key: cord-0037052-yrw6nb9u authors: Lee, Brett; Rose, Emily title: Other Potentially Life-Threatening Conditions with Mucocutaneous Findings (Leptospirosis, Typhoid Fever, Dengue, Diphtheria, Murine Typhus) date: 2018-09-12 journal: Life-Threatening Rashes DOI: 10.1007/978-3-319-75623-3_23 sha: b5597c3f62a7d5c243ca074dcdf106414dc3cb9c doc_id: 37052 cord_uid: yrw6nb9u There are several conditions with mucocutaneous findings that are potentially life-threatening, particularly in certain vulnerable populations. In this chapter, leptospirosis, typhoid fever, dengue, diphtheria, and murine typhus are reviewed. The disease time course of classic and atypical presentations is detailed to assist making the diagnosis in subtle cases. Associated symptoms are discussed as well as a comparison with disease mimics and differential diagnoses. Key diagnostic features are emphasized, and evidence-based management of each condition is detailed in this chapter. Symptoms are largely nonspecific, and patients often present with flu-like illness including fever, myalgias, and headache. However, there are several distinguishing features that herald a diagnosis of leptospirosis (see Table 23 .1). Ocular findings are quite common and may be present in up to 90% of cases. In particular, conjunctival suffusion, a dilatation of conjunctival vessels, is a common presentation in leptospirosis but rarely seen in other infectious diseases (see Fig. 23 .1). Other ocular findings may include subconjunctival hemorrhage, icterus (seen in severe disease), and hypopyon [7] . Rash is less common and may lead one to consider other diagnoses such as dengue, hantavirus, chikungunya, and others; however, other cutaneous findings such as jaundice with intense pruritus (secondary to liver and renal failure) as well as petechiae or ecchymosis from hemorrhagic complications may be present [7] . Hemorrhagic complications may also occur, secondary to coagulopathy and thrombocytopenia. Pulmonary hemorrhage is one of the most severe complications with a demonstrated fatality rate over 50%. GI bleeding, severe epistaxis, and hemolytic anemia are other hemorrhagic complications that may be present [1, 11] . Myocarditis, although rare, is another well documented complication of leptospirosis [9] . Patients may also experience a myriad of neurologic complications including aseptic meningitis (relatively common) and transverse myelitis [9] . Definitive diagnosis is made from PCR, antibody titers, or culture. However, as these diagnostic measures take time, empiric treatment should be initiated if there is a high clinical suspicion of the disease [12] . While the majority of leptospirosis cases are mild and will resolve without intervention, early antibiotic therapy may prevent disease progression (see Table 23 .4). Outpatient therapy is indicated for mild disease and consists of either doxycycline or azithromycin, with azithromycin being the preferred treatment for pregnant women and children. If rickettsial infection is a possible diagnosis, doxycycline should be given (see Chap. 16 for further discussion on rickettsial infections). Patients with evidence of complications, hemodynamic instability, or severe dehydration should be admitted for supportive care, targeted treatment of the specific complication and intravenous antibiotics [1, 13] . Inpatient treatment includes IV penicillin, ampicillin, ceftriaxone, or cefotaxime. A Jarisch-Herxheimer reaction may occur following treatment, which should be managed supportively [14] . Typhoid fever is a febrile illness common among travelers endemic to Asia, Africa, Latin America, and the Caribbean. It is caused by Salmonella enterica serotypes (Typhi and Paratyphi) and is commonly spread through urine and feces. Humans are the only reservoir and it is endemic in areas with poor sanitation [15] . Typhoid fever is a febrile illness that often develops mucocutaneous findings. Classically, typhoid fever is known for its "rose-spot" rash, which is characterized as a blanching salmon-colored maculopapular rash that appears across the trunk in groupings of 5-15 papules (Fig. 23. 