Lecture 19 Microbial Cardiovascular, Lymph, Systemic Diseases PDF

Summary

This lecture covers microbial diseases of the cardiovascular, lymphatic, and systemic systems. It discusses topics such as septicemia, septic shock, lymphangitis, and other related conditions. The lecture also touches upon the signs, symptoms, causes, and treatments of these diseases.

Full Transcript

Microbial Cardiovascular,
Lymphatic and systemic
Diseases
 Septicemia and Septic Shock
Blood is normally sterile:
– a few microbes are OK, because of the presence of defensive
phagocytic cells and lack of freely available iron for growth of
microbes (iron is in RBC)

Septicemia (sepsis): toxic condition from uncontrolled bacterial
proliferation in blood due to failure of defenses and cytokines are
released Tachypnea

– symptoms: chills, fever, accelerated breathing and heart
rate euypnea = normal breathing
bradypnea = slow breathing

Severe sepsis: when sepsis results in drop in blood pressure
and dysfunction of at least one organ
– low blood pressure can still be controlled by adding fluids

Septic Shock: final stage of sepsis
– blood pressure can no longer be controlled by adding fluids
– multi-organ failure often occurs, very high mortality rate
 Lymphangitis
Lymphangitis: Infection Lymphangitis is a sign
and inflammation of the of septicemia
lymphatic vessels
As microbes travel
through lymphatic
vessels, from a site of
infection, localized
inflammation occurs.
Septicemia refers to
any microbial infection
of the blood.

Bacteremia is bacterial
septicemia
 Septicemia and Toxemia
Caused by various bacteria:
– pathogens are often opportunistic or nosocomial infections
– septicemia acquired by direct inoculation of bacteria into blood
Ex. medical procedures, drug users
– Immunocompetent individuals rarely have septicemia
Bacterial infections in these people are self-limited

Signs and symptoms:
– Fever, chills, nausea,
vomiting, diarrhea, malaise
– Petechiae can develop
– Osteomyelitis can occur when
bacteria invade the bones
 Gram-negative Gram-positive
Sepsis Sepsis
all gram negatives can cause sepsis
Gram-negative bacteria: most
Staphylococci and
common cause of sepsis
Streptococci can both cause
– more likely to produce severe
septicemia due to release of toxic shock syndrome
endotoxin (LPS) as the bacteria die G+ bacteria can enter
– LPS activates various defensive bloodstream from invasive
reactions by the body procedures
– endotoxic shock due to release of – kidney dialysis, iv devices,
LPS from G- cell wall etc.
250,000 fatal cases of septic known
shock per year in USA
– G+ cell wall components,
No effective treatment exists bacterial DNA
– early symptoms are non-specific Enterococcus sp.
therefore may not be diagnosed in
– Problem: many penicillin
time
AND vancomycin resistant
– administration of antibiotics at later
stages may aggravate symptoms Streptococcus agalactiae
Potential effects of endotoxin

hyperactive clotting
 Endocarditis
Endocardium: epithelial layer lining heart muscle & covering valves
Subacute bacterial endocarditis: Acute bacterial endocarditis:
slow development rapid progression

viridans
α-hemolytic Streptococci, S. aureus biofilm formation
Staphylococci, Enterococci bacteria migrate from focus of
infection
fever, weakness, heart murmur
normal and abnormal valves are
usually starts w/ focus of infection affected
elsewhere in body untreated: fatal within days
– tooth extraction, tonsillectomies prophylactic penicillin sometimes
abnormal heart valves ↑ risk used
congential heart problems, you are given prophylaxis before a surgery

bacteria lodge in blood clots – tonsillectomies, tooth extractions
– protected from immune system
fatal in a couple months if untreated
 Rheumatic Fever
s. pyogenes

Follows Group A Streptococcal pharyngitis
– Abs cross-react between strep Ags & host heart valves (autoimmune)
– age 4-18 most susceptible
Sore throat  short period of arthritis, fever
– subcutaneous nodules at joints may be present at this stage
Inflammation of heart in ~50% of cases
– valve damage

Glomerulonephritis: due to immune complex formation from
anti-streptococcal Abs
Reinfection w/ Streptococci can renew immune attack
– monthly prophylactic penicillin injections
Heart damage may be fatal
 Gangrene
systemic

Commonly caused by Clostridium
perfringens obligate anerobes

– Gram +, endospore-forming,
anaerobic bacillus
– 12 toxins
– generally introduced by trauma,
injection sites, surgery

Gangrene: death of soft tissue in part of the body.
– happens with ischemia (interruption in blood flow and loss of
blood supply to tissue) necrosis of affected tissue
– necrotic tissue provides nutrients for bacterial growth
– perfect conditions for growth of C. perfringens
anaerobic environment , lots of nutrients released from
dead/dying cells
 Gangrene
most people with gas gangrene get it from serious accidents

