to scarring and poor vessel integrity.  It is for this reason that coronary artery aneurysm (ballooning and tearing) occurs in 25% of cases, particularly if the child is less than 6 months or older than 6 years old. Other complications include myocardial infarction, cardiac arrest, heart failure, myocarditis and pericarditis. Two reports have noted children becoming insulin dependent diabetic within 4 months of the vasculitis.

When the pediatrician recognizes these harrowing symptoms, he or she will order an echocardiogram to visualize the heart.  When a blood test reveals high white blood cells (leukocytosis), high erythrocyte sedimentation rate (ESR) and high C-reactive protein (CRP), a diagnosis can be made.

The treatment for KD is intravenous immunoglobulin (IVIG), which is an injection of IgG (long-term) antibodies pooled from over 1,000 blood donors. High dose aspirin with or without corticosteroids is also administered to help reduce swelling and prevent a heart attack. The child should follow up with a cardiologist for repeated echocardiograms and long-term monitoring, since the highest risk for a heart attack is in the first year after diagnosis.

Until more is learned about KD and its origins, it will be added to a long list of autoimmune diseases that are poorly understood but well respected in the medical community.  

References

Saundankar J1, Yim D, Itotoh B, Payne R, Maslin K, Jape G, Ramsay J, Kothari D, Cheng A, Burgner D. The epidemiology and clinical features of Kawasaki disease in Australia. Pediatrics. 2014; 133(4):e1009-14.

Kawasaki Disease. Dynamed Database. Updated June 9, 2014. Accessed June 13, 2014.

Protect Your Baby From Bronchiolitis

Bronchiolitis is a relatively common respiratory condition seen in children younger than 2 years old.  According to a recent study out of Finland published in the Scandanavian journal Acta Paediatrica, bronchiolitis is a major cause of lower respiratory tract illness and hospitalization in babies, especially those younger than 6 months old. The condition is mostly caused by the respiratory syncytial virus (RSV), which is the infectious agent in over 75% of cases.  Other viruses, including influenza (flu) and adenovirus represent the remaining 25% and in many cases exist as co-infections.

RSV season typically begins in October and ends in April.  The virus is spread via the hands of caregivers and other inanimate surfaces (fomites), and can stay alive on them for several hours. The virus enters the respiratory tract and infiltrates the top cell layer of the lungs, known as bronchiolar epithelium, causing inflammation and swelling and obstructing the small airways. Once this happens, air passing through these small spaces emits a whistle-like sound that can be heard as a wheeze outside of the body.

This wheeze, along with a runny nose (rhinitis), cough, and fever, is suggestive of  RSV bronchiolitis. It is important, however, for the pediatrician to rule out other disease processes, such as pneumonia or foreign body aspiration. Studies have shown that infants <12 weeks old, particularly those who were premature at birth, have an increased risk of requiring hospitalization and medical intervention. For many babies, though, this disease is self-limiting and no tests or treatments are necessary.

There are established risk factors for RSV that you can’t avoid; childcare attendance, school aged siblings, prematurity, congenital cardiopulmonary disease and immunodeficiency. But the steps listed below have been shown to reduce the risk of spreading RSV:

• When in a group setting such as daycare or doctors offices, be sure that you and others caring for your children decontaminate their hands with alcohol-based sanitizer before and after direct contact with children or inanimate objects

• Do not smoke tobacco or wear clothing that has been around cigarette smoke unless it has been thoroughly washed

• Avoid exposing your infant to air pollutants

• Always breastfeed your infant whenever possible to allow your infant's immune system to strengthen

• Always follow current vaccination guidelines, including the flu vaccine

References

Bronchiolitis. Dynamed Database. Updated 2014 May 12 02:17:00 PM. Accessed June 6 2014. 

Pruikkonen H1, Uhari M, Dunder T, Pokka T, Renko M. Infants Under Six Months With Bronchiolitis Are Most Likely To Need Major Medical Interventions In The Five Days After Onset. Acta Paediatr. 2014 [Epub ahead of print]

How to Recognize Croup in Your Child

Pay close attention to your child’s next cough- it may suggest a common but serious childhood condition known as croup. Experienced pediatricians can recognize this particular cough in a crowded room; a sound often described as a “seals bark” that carries a potentially deadly omen. The medical term for this condition is laryngotracheobronchitis- a complicated word for inflammation of the upper respiratory tract, specifically the trachea and larynx.