3). These lesions may extend across the back and to proximal extremities as well [16] . One notable atypical finding that appears to be specific to typhoid fever is "furry tongue" (see Fig. 23 .4). There are well-documented cases of white-yellow-coated tongues following infection with a reported specificity up to 94% [17, 18] . In addition to fever and rash, patients commonly present with abdominal pain. This abdominal pain may be associated with either constipation or diarrhea which occur with similar frequency. In addition, relative bradycardia (Faget's sign/sphygmothermic dissociation) is a well-described phenomenon as are headache, sleep disturbance, cough, arthralgias, and myalgias (see Table 23 .5) [19] . • Diagnosis should be made clinically and is confirmed with serology, PCR, and culture. • Outpatient treatment includes doxycycline, azithromycin, or amoxicillin. • Inpatient regimens include IV penicillin, doxycycline, ceftriaxone, and cefotaxime. • Complications may affect nearly any organ system and include hemorrhagic complications, liver failure, myocarditis, neurologic manifestations, ARDS, and renal failure. Classically, typhoid fever presents in stages (see Fig. 23 .5). The incubation period lasts roughly 5-21 days after ingestion of the microorganism. In the first week of clinical symptoms, patients often develop fever which classically rises in a stepwise fashion and, if left untreated, may persist for weeks. In the second week of infection, the classic "rose-spot" rash appears with lesions usually lasting 3-5 days before remitting. Patients commonly complain of abdominal pain at this time and may suffer from a myriad of GI symptoms. In the third week, patients may develop complications of ongoing illness as discussed below [15] . Findings in typhoid fever are largely nonspecific, and therefore a wide differential needs to be maintained. The differential diagnosis includes malaria, tuberculosis, brucellosis, tularemia, leptospirosis, rickettsial infections, dengue fever, hepatitis, and infectious mononucleosis. Left untreated, typhoid fever can lead to a number of significant complications, which commonly present as GI complaints in the later weeks of infection (see Table 23 .6). These include small bowel ulceration, intestinal perforation, and subsequent septic shock. Other complications are also possible, including psychosis, neurologic deficits, and "typhoid encephalopathy" which can be described as altered level of consciousness or delirium. The bacteria can also seed nearly every other organ system so there may potentially be cardiac, respiratory, genitourinary, musculoskeletal, and central nervous system abnormalities. Finally, patients if untreated, may become chronic carriers causing autoinoculation and or transmission to other contacts [19] [20] [21] . The diagnosis of typhoid fever should largely be clinical with high suspicion in patients exposed to endemic areas. Diagnosis can be confirmed with cultures from blood, stool, urine, rose spots, and bone marrow; however, these diagnostic methods are imperfect. Serology is of limited utility as a positive result may indicate a prior infection rather than an ongoing one. Other developing modalities include ELISA and PCR [22] . Historically, chloramphenicol or amoxicillin were the drugs of choice for treatment of typhoid fever; however, drug resistance has become a significant problem (see Table 23 .7). Treatment should be directed by local resistance patterns and severity of illness. In severe disease with systemic signs, IV ceftriaxone or fluoroquinolones should be initiated if there is local susceptibility. Glucocorticoid therapy has been shown to reduce severity of illness and mortality in patients with severe disease based on a randomized, double-blind placebo-controlled trial out of Indonesia with a relatively low side effect profile. Therefore, if patients develop delirium, coma, shock, or DIC, glucocorticoid therapy should be considered with dexamethasone loading at 3 mg/kg IV followed by 1 mg/kg IV every 6 h for eight doses. Steroid treatment beyond this is contraindicated as it may increase relapse rate [23] [24] [25] [26] . In uncomplicated disease, oral agent therapy with ciprofloxacin 500-750 mg PO BID for 14 days should be initiated. In quinolone-resistant regions, azithromycin 1 g PO may be taken daily for 5 days [23] . Background Dengue fever, caused by several serotypes of Flaviviridae, is one of the most common etiologies of arthropod-borne viral disease in the world. While often asymptomatic and self-limited, dengue fever can vary significantly in severity and is a significant public health concern in developing nations [27] . Dengue fever classically presents with high fever, headache, abdominal pain, myalgias, and arthralgias as well as mucocutaneous findings (see Tables 23.8 and 23.9). During the febrile portion of the illness, conjunctival injection and oropharynx hyperemia are commonly present (see Fig. 23 .6). Facial flushing or erythematous mottling may occur at the beginning of fever or just before, usually