C. perfringens ferments
carbohydrates to CO2 and H2
leading to tissue swelling and
gas bubbles = Gas gangrene
Virulence factors: gas gangrene in uterine wall 
– toxins, collagenase, complication of improperly
proteinase performed abortions
Systemic illness: septicemia, – C. perfringes normal flora in
toxemia genital tract of ~5% of women
Symptoms – leads to life-threatening infection
of bloodstream
– extreme pain
treatment:
– weeping bullae; – debridement, amputation
brownish foul-
– hyperbaric chamber for
smelling discharge abdominal cavity infections
– hypotension – IV antibiotics
– massive hemolysis
 jaundice, black
urine
 Plague
Black Death, Bubonic plague
– hemorrhages cause dark areas
Yersinia pestis
– G- coccobacillus
reservoirs: rodents, prairie dogs, squirrels, cats
– transmitted by fleas
– if host dies flea seeks new host – can jump 3.5”
– can also spread by direct contact with animals
bubonic, pneumonic, septicemic, meningeal
flea bite  bacteremia  proliferate in lymph & blood
– survive and proliferate inside of phagocytic cells (T3SS, injects Yops in macrophages)
– large # of virulent organisms produced
– organisms emerge & overwhelming infection results
 Bubonic Plague

Signs & symptoms:
– fevers, chills, headache
swollen lymphs

– 24 hours: massive buboes
usually near inoculation site
– progress to multisystem
disease
sepsis, hypotension, DIC,
encephalitis, diarrhea,
pneumonia
 Plague
septicemic plague: septic shock due to bacterial proliferation in blood
– untreated: mortality rate of 50-75%
pneumonic plague: bacteria can be carried via blood to lungs
– mortality ~100% even today unless recognized w/in 12-15 hr
– death usually within 3 days
– easily spread by airborne droplets from humans or animals
treatment:
– i.v. gentamicin or streptomycin or doxycycline
– prophylactic antibiotic protection following exposure (contacts of
respiratory patients)
recovery = immunity
– vaccine available for high risk workers
wound infections / surgical wound infections

complications: secondary infection of buboes (S. aureus)
 Lyme Disease

Bacterial pathogen: Borrelia burgdorferi
– Spirochete
tick-borne disease
first diagnosed as rheumatoid arthritis
– young people
– seasonal occurrence (summer)
– not contagious among family members
– unusual rash prior to onset of symptoms
– symptom progression alleviated by penicillin
 Lyme Disease
Symptoms:
1st phase:
– “bull’s-eye” rash at bite site
erythemia chronicum migrans

– flu-like symptoms as rash disappears
2nd phase:
– cardiac: (myocarditis)irregular heartbeat  pacemaker
– neurological: facial paralysis, meningitis, encephalitis
– arthritis may develop months or years later
due to immune response against bacteria
Treatment:
progression to 2nd phase can be prevented by
antibiotics in 1st phase
various combinations of antibiotics depending on stage
and symptoms
 Epstein-Barr Virus (EBV)

Burkitt’s Lymphoma
– HHV-4
– EBV isolated from tumors
of Burkitt’s lymphoma
first link between virus &
human cancer

EBV mechanism of tumor formation not well
understood
– malarial infections may facilitate development of Burkitt’s
lymphoma by impairment of EBV-directed immune
response
– disease is rare in absence of endemic malaria
 Epstein-Barr Virus (EBV)
kissing disease

Infectious mononucleosis (“mono”)
– often acquired during childhood
– exposure during adolescence tends to be more symptomatic
– fewer people in developed countries display immunity
sore throat, fever, swollen neck lymph nodes, general
weakness
lymphoadenopathy

incubation 4-7 weeks
EBV multiplies within B cells *ATYPICAL LYMPHOCYTES = reactive T cells

usually self-limiting, infection = immunity
seldom fatal
death may be caused by splenic rupture during vigorous
activity
 Cytomegalovirus (CMV)
Human Herpesvirus 5 primary CMV infection during
CMV remains latent in leukocytes pregnancy
– infected cells have distinct ‘inclusion serious damage to fetus can result
bodies’, visible by microscopy severe mental retardation,
– the infected cells swell (cyto=cell, hearing loss
megaly=enlargement)
enlarged liver and spleen
~80% of population in North America
(hepatosplenomegaly)
carries CMV
transmission
– mild or asymptomatic disease in healthy
adults body fluids: saliva, semen, breast
– infection is normally contained by host milk
immune response kissing, sexual contact, transfused
CMV is a common opportunistic blood, transplanted tissue
pathogen Treatment:
– reactivates when host becomes antivirals such as gancyclovir in
immunocompromised immunocompromised
transplantation recipients: pneumonia
treatment may be lifelong
Majority of AIDS patients exhibit CMV
retinitis which can result in vision loss Vaccine:
under development but none
available yet
 Toxoplasmosis
can cross placenta