Croup is most commonly caused by any one of several viral infections, including parainfluenza, influenza (flu), rhinovirus (common cold), adenovirus, respiratory syncitial virus (RSV), enterovirus and echovirus. In about 20% of cases, bacterial infections such as Mycoplasma pneumoniae, Corynebacterium diptheriae or staph or strep species are to blame.

The typical case of croup begins in a child under 6 years old between the fall and early winter months: The child has a history of an upper respiratory infection with fever and a cough that worsens at night.  The child's breathing becomes increasingly more labored, and a high pitched sound on inspiration known as stridor develops. This characteristic barking cough may follow:

How does this happen? When the upper airways become inflamed by an infection, swelling begins to narrow the passageway below the glottis through which air travels. As the airway narrows, our bodies attempt to compensate for poor airflow by increasing the respiratory rate (breaths per minute). The result is rapid air exchange through a narrowed airway (stridor), poor ventilation/oxygenation and respiratory distress.

It’s important that a pediatrician evaluates any child with stridor. Though many cases are self limiting and resolve in less than 48 hours, the doctor will rule out more serious conditions that present in a similar fashion, particularly epiglottitis, bacterial tracheitis and aspiration of a foreign budy. A simple oral dose of steroids (dexamethasone 0.15-0.60 mg/kg) will rectify the child’s breathing difficulties, though moderate to severe cases require inhaled (nebulized) racemic epinephrine.

• A diagnosis of epiglottitis is more likely when the child is experiencing excessive drooling and leaning over in a “sniffing position”.

• If the child is not treated, croup may lead to severe respiratory distress or become complicated with a pneumonia (known as laryngotracheobronciopneumonia)

• There are reports of repeated cases of croup, known as  spasmodic croup, that may be caused by gastroesophageal reflux disease (GERD) or extreme sensitivity to the parainfluenza virus.

• Any time your child is suffering from an upper respiratory infection, he or she is at an increased risk for developing croup

References

Croup. Dynamed Database. Updated December 27, 2013. Accessed June 2, 2014.

Petrocheilou A, Tanou K, Kalampouka E, Malakasioti G, Giannios C, Kaditis AG. Viral croup: diagnosis and treatment algorithm. Pediatr pulmonol. 2014; 49(5): 421-9.

Pediatric autoimmune neuropsychiatric disorders associated with streptococcal infection (PANDAS)

Does a simple sore throat lead to psychological symptoms such as obsessive compulsive disorder (OCD) or Tourette syndrome?

In 1998, physicians began reporting odd encephalitis (brain inflammation)-like symptoms following an infection with Group A beta-hemolytic Streptococcus (GABHS), a bacterial infection.

Currently, PANDAS is not an ICD-9 recognized disease, and there is no recommended treatment. The suggested diagnostic criteria for PANDAS is abrupt onset (or dramatic exacerbations) of OCD or tic disorder, beginning between 3yo and the start of puberty, that occurs following an infection with GABHS. The neurologic examination would reveal hyperactivity, choreiform (snake-like) movements and/or tics.

Several studies have explored this phenomenon with conflicting results. Some authors found no correlation, while others found only elevated ASO (antibody) titers or the worsening of preexisting tic or OCD disorders. While some retrospective studies verified an association between infection and these neurological changes, a direct relationship has not been established.

Many clinicians think that PANDAS is simply a misdiagnosis of Sydenham’s chorea, a criteria for acute rheumatic fever (also caused by streptococcal infection) that is characterized by spastic and purposeless movements of the face or arms. Similarly to rheumatic fever, researchers believe that PANDAS may be due to the accidental production of antibodies that attack an area of the brain known as the basal ganglia.

•  If your child develops a sudden tic or movement disorder, or begins to display uncharacteristic psychological behavior, it is important to contact your physician. While PANDAS may be only temporary, acute rheumatic fever can lead to serious heart problems.