resolving within 2 days after onset of symptoms ( Fig. 23 .7). Rash can occur in up to 50% of patients, occurring either early or late. The rash is typically described as maculopapular and can occur diffusely across face, throat, abdomen, and extremities. Patients may endorse pruritus as well. With defervescence, a late cutaneous eruption develops, characterized by confluent and erythematous islands, which are often pruritic in nature (Figs. 23.8 and 23.9). The rash often resolves within 2-3 days but may last up to as many as 5 days. In addition, as the disease resolves, pruritic desquamation of the palms and soles may occur. Other cutaneous manifestations occur secondarily to hemorrhagic complications, as discussed below, and include petechiae, purpura, and ecchymosis (see Fig. 23 .10) [28] . • Typhus is endemic to Mexico, Peru, Indonesia, and the Indian subcontinent. • Classic presentation includes high fevers, abdominal discomfort, and a maculopapular rash that appears in clusters across the torso. • Significant complications may occur from untreated typhoid fever particularly throughout the GI tract, but any organ may be affected. • Diagnosis is clinical and treatment initiated empirically in suspected cases, while confirmatory tests are pending. • Treatment choice should be based on severity of disease and local susceptibilities. As above, patients may experience a myriad of symptoms consistent with viral illness. Patients commonly complain of frontal headache with retro-orbital pain, myalgias, arthralgias, nausea, and vomiting. During the febrile phase of the illness, patients commonly have a relative bradycardia to the degree of fever. Less common associated symptoms include anorexia, altered taste sensation, and mild sore throat. Other symptoms may occur secondarily to complications and will be discussed below [28] . Patients may have conjunctival injection and pharyngeal erythema. Given propensity for hemorrhagic complications, patients commonly develop petechiae, purpura, and ecchymosis. Additionally, lymphadenopathy, hepatomegaly, facial plethora, or signs of overload secondarily to vascular leak may be present [28] . Dengue virus is typically transmitted by the Aedes mosquito and is typically found in densely forested areas. The viral incubation period is 3-14 days after inoculation. Dengue fever is divided into three phases: the febrile phase, the critical phase, and the convalescent phase [28] . In the febrile phase, patients experience fever that waxes and wanes, lasting from 2 to 7 days, as well as many of the symptoms above [28] . The critical phase occurs around the time of defervescence, often 3-7 days after fever onset. This phase usually lasts 24-48 h and may be complicated by systemic vascular leak syndrome. This syndrome is characterized by plasma leak, bleeding, shock, and organ dysfunction [29] . The convalescent phase, often occurring 1-2 days after defervescence, is characterized by resolution of plasma leakage and hemorrhage. A pruritic confluent erythematous rash often is present during this phase as seen above [28] . Differential diagnosis should include malaria, dengue, chikungunya, typhus, rickettsial disease, and hantavirus. See Table 23 .2 for distinguishing features of the differential diagnoses. The complications of dengue are many and involve multiple organ systems with potential organ failure. Table 23 .10 outlines many of the common complications [28] [29] [30] [31] [32] [33] . Early diagnosis of dengue fever is usually clinical and should be suspected in patients with the signs and symptoms above and exposure to endemic regions. Although neither sensitive nor specific, providers may perform a tourniquet test to a c d b Fig. 23. 10 Panel A shows a typical petechial rash in an infant with dengue. Panel B shows minor bleeding around injection sites, a very common feature in dengue. Panel C shows a hematoma in a patient with severe dengue. Panel D shows characteristic diffuse macular rash that appears after recovery from the acute illness in an adult patient with dengue (typically 3-6 days after fever onset). Note the "islands of white" of normal skin surround by an erythematous rash Simmons et al. [60] help in diagnosis (Figs. 23.11 and 23.12) . In this test, a blood pressure cuff is inflated midway between systolic and diastolic pressures and left for 5 min. A positive test is characterized by ten or more new petechiae in 1 square inch. Diagnosis may be confirmed by detection of viral components in serum or PCR, although these methods are labor intensive and costly. Serology is also available