caused by Toxoplasma gondii (protozoan)
cat = definitive host
– large number of urban cats infected (no symptoms in cat)
– microbe lives in GI tract of cat  shed in cat feces 
contaminate food/water sources  ingested by other animals
~40% of population has Abs to T. gondii
– in healthy people – mild or no symptoms
T. gondii forms cysts in tissue
– infection can be reactivated from cysts in immunocompromised
people
– vision damage, neurological damage (cyst location)
if initial infection in acquired during pregnancy:
– congenital infection: stillbirth, brain damage, vision problems
– In Europe if acquired during pregnancy, abortion is encouraged
 Schistosomiasis
debilitating disease caused by fluke: Schistosoma sp.
specific species of snail is required for part of life cycle
spread through contaminated water
– eggs from human feces or urine
– problem in areas of poor sanitation
schisto-some = “split body”
– female lives permanently in groove in male
worms may live 20 years
– constantly produce eggs
some eggs lodge in tissues
some excreted ending up in H2O supply
different species cause damage to
different organs
depends on egg migration: liver, lungs,
urinary bladder, brain
 Schistosomiasis
adult worms avoid immune system by coating themselves
with a layer that mimics host tissues
drugs, sanitation, elimination of host snail are means of
control of this infection
clinical manifestations
– papular skin rash at penetration site (lasts 24-48 hours)
– fever, chills, headaches, cough
begins 4-8 weeks after infection; lasts 2-4 weeks
immune reaction to eggs
– chronic phase (lasts many years)
abdominal pain, diarrhea
liver failure (eggs pass through liver)
pulmonary hypertension (eggs in lungs)
urinary obstruction, renal failure
CNS symptoms (eggs in brain)
 Zoonosis Brucellosis
up and down fever (high temp and low temp)

Brucellosis (undulant fever).

 Small, Gram-ve rods;
 no capsule
 flagellated
 Aerobic
 Facultative intracellular pathogen hides inside of cells

 Survive outside the host in extreme temperature, pH
and humidity
 Potentially bio-warfare agent
 Brucellosis
major human pathogens are:
 B. melitensis (reservoir = goats & sheep);
 B. abortus (cattle);
 B. suis (pigs or swine)
 B. Canis (dogs)
goat milk and cheese

 Enter body by ingestion of contaminated milk
products, or by direct through skin in occupational
setting e.g. in abattoir.
 Pathogenesis, epidemiology,

The bacterium enters the body through breaks in
mucous membranes of the digestive and respiratory
tracts

It travels inside phagocytic cells to organs of the body
including lymph nodes, spleen, bone marrow, liver, and
heart.
Diseases:
Arthritis
Splenomegaly
Enlarged testes,
Endocarditis
Meningitis and encephalitis (rare cases)
 Treatment, prevention

Treatment
Use doxycycline and rifampin or streptomycin for
weeks

Prevention
Attenuated vaccine for animals
Pasteurization of milk
slaughtering of infected animals
No human vaccine available
 Tularemia

Bacteria: Francisella tularensis
 F. tularensis is small, pleomorphic, Gram –ve rod.
 Strict aerobe
 Single serologic type.
 Enzootic in every US state.

 Most important animal reservoirs are rabbits,
deer & rodents.

 Vectored between animals by ticks, mites & lice, especially
Dermacentor, a tick that feeds on wild rabbits.
 Pathogenesis
 Most frequent form in US
is tick-borne
tularaemia from rabbit.
 Entry usually through
skin; ulcer formed at
site of entry in most
cases.
 Bacteria then localise in
typo, should be rectoendothelial system

resulting in formation of
recticuloendothelial

granulomas.
 Abscesses & caseation
tissue breakdown into cheese-like formation

can occur.
 Symptoms

 Symptoms vary from rapid onset of influenza- like
illness to prolonged onset of mild fever &
adenopathy.
enlargement of lymph nodes
ulcers and enlargement of glands

  75% of cases are ulceroglandular; i.e. site of entry
ulcerates & local lymph nodes become swollen &
painful.

 Glandular, oculoglandular, typhoidal, gastrointestinal &
pul monary tularaemia occur but are rarer.

 Disease usually results in immunity for life.
 Treatment and prevention

 Streptomycin is the drug of choice.
 No significant resistance reported.

 Can be prevented by avoiding tick bites &
handling of wild animals..

 Experimental live, attenuated vaccine is given to
individuals whose occupation puts them at risk
– e.g., fur trappers.