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Pertussis. Dr. Rezai MS Pediatrics infectious disease sub specialist. ETIOLOY. Bordetella pertussis Bordetella parapertussis is an occasional cause Exclusive pathogens of humans and some primates. B. bronchiseptica is a common animal pathogen. Protracted coughing. Mycoplasma
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Pertussis Dr. Rezai MS Pediatrics infectious disease sub specialist
ETIOLOY • Bordetella pertussis • Bordetella parapertussis is an occasional cause • Exclusive pathogens of humans and some primates. • B. bronchiseptica is a common animal pathogen.
Protracted coughing • Mycoplasma • Parainfluenza or influenza viruses • Enteroviruses • Respiratory syncytial virus • Adenoviruses.
EPIDEMIOLOY • 60 million cases of pertussis each year • >500,000 deaths. • Widespread use of pertussis vaccine led to a >99% decline in cases. • Pertussis is increasingly endemic.
EPIDEMIOLOY • Approximately 60% of cases are in adolescents and adults. • Infants have the highest morbidity • Pertussis is extremely contagious attack rates as high as 100%
EPIDEMIOLOY • Chronic carriage by humans is not documented. • After intense exposure as in households, the rate of subclinical infection is as high as 80% in fully immunized or previously infected individuals.
EPIDEMIOLOY • Neither natural disease nor vaccination provides complete or lifelong immunity against reinfection or disease. • Protection against typical disease wane 3-5 yr after vaccination unmeasurable after 12 yr
PATHOGENES • B.ordetella organisms are tiny, fastidious, gramnegative coccobacilli that only colonize ciliated epithelium. • Only B. pertussis expresses pertussis toxin (PT), the major virulence protein. • (PT), histamine sensitivity, insulin secretion, leukocyte dysfunction
PATHOGENES • PT causes lymphocytosis immediately • Tracheal cytotoxin, adenylate cyclase, and PT appear to inhibit clearance of organisms. • Tracheal cytotoxin, dermonecrotic factor, and adenylate cyclase are postulated to be predominantly responsible for the local epithelial damage that produces respiratory symptoms and facilitates absorption of PT.
CLINICAL MANIFESTATION 3stages • Catarrhal • paroxysmal • convalescent
CLINICAL MANIFESTATION • incubation period ranging from 3-12 days • catarrhal stage (1-2 wk) begins insidiously congestion and rhinorrhea, lacrimation low-grade fever sneezing conjunctival suffusion
CLINICAL MANIFESTATION • paroxysmal stage (2-6 wk). • The cough begins as a dry, intermittent, irritative hack and evolves into the inexorable paroxysms that are the hallmark of pertussis. • anxious aura, whoop follows after caugh • Post-tussive emesis is common
CLINICAL MANIFESTATION • At the peak of the paroxysmal stage, patients may have more than 1 episode hourly.
CLINICAL MANIFESTATION • Convalescent stage (≥2 wk) • The number, severity, and duration of episodes diminish.
CLINICAL MANIFESTATION • Infants <3 mo of age • Do not display classical stages. • Cough (expiratory grunt) may not be prominent. • Whoop infrequently occurs in infants <3 mo • Cyanosis can follow a coughing paroxysm • Apnea may be the only symptom. • Apnea can occur without a cough
CLINICAL MANIFESTATION • Paradoxically, in infants, cough and whooping may become louder and more classic in convalescence. • Convalescence includes intermittent paroxysmal coughing throughout the 1st year of life, including "exacerbations" with subsequent respiratory illnesses; these are not due to recurrent infection or reactivation of B.pertussis.
CLINICAL MANIFESTATION • Immunized children have foreshortening of all stages of pertussis. • Signs of lower respiratory tract disease are not expected unless complicating secondary bacterial pneumonia is present. • Conjunctival hemorrhages and petechiae on the upper body are common.
DIAGNOSIS • Clinical suspect • Leukocytosis (15,000-100,000 cells/mm3) due to absolute lymphocytosis is characteristic in the catarrhal stage. • Lymphocytes are of T- and B-cell origin and are normal small cells, rather than the large atypical lymphocytes seen with viral infections.
DIAGNOSIS • Eosinophilia is not a manifestation of pertussis. • A severe course and death are correlated with extreme leukocytosis (median peak white blood cell count fatal vs nonfatal cases, 94 vs 18 x 109 cells/L) and thrombocytosis (median peak platelet count fatal vs nonfatal cases, 782 vs 556 x 109/L)
DIAGNOSIS • Mild hyperinsulinemia and reduced glycemic response to epinephrine • Hypoglycemia is reported only occasionally. • Parenchymal consolidation suggests secondary bacterial infection. • Pneumothorax, pneumomediastinum, and air in soft tissues can be seen occasionally.
DIAGNOSIS • Isolation of B. pertussis in culture remains the gold standard for diagnosis. • deep nasopharyngeal aspiration or by use of a flexible swab, preferably a dacron or calcium alginate swab, held in the posterior nasopharynx for 15-30 sec (or until coughing).
A 1.0% casamino acid liquid is acceptable for holding a specimen up to 2 hr; Stainer-Scholte broth or Regan-Lowe semisolid transport medium is used for longer periods, up to 4 days.
Direct testing of nasopharyngeal secretions by DFA is a rapid test • PCR to test nasopharyngeal wash specimens • Less than 10% of any of these test results are positive in partially or remotely immunized individuals tested in the paroxysmal stage.