but is of lower specificity. Viral culture is also available but of limited utility given time needed for test to result [34] [35] [36] . Management is largely supportive because there is no antiviral therapy for dengue fever. Outpatient management may be appropriate in patients without systemic complications or comorbid conditions such as pregnancy, infancy, advanced age, renal failure, underlying hemolytic disease, or poor social support/access to followup care [37] . Inpatient management should be considered for any patient with comorbid conditions or for those with signs of severe infection. Signs of severe infection include abdominal pain, persistent nausea and vomiting, fluid accumulation (ascites, pleural effusion), mucosal bleeding, lethargy or altered mental status, hepatomegaly, increased hematocrit with rapid decrease in platelet count, and signs of shock or end-organ dysfunction. Aggressive IV fluid supplementation is warranted in those with signs of dehydration. Fevers, myalgias, and arthralgias can be managed with acetaminophen. NSAIDs and aspirin should be avoided, given the potential hemorrhagic complications. During the disease course, hemoglobin and platelets should be monitored. Transfusion with packed red blood cells is indicated for worsening anemia and suspected bleeding. Platelet transfusion is indicated for severe thrombocytopenia (<10,000/mm 3 ) but should not be pursued prophylactically. Vitamin K may be indicated if the prothrombin time is prolonged which may occur as a result of liver dysfunction or DIC [37] [38] [39] . Caused by the gram-positive rod Corynebacterium diphtheriae, diphtheria is a disease that can cause a myriad of symptoms, ranging from asymptomatic infection to respiratory distress. It is often associated with mucocutaneous symptoms. Diphtheria • Dengue is endemic to tropical regions and transmitted by the Aedes mosquito. • The disease presents in three phases: The febrile phase, the critical phase, and the convalescent phase. • Symptoms may vary significantly; patients commonly present with fever, headache, retro-orbital pain, GI symptoms, and rash. • The initial rash is maculopapular and may last several days. • A secondary rash may present in the convalescent phase, which is erythematous, occurs in clusters, and is often pruritic. • There are a wide range of complications that can occur from dengue fever, including vascular leak, hemorrhagic sequelae, and multi-organ dysfunction. • Diagnosis is largely clinical and confirmed with titers and PCR. • Treatment is largely supportive with IV fluids and antipyretics, particularly acetaminophen. • Aspirin and NSAIDs should be avoided due to potential hemorrhagic complications. • Transfusion and vitamin K may be required for hemorrhagic complications. was a significant cause of morbidity and mortality in the pre-vaccine era; however, since the advent of the diphtheria vaccine, the disease has largely been eliminated in developed countries but may sporadically occur [40] . Patients infected with C. diphtheria usually present in one of two fashions: respiratory diphtheria or cutaneous diphtheria. Respiratory diphtheria is often caused by toxigenic strains, whereas cutaneous diphtheria may be caused by both toxigenic and non-toxigenic strains. Respiratory diphtheria often presents with sore throat, malaise, cervical lymphadenopathy, and low-grade fever. Early in the disease course, only pharyngeal erythema may be present, which then progresses to isolated areas of gray and white exudate (see Figs. 23.13 and 23.14; Table 23 .11). Although known as the hallmark of this disease, pseudomembranes form in only one third of cases. Pseudomembranes are easily friable gray tissue adhering to underlying tissue, composed of necrotic fibrin, leukocytes, epithelial cells, and organisms. These membranes can spread anywhere along the respiratory tract; however, the majority of cases are found along tonsils and oropharynx. Extensive spreading of these membranes can lead to respiratory compromise which will be discussed below [41] . Cutaneous diphtheria is often the more benign of the two conditions as systemic toxicity is rare. Early, patients may experience a small blister or pustule, often over a site of minor skin trauma, with straw-colored fluid that ruptures early forming a punched-out ulcer. These shallow ulcers usually become chronic, poorly healing lesions (taking from 6 weeks to up to a year to heal) that become covered by gray membrane. While initially painful during the first 2 weeks, these lesions often become anesthetic and develop a hemorrhagic or