Reference

Pediatric autoimmune neuropsychiatric disorders associated with streptococcal infection (PANDAS). Dynamed Database. Updated February 19, 2013, Accessed May 24, 2014.

MERS Virus Not Considered a Major Threat to the U.S.

Middle East Respiratory Syndrome (MERS) virus has made its way into the United States after killing hundreds in the Middle East. The MERS virus, first isolated in 2012, is a coronavirus that spreads through respiratory droplets and causes a severe acute respiratory illness. Symptoms of infection include fever, cough and shortness of breath.

MERS, similar to the flu, can be quite dangerous to the elderly and those with compromised immune systems. Since it’s transmitted following close human-to-human contact, family members caring for their sick relatives can easily contract the virus. This seems to be why so many have been infected in the Middle East: Owing to poor living conditions and the lack of proper medical care, an estimated 30% of those infected have died.

Two confirmed cases have been reported in patients traveling from the Arabian Peninsula to the United States.

On May 2, MERS was confirmed in an Indiana hospital. The patient, a healthcare worker, had recently arrived from Saudi Arabia following layovers in London and Chicago. He was isolated and successfully treated. Shortly after, an Illinois resident whom had close contact with the infected patient before his hospitalization began exhibiting symptoms of infection. He tested positive for antibodies to the virus, suggesting he suffered a very mild illness before fully recovering.

On May 11, MERS was reported in an Orlando hospital. The patient, a healthcare worker, was traveling from Saudi Arabia and reported layovers in London, Boston and Atlanta. He felt unwell during the flight, so visited the Emergency Room after landing. He was successfully treated and is currently in good health.

The current strain of MERS virus is not a major threat to the United States. Still, communities of immuno-compromised citizens in close quarters are at risk. It is for this reason that hospitals and nursing homes across states like Florida are warning residents to stay aware of the warning signs.

• All viruses have the ability to mutate into a deadlier strain

• There is no evidence of sustained spreading in community settings

• If you’ve been in close contact with one of the individuals infected by MERS, call your healthcare professional and inform them promptly

• Always wear a protective mask (such as N95) when caring for a patient or relative with a cough and a fever

Reference

Middle East Respiratory Syndrome (MERS). Centers for Disease Control and Prevention. Accessed May 19, 2014. http://www.cdc.gov/coronavirus/mers/index.html

The Importance of Identifying a Morbilliform Rash

The term "morbilliform" is used to describe any skin finding that resembles the measles rash. The macular lesions are typically diffuse, red and 2-10 mm in diameter. They may become confluent (come together to form clusters) in some areas. 

It is very important for doctors to know the differential diagnosis for a morbilliform rash, since some of the conditions are deadly. The process occurring within the body leading up to the rash, known as the prodrome, will help the physician narrow the diagnosis.This prodrome can be learned by ascertaining a good history. 

Some notable causes of morbilliform rash are:

• Fifth Disease (erythema infectiosum/parvovirus B19/)
• Sixth disease (roseola infantum/herpesvirus 6)
• Streptococcal infection (Groups A, C)
• Echovirus
• Adenovirus
• Kawasaki Disease
• Rubella
• Measles
• Syphilis
• Meningeal Petechiae (or Waterhouse Friedrichsen Syndorme)
• Drug hypersensitivity Reaction (especially nevirapine, abacavir, phenytoin)

A study by Ramsay et al in 2002 evaluated the laboratory samples of 93 vaccinated children in England, and noted that the most common cause of the rash was a parvovirus B19 infection (17%). Group A strep was found in 15% of cases, and sixth disease (roseola infantum or herpesvirus 6) in 11%. None of the cases were caused by measles. The use of widespread vaccination has nearly eliminated the measles infection, making way for other viruses that cause similar rashes. It is paramount that physicians discern the cause of the findings.

Reference

Ramsay M, Reacher M, O'Flynn C, Buttery R, Hadden F, Cohen B, Knowles W, Wreghitt T, Brown D. Causes of morbilliform rash in a highly immunised English population. Arch Dis Child. 2002 Sep;87(3):202-6.

