PREVENTION OF THE SPREAD OF DIPHTHERIA INFECTION, PATHOGENESIS AND STATISTICS ON THE WORLD

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ABSTRACT

In this article you will get information about diphtheria, which currently has its place within insfection diseases.

through this article , you will receive the necessary information about what kind of infeskia diphtheria itself is , its

spread, transmission routes and Prevention.

KEYWORDS

Corynebacteriophages, diphtheriae , blood, toxin , infection, pathogenesis.

INTRODUCTION

C. diphtheriae is an aerobic, gram-positive bacillus.

Toxin production (toxigenicity) occurs only when the

bacillus is itself infected (lysogenized) by specific

viruses (corynebacteriophages) carrying the genetic

information for the toxin (tox gene). Diphtheria toxin

causes the local and systemic manifestations of

diphtheria.

C. diphtheriae has four biotypes: gravis, intermedius,

mitis, and belfanti. All biotypes can become toxigenic

and cause severe disease. All isolates of C. diphtheriae

should be tested for toxigenicity.

Pathogenesis. Susceptible persons may acquire

toxigenic diphtheria bacilli in the nasopharynx. The

organism produces a toxin that inhibits cellular protein

synthesis and is responsible for local tissue destruction

and formation of the pseudomembrane that is

characteristic of this disease. The toxin produced at the

site of the membrane is absorbed into the bloodstream

Research Article

PREVENTION OF THE SPREAD OF DIPHTHERIA INFECTION,
PATHOGENESIS AND STATISTICS ON THE WORLD

Submission Date:

October 06, 2023,

Accepted Date:

October 11, 2023,

Published Date:

October 16, 2023

Crossref doi:

https://doi.org/10.37547/ijmscr/Volume03Issue10-05

Jo’rayev Muzaffar G’ulomovich

Andijan State Medical Institute, Uzbekistan

Journal

Website:

https://theusajournals.
com/index.php/ijmscr

Copyright:

Original

content from this work
may be used under the
terms of the creative
commons

attributes

4.0 licence.

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and then distributed to the tissues of the div. The

toxin is responsible for major complications such as

myocarditis, polyneuropathies, and nephritis, and can

also cause thrombocytopenia.

Non-toxin-producing C. diphtheriae strains can cause

mild to severe exudative pharyngitis. Severe cases with

pseudomembranes caused by such strains have been

reported rarely; it is possible that these infections were

caused by toxigenic strains that were not detected

because of inadequate culture sampling. Other

manifestations of nontoxigenic C. diphtheriae

infection include cutaneous lesions, endocarditis,

bacteremia, and septic arthritis.

Clinical Features . The incubation period for diphtheria

is 2 to 5 days, with a range of 1 to 10 days. Disease can

involve almost any mucous membrane. In untreated

people, organisms can be present in discharges and

lesions 2 to 6 weeks after infection. For clinical

purposes, it is convenient to classify diphtheria by

anatomic site: respiratory (pharyngeal, tonsillar,

laryngeal, nasal) and non-respiratory (cutaneous and

other mucus membranes) disease.

Pharyngeal and Tonsillar Diphtheria

The most common sites of diphtheria infection are the

pharynx and the tonsils. Infection at these sites is

usually

associated

with

substantial

systemic

absorption of toxin. The onset of pharyngitis is gradual.

Early symptoms include malaise, sore throat, anorexia,

and low-grade fever (less than 101°F). Within 2 to 3

days, a bluish-white membrane forms and extends,

varying in size from covering a small patch on the

tonsils to covering most of the soft palate. Often by the

time a physician is contacted the membrane is greyish-

green or, if bleeding has occurred, black. There is a

minimal amount of mucosal erythema surrounding the

membrane. The membrane is firmly adherent to the

tissue, and forcible attempts to remove it cause

bleeding. Extensive membrane formation may result in

respiratory obstruction.

While some patients may recover at this point without

treatment, others may develop severe disease. The

patient may appear quite toxic, but the fever is usually

not high. Patients with severe disease may develop

marked edema of the submandibular areas and the

anterior neck along with lymphadenopathy, giving a

characteristic “bull neck” appearan

ce. If enough toxin

is absorbed, the patient can develop severe

prostration, pallor, rapid pulse, stupor, and coma.

Death can occur within 6 to 10 days.

Laryngeal Diphtheria

Laryngeal diphtheria can be either an extension of the

pharyngeal form or can involve only this site.

Symptoms include fever, hoarseness, and a barking

cough. The membrane can lead to airway obstruction,

coma, and death.

Anterior Nasal Diphtheria

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The onset of anterior nasal diphtheria looks much like

the common cold and is usually characterized by a

mucopurulent nasal discharge that may become blood-

tinged. A white membrane usually forms on the nasal

septum. The disease is usually fairly mild because of

apparent poor systemic absorption of toxin from this

location, and it can be terminated rapidly by diphtheria

antitoxin and antibiotic therapy.

Cutaneous Diphtheria

Skin infections may be manifested by a scaling rash or

by ulcers with clearly demarcated edges and an

overlying membrane, but any chronic skin lesion may

harbor C. diphtheriae along with other organisms.

Cutaneous diphtheria is quite common in the tropics

and is probably responsible for the high levels of

natural immunity found in these populations. Infection

with toxigenic strains appears to result less frequently

in systemic complications with cutaneous compared to

other forms of diphtheria. C. diphtheriae isolated from

cutaneous cases in the United States typically has been

nontoxigenic, although recently a number of imported

toxigenic cutaneous cases have been identified.

Complications

Most complications of diphtheria, including death, are

caused by effects of the toxin. The severity of the

disease and complications are generally related to the

extent of local disease. The toxin, when absorbed,

affects organs and tissues distant from the site of

invasion. The most frequent complications of

diphtheria are myocarditis and neuritis.