purple base (see Fig. 23.15 ). In addition, this variant of the disease tends to predominately affect the impoverished and intravenous drug users. Patients with cutaneous diphtheria rarely develop the respiratory variant of the disease but commonly serve as a reservoir of infection for others [42] [43] [44] . Respiratory diphtheria often presents similar to streptococcal pharyngitis with sore throat, malaise, lymphadenopathy, and low-grade fever; however, patients may also experience cough as areas of the respiratory tract become involved. Symptoms may become significantly more severe in cases of systemic toxicity as discussed below. Symptoms are not solely limited to cutaneous and respiratory systems, however, and further manifestations will be discussed below [45, 46] . As above, findings consistent with diphtheria are posterior oropharynx erythema and pseudomembrane formation. In cases of nasal diphtheria, the clinician may find serosanguineous to purulent nasal discharge. In laryngeal diphtheria, hoarseness and cough may be present. In severe cases, the pseudomembranes may be extensive causing massive swelling of the tonsils, uvula, cervical lymph nodes, submandibular region, and neck. This presentation is colloquially known as the "bull neck" of diphtheria, and such swelling may cause stridor and respiratory distress (see Fig. 23 .16) [41] . Humans are the only known reservoir of disease, with spread primarily occurring via respiratory secretions or direct contact with mucocutaneous manifestations. Symptoms often appear 2-5 days postexposure. After symptoms begin, in untreated patients, the disease often lasts up to 2 weeks but can last up to 6 weeks. In appropriately treated patients, the infection is often cleared within 4 days [41, 47] . Differential diagnosis should include infectious mononucleosis, group A streptococcal pharyngitis, epiglottitis, viral pharyngitis, acute necrotizing ulcerative gingivitis, oral candidiasis, and viral pharyngitis. See Table 23 .12 for a summary of complications associated with diphtheria. The primary and most feared complication is severe membranous pharyngitis which can lead to thickening of the neck, narrowing of the airway, and resultant respiratory distress. Airway management is of the utmost importance in the emergent management of these patients [41] . Another well-described complication of diphtheria is myocarditis, which is more common in severe infections. Cardiac manifestations of diphtheria have been noted in up to 10 to 25 percent of patients with diphtheria, often occurring 1-2 weeks after symptom onset. Patients may experience heart blocks, arrhythmia, heart failure, and, in severe cases, circulatory collapse. These potential complications mandate cardiac monitoring in patients with potential systemic disease [41, 48] . Neurologic toxicity is another well-known complication of severe diphtheria infection. As with cardiac complications, neurologic symptoms are more common with worsening systemic illness. Manifestations of neurologic involvement often include paralysis of the soft palate and posterior pharyngeal wall. These neuropathies can progress to cranial neuropathies and peripheral neuritis ranging from mild weakness to total paralysis [49] . A diagnosis of diphtheria should first be suspected clinically in the unvaccinated or exposed population in the setting of above findings, particularly with friable pseudomembrane formation. Culture from respiratory tract or cutaneous lesions is required for definitive diagnosis; however, a presumptive diagnosis can be made in the setting of gram-positive rods on gram stain with the above findings. PCR and toxin assay are also available to help distinguish whether a toxigenic form of diphtheria is causing the patient symptoms [50] . The most important aspect of treatment of treatment in diphtheria is airway management given risk for obstruction. Patients should also be monitored for dysrhythmias and hypotension secondary to cardiac involvement with supportive management as needed [41] . In cases of early suspected or confirmed respiratory diphtheria, antitoxin should be administered. Of note, antitoxin is only effective before the toxin enters the cell. In addition, there is a 5-20% risk of hypersensitivity or serum sickness; therefore, ideally a scratch test can be performed before IV administration, and epinephrine should be readily available in cases of anaphylaxis [51] . Antibiotic therapy also plays a role in the treatment of diphtheria, with the antibiotics of choice being erythromycin or penicillin. Benefits of antibiotic therapy