An Update on Cat Scratch Fever

Cat Scratch Disease, also known as Cat Scratch Fever, is found in more locations than just a Ted Nugent album. This disease, first isolated in 1992, is caused by a bacteria called Bartonella henselae and affects roughly 6.6 in every 100,000 children in the United States. It's mostly benign (harmless), and in some cases goes unnoticed. Every now and then, though, a mother may see this in her child and become concerned:

The bacteria is transmitted to cats, typically kittens, by fleas. When a child is scratched by the cat, or in some cases pets the cat and then rubs his or her eye, the bacteria enters their bloodstream.

In 2-3 weeks, the child will develop lymphadenopathy, or the enlargement of the lymph nodes. The most common location of the lymphadenopathy is in the neck (33% of cases), followed by the axilla (underarm, 27%) and inguinal (groin, 18%). The child will also develop the characteristic fever and may complain of a sore throat.

In children with weak immune systems (immunocompromised), the disease may become disseminated (spread throughout the body) and cause infection of the bone (osteomyelitis), brain (encephalitis, resulting in seizures) and eye (oculoglandular conjunctivitis). In children with heart valve problems, this disease may cause endocarditis (infection of heart valve). For this reason, the CDC recommends that these children and adults avoid playing with cats or kittens, especially those with fleas.

Since the disease goes away on its own, a doctor will only need to prescribe pain medication for the painful lymph nodes. There is limited evidence that antibiotics are helpful in treating Cat Scratch Fever, so put on an old record and let Ted do all of the work.

• Cases in adults are not uncommon. 80% of patients with cat-scratch disease are < 21 years old

• Cases of dogs, monkeys, porcupine quills and thorns have been reported

• The disease is not contagious. There are no reports of person-to-person transmission

• Laboratory diagnosis is difficult, since the organism can be difficult to see. Currently, polymerase chain reaction (PCR) or Warthin-Starry Stain is used

• Differential diagnosis of chronic lymphadenopathy includes L. venereum, mycobacteria, tularemia, brucellosis. mononucleosis, syphilis, toxoplasmosis, systemic fungal infections, sarcoidosis, lymphoma, connective tissue disease and kawasaki disease

Reference

Cat Scratch Disease. In DynaMed [database online]. EBSCO Information Services. 

Updated 2012 Oct 25. Accessed May 10, 2014.

SIRS: The End of a Deadly Disease Spectrum

When an infant or child falls very ill, one of the most feared complications is systemic inflammatory response syndrome (SIRS). 

SIRS is a deadly ending to a spectrum of bloodstream infection which begins when a bacteria or virus enters the bloodstream (bacteremia). In most cases, young bodies can successfully fight off the organism before it causes any serious problems. Unfortunately, this is not always the case. Sometimes, the immune system goes a bit too far and decides to put all of its cards on the table. It releases everything it has, including white blood cells, pro-inflammatory molecules and blood-clotting proteins. This most often leads to the loss of fluids in our blood vessels and the collapse of our circulatory system. Inside the body, the organs (heart, lungs, kidneys, brain) lose vital oxygen and nutrients and begin to shut down. Outside the body, doctors notice signs of shock, which include fever and changes in breathing, heart rate, mental status, blood pressure and temperature regulation. If caught very early, doctors can typically keep the patient alive. In many cases, however, nothing the physician does will save the patient from the downward spiral.

The inci­dence of SIRS is highest in infants (5.16 per 1000), occurring in 20% of low birthweight neonates and resulting in death in over 10% of cases. Studies show that 37% of infections leading to SIRS arise from the respiratory tract, while 25% are primary bloodstream infections (BSIs). 

The management of SIRS is performed in a neonatal intensive care unit (NICU) or pediatric intensive care unit (PICU). Doctors will culture the blood and monitor vital organs while ensuring the body is receiving adequate oxygen. A broad spectrum antibiotic (fights many different infections) is started until a culture comes back from the lab showing what specific organism is causing all the trouble. The antibiotic is then switched to one specifically formulated to kill that bug. One of the most frightening scenarios for a physician is when the culture comes back showing a bacteria that is resistant to all the drugs we have available. This is becoming the case with some gram negative bacteria (Klebsiella and E. coli) that release something called endotoxin and are resistant to our last line of antibiotic defense against them, carbapenems.