DIAGNOSIS • Serologic tests in acute and convalescent samples are the most sensitive tests in immunized individuals and are useful epidemiologically. • (lgG) antibody to pertussis toxin elevated >2 standard deviations above the mean of the immunized population indicates recent infection.
DIAGNOSIS • IgA and IgM pertussis antibody tests are not reliable methods for diagnosis.
DIAGNOSIS • Adenoviral infections are usually distinguishable by associated features, such as fever, sore throat, and conjunctivitis. • Mycoplasma and B. pertussis in young adults can be difficult to distinguish on clinical grounds.
DIAGNOSIS • Chlamydia trachomatis • B. pertussis is not associated with staccato cough (breath with every cough), purulent conjunctivitis, tachypnea, rales or wheezes
TREATMEN • Goals of therapy are to limit the number of paroxysms,to observe the severity of the cough, to provide assistance when necessary • Infants <3 mo of age are admitted to hospital almost without exception • 3-6 mo unless witnessed paroxysms are not severe, and those of any age if significant complications occur.
Typical paroxysms that are not life threatening • Duration <45 sec • Red but not blue color change • Tachycardia, bradycardia (not <60 beats/min in infants) • Oxygen desaturation that spontaneously resolves at the end of the paroxysm • Whooping or strength for self-rescue at the end of paroxysm • self-expectorated mucus plug • post-tussive exhaustion but not unresponsiveness.
TREATMEN • Mist by tent can be useful in some infants with thick, tenacious secretions and excessively irritable airways. • Large volume feedings are avoided. • Portable oxygen, monitoring, or suction apparatus should not be needed at home.
Hospital discharge • If over a 48-hr period disease severity is unchanged or diminished • No intervention is required during paroxysms, • Nutrition is adequate, no complication has occurred • Parents are adequately prepared for care at home.
Antibiotics • given when pertussis is suspected or confirmed primarily to limit the spread of infection and secondarily for possible clinical benefit. • A 7- to 10-fold relative risk for infantile hypertrophic pyloric stenosis (IHPS) has been reported in neonates treated with orally administered erythromycin. • Azithromycin is the preferred agent for use in neonates.
Adjunct Therapies • Corticosteroids clinical use is not warranted. • Beneficial effect of beta2-adrenergic is not documented
Isolation • Respiratory isolation with use of masks by all health care personnel entering the room. • Children and staff with pertussis in child-care facilities or schools should be excluded until macrolide prophylaxis has been taken for 5 days.
Care of Household and Other Close Contacts. • A macrolide agent should be given promptly to all household contacts and other close contacts, such as those in daycare, regardless of age, history of immunization, or symptoms • Children <7 yr of age who received a 3rd dose >6 mo before exposure or a 4th dose ≥3 yr before exposure should receive a booster dose.
Care of Household and Other Close Contacts • Individuals ≥9 yr should be given a booster if they have not previously received Tdap and >2 yr have passed since receipt of a diphtheria containing vaccine • Coughing health care workers, with or without known exposure to pertussis, should be promptly evaluated for pertussis
COMPLICATION • Infants <6 mo of age have excessive mortality and morbidity • Infants <4 mo of age account for 90% of cases of fatal pertussis. • Preterm birth and young maternal age are significantly associated with fatal pertussis.
COMPLICATION • Progressive pulmonary hypertension or hemorrhage (especially in very young infants) and secondary bacterial pneumonia are usual causes of death. mortality rate of >80%. • otitis media • pneumonia(S. aureus, S. pneumoniae) • Seizure
COMPLICATION • Seizures are usually a result of hypoxemia, but hyponatremia from excessive secretion of antidiuretic hormone during pneumonia can occur. • infants with apnea raises the possibility of a primary effect of PT on the CNS.
COMPLICATION • Conjunctival and scleral hemorrhages petechiae on the upper body, epistaxis • Hemorrhage in the central nervous system (CNS) and retina • Pneumothorax and subcutaneous emphysema, and umbilical • Inguinal hernias.
COMPLICATION • Children ≤2 yr may have abnormal pulmonary function into adulthood. • Laceration of the lingual frenulum is not uncommon.
PREVENTION • 2, 4, and 6 mo of age. • Booster:15-18 mo, 4-6 yr • A 5th dose is not necessary if the 4th dose in the series is administered on or after the 4th birthday. • The preferred age for Tdap vaccination is 11-12 yr
Tetanus(Clostridium tetani) lockjaw • C. tetani is not a tissue-invasive organism and instead causes illness through the effects of a single toxin, tetanospasmin • The human lethal dose of tetanus toxin is estimated to be 10-5 mg/kg.
EPIDEMIOLOG • Tetanus occurs worldwide and is endemic in approximately 90 developing countries. • The most common form, neonatal (or umbilical) tetanus, kills approximately 500,000 infants each year, with about 80% of deaths in just 12 tropical Asian and African countries. • It occurs because the mother was not immunized.
maternal tetanus that results from postpartum, postabortal, or postsurgical wound infection with C.tetani. • Most non-neonatal cases of tetanus are associated with a traumatic injury, often a penetrating wound inflicted by a dirty object such as a nail, splinter, fragment of glass, or unsterile injection. • Tetanus occurring after illicit drug injection is becoming more common. (quinine)
PATHOGENESIS • Toxin is released after vegetative bacterial cell death and lysis. • Tetanus toxin binds at the neuromuscular junction and enters the motor nerve by endocytosis, after which it undergoes retrograde axonal transport to the cytoplasm of the a motoneuron.