are threefold: killing of bacteria preventing further toxin formation, slowing spread of local infection, and reducing of transmission. Treatment with these antibiotic regimens is for 2 weeks followed by a repeat culture to ensure eradication [47, 51] . See Table 23 .13 for antibiotic treatment regimens. Murine or endemic typhus is a flea-borne infectious disease caused by Rickettsia typhi. The infection is often mild and self-limited and likely frequently remained undiagnosed as a nonspecific febrile illness with rash. As with other rickettsial disease, infection induces a widespread vasculitis [51, 52] . Murine typhus is primarily transmitted via the rat flea, particularly in the developing world and in locations with large rat populations. However, any type of flea may carry and transmit the disease. In suburban United States, cats, opossums, mice, and shrews may host infected fleas. Humans are infected via infected flea bite. Most cases of murine typhus in the United States are reported in people from California, Hawaii, and Texas [51, 52] . Murine typhus is typically a mild illness of nonspecific viral-type symptoms (see Table 23 .14). Typically, the onset of illness is abrupt with fever, headache, chills, and myalgias. A rash is present in 20-50 percent of patients. The classic rash is a fine, maculopapular rash that begins on the abdomen and spreads centripetally to the extremities (see Fig. 23.17) . Classically, the palms, soles, and face are spared. The rash is frequently faint and less apparent in dark-skinned individuals [51, 53] . Children are more likely to additionally have abdominal pain, vomiting, and diarrhea [54] . In approximately 10 percent of patients, the rash may be petechial. In contrast to the typical mild disease course, severe complications may potentially occur, particularly in patients with glucose-6-phosphate dehydrogenase deficiency (G6PD) and the elderly (see Complications below). After inoculation, there is a 7-14-day incubation period prior to symptom onset. Low-grade fever generally occurs within the first 1-2 days and resolves within 2 days. Rash onset classically occurs 5 days after onset of symptoms and usually resolves spontaneously within 4 days. Total resolution of symptoms generally occurs within 14 days (see Fig. 23 .18) [55] . There is a wide differential diagnosis to the nonspecific symptoms of murine typhus. Important diagnoses to consider include viral infections, rubella, measles (see Chap. 6), mononucleosis, and classically tropical infections such as dengue and Zika. Diagnosis typically occurs with initial clinical suspicion in a patient with fever, headache, rash, and possible exposure to infected fleas. Similar to other rickettsial infections, there is no reliable diagnostic test early in the disease course. Serologic confirmation may occur with an indirect fluorescent antibody testing which is typically only available at a health department laboratory. Other laboratory findings are nonspecific and also nondiagnostic. Thrombocytopenia occurs in approximately half of all patients with murine typhus [51, 55] . Treatment of murine typhus rapidly improves clinical symptoms and decreases complication rates; therefore, empiric treatment should be initiated in those with a high enough index of suspicion (see Table 23 .15). While tetracyclines and chloramphenicol are effective treatments, doxycycline is the antibiotic of choice for rickettsial infections (see Chap. 16) , and adults should receive 100 mg twice daily. In children, doxycycline is still the recommended agent of choice regardless of age. The recommended dosing of doxycycline in children is 4 mg/kg daily divided into two doses to be received every 12 h. Of note, fluoroquinolones and chloramphenicol may also be used but appear to be less efficacious. In addition, fluoroquinolones should not be used in children under the age of 18 years. While duration of therapy is controversial, some sources recommend treatment until 3 days after defervescence, and evidence of clinical improvement is documented. In addition, it should be noted that most individuals will recover from illness within 2 weeks without treatment [51, 52, 56] . While complications are rare, nearly any organ system may be affected by murine typhus. Notable complications include renal dysfunction, pulmonary edema, respiratory failure, aseptic meningitis, splenomegaly, and rarely septic shock and multiorgan system failure. Severe disease is more likely to occur in patients with G6PD deficiency and advanced age [52] . 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