Scientists and physicians continue to conduct studies in order to discover ways to prevent SIRS from occurring. Though many different types of treatments have been attempted, the most effective of them continues to be early detection with  prompt antibiotic administration and fluid resuscitation.

• Occasionally, other conditions can trigger SIRS (trauma, ARDS, neoplasm, burn injury, pancreatitis)
• In order to reduce your child's risk, always ensure they are up to date on their vaccinations and be sure to keep them away from undercooked meat, especially beef and chicken.

References

Principles and Practice of Pediatric Infectious Diseases. Judith A. Guzman-Cottrill, Beth Cheesebrough, Simon Nadel, and Brahm Goldstein. Part II, Section A, 11: The Systemic Inflammatory Response Syndrome (SIRS), Sepsis, and Septic Shock. Pg 97-104.

Is Ebola Coming To America?

The deadly Ebola virus has again struck the human race and attracted media attention in it's wake, particularly in the United States. For many, simply hearing or reading about Ebola evokes an uncomfortable and fearful feeling, partly due to media attention and movies like Outbreak but mostly because of the mystery that surrounds it. 

Is this virus as threatening to us as we make it out to be?

The Ebola virus likely begins it's life in African caves and mines within the bodies of fruit bats. Epidemics seem to begin when a single farmer or miner comes into contact with the infected animal. After seven days of incubation (virus making millions of copies of itself), the man develops sudden flu-like symptoms (headache, body ache, fever) and severe diarrhea that rapidly progress to cell death (necrosis), multi-organ failure, shock, widespread bleeding and, in many cases, death. Often, hospital staff or family members also become infected through contact with the patient's bodily fluids. 

Every couple of years, Ebola cuts through the middle of Africa like a knife, killing up to 88% of those it infects. It's monitored closely by the Center for Disease Control (CDC) for two important reasons: it easily spreads through the air (aerosol) and kills more than half of those it infects (high mortality rate). This is a harrowing combination for a virus but, despite it's label as a biosafety level 4 pathogen, it's currently not very threatening to the human race. Good sterilization and isolation processes help prevent rapid and deadly spread.

It's the fear of the unknown, though, that keeps scientists wary.

Ebola's lethal potential is recognizable in non-human primates: the virus has caused massive die-offs in gorilla and chimpanzee groups. It seems that the primates produce more infectious aerosol particles than do humans, attributing to the lethality. Luckily, these primate infections rarely spread to humans: only 25 human cases have been acquired from monkeys, with seven ending in death. The typical infection transmitted to humans from primates is more on par with a common cold. If this virus were to acquire the same virulence (or lethality) in humans as in monkeys, the results would be catastrophic. For now, however, it seems that Ebola is a manageable illness with little threat to the Americas.

• There are five known species of Ebola, each named for the regions where they were originally identified.  The first reported cases in 1967 included 550 humans in Zaire and Sudan. The Zaire Ebola virus recurred in Gabon in 1994, causing 317 cases. The Sudan Ebola species returned in 2004, but this time in Uganda, killing 224 (53%) of 425 patients. 

• The inflammatory response caused by the virus often leads to the body losing all it's platelets (used to plug holes), resulting in bleeding through multiple orifices.  It is for this reason it is known as a "hemorrhagic fever"

• A new Ebola vaccine has been developed, but low funding has halted human trials. It may be as long as 20 years before the vaccine is commercially available. 

References

Peters CJ. Chapter 197. Ebola and Marburg Viruses. In: Longo DL, Fauci AS, Kasper DL, Hauser SL, Jameson J, Loscalzo J. eds. Harrison's Principles of Internal Medicine, 18e. New York: McGraw-Hill; 2012.http://accessmedicine.mhmedical.com.ezproxy.hsc.usf.edu/content.aspx?bookid=331&Sectionid=40726956. Accessed March 22, 2014.

Deciphering Your Recent Blood Test, Part 1 of 3

On your recent visit to the doctor's office, you had the pleasure of getting stuck with a needle and drained of a few small tubes of your blood. You were left with a painful memory, a small bruise at the site of injection and a printout of the results. You spend a few seconds looking through the words and values before giving up, but wouldn't it be helpful if you really knew what all of those numbers meant? 