Myocarditis may present as abnormal cardiac rhythms

and can occur early in the course of the illness or weeks

later. Myocarditis can lead to heart failure and, if it

occurs early, it is often fatal.

Neuritis most often affects motor nerves and usually

resolves completely. Paralysis of the soft palate is most

frequent during the third week of illness. Paralysis of

eye muscles, limbs, and the diaphragm can occur after

the fifth week. Secondary pneumonia and respiratory

failure may result from diaphragmatic paralysis.

Other complications include otitis media and

respiratory insufficiency due to airway obstruction,

especially in infants.

The estimated overall case fatality ratio for diphtheria

is 5% to 10%.

Laboratory Testing

Diagnosis of respiratory diphtheria is usually made

based on clinical presentation because it is imperative

to begin presumptive therapy quickly. Non-respiratory

diphtheria, such as cutaneous diphtheria, may not be

clinically suspected and therefore diagnosis is typically

based on the laboratory finding.

Confirmatory testing for diphtheria includes culture to

identify the bacterial species and the Elek test to

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confirm diphtheria toxin production. Capacity for

diphtheria culture may be available at public health or

commercial laboratories. CDC’s Pertussis and

Diphtheria Laboratory routinely performs culture to

confirm C. diphtheriae and is currently the only

laboratory in the United States that tests for toxin

production. It is critical to take a swab of the affected

area, especially any ulcerations or pseudomembranes.

The organism can be cultured on common laboratory

media; culture on a selective medium containing

tellurite allows for distinguishing C. diphtheriae and C.

ulcerans from other Corynebacterium species that

normally inhabit the nasopharynx and skin (e.g.,

diphtheroids). However, further biochemical tests are

required to fully identify an isolate as C. diphtheriae. If

C. diphtheriae or C. ulcerans are isolated, they must be

tested for toxin production.

If antibiotic therapy was started prior to specimen

collection from a suspected diphtheria case, and

culture was negative for C. diphtheriae, two sources of

evidence can help support presumptive diagnosis:

1.

a positive polymerase chain reaction (PCR) test

for diphtheria tox gene;

2.

isolation of C. diphtheriae from cultures of

specimens from close contacts.

Medical Management

Diphtheria Antitoxin

Diphtheria antitoxin, produced in horses, has been

used for treatment of respiratory diphtheria in the

United States since the 1890s. It typically is not

administered in cases of non-respiratory diphtheria

and it is not indicated for prophylaxis of diphtheria

patient contacts. Diphtheria antitoxin is available only

from CDC, through an Investigational New Drug (IND)

protocol. Diphtheria antitoxin does not neutralize

toxin that is already fixed to tissues, but it will

neutralize circulating toxin and prevent progression of

disease.

After a provisional clinical diagnosis of respiratory

diphtheria is made, appropriate specimens should be

obtained for culture and the patient placed in isolation.

Persons with suspected diphtheria should be promptly

given diphtheria antitoxin and antibiotics in adequate

dosage, without waiting for laboratory confirmation.

Respiratory support and airway maintenance should

also be provided as needed. Consultation on the use of

and access to diphtheria antitoxin is available through

t

he duty officer at CDC’s Emergency Operations Center

at 770-488-7100.

Antibiotics

In addition to diphtheria antitoxin, patients with

respiratory diphtheria should also be treated with

antibiotics. The disease is usually no longer contagious

48 hours after antibiotics have been given. Elimination

of the organism should be documented by two

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consecutive negative cultures taken 24 hours apart,

with the first specimen collected 24 hours after

therapy is completed.

Preventive Measures

Diphtheria disease might not confer immunity.

Unvaccinated or incompletely vaccinated persons

recovering from diphtheria should begin or complete

active immunization with diphtheria toxoid during

convalescence.

Vaccination history of close contacts of diphtheria

patients should also be assessed: if vaccination history

is incomplete or unknown, the contact should receive

a dose of diphtheria toxoid-containing vaccine

immediately, and the vaccination series should be

completed according recommendations from the

Advisory Committee on Immunization Practices (ACIP).

If the contact is up-to-date according to ACIP

recommendations but the last dose was more than 5

years ago, a diphtheria toxoid-containing vaccine

should be immediately administered. In addition, close

contacts should receive a single intramuscular dose of

benzathine penicillin G or a 7- to 10-day course of oral

erythromycin. Benzathine penicillin G should be given

to contacts for whom surveillance cannot be

maintained for 7 to 10 days. Contacts should be closely

monitored and begin diphtheria antitoxin treatment at

the first signs of illness.

Secular Trends in the United States

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During the 1920s, 100,000 to 200,000 cases of

diphtheria (140 to 150 cases per 100,000 population)

and 13,000 to 15,000 deaths were reported each year.

After diphtheria toxoid-containing vaccines became

available in the 1940s, the number of cases gradually

declined to about 19,000 in 1945 (15 cases per 100,000

population). A more rapid decrease began with

implementation of a universal childhood vaccination

program which included diphtheria toxoid-containing

vaccines beginning in the late 1940s.

From 1996 through 2018, 14 cases of diphtheria were

reported in the United States, an average of less than 1

per year. One fatal case occurred in a 63-year-old male

returning to the United States from a country with

endemic diphtheria disease.

Within the United States, coverage with diphtheria

toxoid childhood vaccines (DTaP) has been

consistently high. Among children born during 2016

–

2017, 93.3% had received at least 3 doses of DTaP

vaccine by age 24 months, and 80.6% had received at

least 4 doses of DTaP vaccine by age 24 months.

Coverage with the adolescent and adult diphtheria

toxoid vaccines (Tdap or Td) is variable: Tdap coverage

among adolescents age 13 through 17 years reached

90.2% in 2019.

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