The laboratory blood test is one of the most useful diagnostic tools of the modern physician. It allows the provider to peer inside the body like a mechanic checks under the hood. There are many blood tests available, from single tests on proteins to "panels" containing several different measurements. Two commonly ordered panels are the complete blood count (CBC) and the comprehensive metabolic panel (CMP).

CBC

Our blood is made up primarily of red blood cells (RBC) and white blood cells (WBC). The RBCs carry nutrients through the body, while the WBCs protect us either by filling holes (platelets) or by attacking and killing whatever looks suspicious (leukocytes). The colors are red and white because, simply, when you spin the blood around very fast, these cells separate based on weight and reveal red-colored and white colored fluids. The CBC is performed by a machine that lines the blood cells up in a single row and counts how many are present in a set amount (microliter) of blood. 

WBC. An increase in WBC typically suggests that our body is training an army to kill an infection. This can also be elevated in cases of cancer or with the administration of steroid medications. The specific types of WBCs (neutrophils, eosinophils, basophils, monocytes or  lymphocytes) help give insight as to what type of infection may be present (for example, neutrophils are released acutely for bacterial infections). Decreases in WBCs are seen most commonly as a side effect of medications such as chemotherapy, antibiotics and anti-seizure drugs. In other cases, a decrease may suggest that something is killing them (infection, alcohol, autoimmune, radiation) or that there is a problem within the factory that produces them (the bone marrow). 

RBC and Hemoglobin. The primary role of the RBC is to carry oxygen, using hemoglobin, to cells so they can use it to make energy. When RBCs are decreased, it is known as anemia. This can be caused by iron (holds on to oxygen) deficiency, blood loss from chronic diseases, genetic diseases such as sickle cell anemia, significant bleeding or a problem with the factory that produces RBCs (the bone marrow). Increased RBCs can be seen in cases of dehydration, chronic breathing problems (COPD) and some cancers of the bone marrow.

Hematocrit. This is simply the ratio of red to white fluid when the blood is spun around very fast in a centrifuge. Normally, 46% of blood is RBCs. If this number is low, it's an anemia. 

MCV. This is the size of the RBC, much like measuring the square footage of a house. Increased MCV is seen with alcoholism, vitamin deficiency (B12 and/or folate) and a stomach disorder called pernicious anemia. Decreased MCV suggests one of the anemias described above.

MCH and MCHC. These measure the amount of hemoglobin per RBC, helping the physician narrow down the type of anemia present. MCHC is decreased in the anemias described above, and elevated in some genetic diseases.

RDW. This compares the RBCs to one another. If there is a large discrepancy between them, meaning some are very large and others are very small, this number will be high. The most common cause of this is iron deficiency anemia.

Platelets. Platelets are very important because they plug holes and cracks to stop bleeding. Low platelets are dangerous because it increases the risk of bleeding, whether out of a wound or into body cavities like the head or digestive system. High platelets are also dangerous because they cause over-clotting, which can lead to obstruction of blood vessels and thus problems like stroke and heart attack. Platelets are often kept intentionally low with medication (such as aspirin) to reduce the risk of stroke and heart attack. Many rare diseases and some cancers can also cause low platelet counts. 

• Parts 2 and 3 of this section, coming soon, will cover the CMP and other specialty tests.

• Your physician should discuss any abnormal blood test result with you. 

• Visit our resources at thedailydiagnosis.com for more trusted information on blood tests.

References

Chapter 5. Laboratory Diagnosis: Clinical Hematology. In: Gomella LG, Haist SA. eds. Clinician's Pocket Reference: The Scut Monkey, 11e. New York: McGraw-Hill; 2007. 

Klepin HD, Powell BL. Chapter 103. White Cell Disorders. In: Halter JB, Ouslander JG, Tinetti ME, Studenski S, High KP, Asthana S. eds. Hazzard's Geriatric Medicine and Gerontology, 6e. New York: McGraw-Hill; 2009. 

Verhovsek M, McFarlane A. Chapter 173. Abnormalities in Red Blood Cells. In: McKean SC, Ross JJ, Dressler DD, Brotman DJ, Ginsberg JS. eds. Principles and Practice of Hospital Medicine. New York: McGraw-Hill; 2012.