|ICD-10||A60, B00, G051, P352|
|ICD-9||054.0, 054.1, 054.2, 054.3, 771.2|
- This is a background article. See Psychological aspects of herpes simplex,
Herpes simplex' is a viral disease caused by herpes simplex viruses that primarily infect mucosal tissues and skin. Infection of the genitals is commonly known as herpes and is predominantly caused by the type 2 strain of herpes simplex virus (HSV-2), which is usually sexually transmitted. Oral herpes, colloquially called cold sores, and sometimes mistaken for canker sores, is usually caused by the type 1 strain of herpes simplex virus (HSV-1). These viruses infect the skin to cause conditions called herpes whitlow and herpes gladiatorum, and can infect the eye to cause ocular herpes. More serious disorders are caused by these viruses when they infect the central nervous system - these include herpes encephalitis, Mollaret's meningitis, and possibly Bell's palsy. In newborn babies, infection by herpes viruses (neonatal herpes) can be very serious, resulting in brain damage or even death of the infant. Neonatal HSV is more likely in a mother that acquired a primary HSV infection shortly before giving birth, such that she lacks protective antibodies that would otherwise reduce viable virus shedding.
Although HSV-1 is classically associated with oral herpes, an increasing number of genital herpes infections are caused by this virus. HSV-1 genital herpes is more infectious during primary episodes than HSV-2, but reoccurs less frequently. Both viruses cause periods of active disease lasting 2-21 days, followed by remission when the sores disappear. Most cases of genital herpes are asymptomatic, although shedding may still occur. Over time, periods of remission generally increase in length, and the duration of lesions and viral shedding decrease, leading to reduced episodes of active disease. The frequency of recurrences is regulated by specific immunity developed against the virus. Previous HSV-1 infection tends to ameliorate the symptoms of a subsequent HSV-2 infection.
HSV-1 and HSV-2 are transmitted by direct contact with a sore or body fluid of an infected individual, and can cause painful fluid-filled blisters, containing millions of infectious virus particles. After initial infection, these viruses travel from cells in the skin to sensory nerves, where they reside as life-long, latent viruses. HSV-1 lies dormant in trigeminal ganglia that provide sensation to the lips, lower mouth and neck; HSV-2 resides in sacral ganglia that supply sensation to the genitals, perineum and upper legs. Occasionally, these viruses reactivate. When this occurs, HSV travels down the same nerves to reinfect the same area of skin infected during the primary infection. Recurrences can be triggered in some individuals by specific events, such as sunburn, ultraviolet light, wind, trauma, surgery, stress or other infections. Since viral reactivation is controlled by the immune system, in immunocompetent persons, oral and genital herpes are not typically life-threatening. Individuals with HIV and transplant patients have compromised immune systems, and can develop serious HSV infections such as keratitis or encephalitis. Similarly, immuno-incompetent newborns, infected by genital herpes at birth or shortly thereafter, are at highest risk if they acquire central nervous system HSV infection that can cause brain damage or disseminated HSV which often results in liver failure and death.
Prevalence of HSV-1 and HSV-2 infections varies throughout the world. Socioeconomic status appears to be an important factor associated with HSV-1 infection levels with developing countries, such as those in Sub-Saharan Africa, showing higher levels of HSV-1 and younger acquisition rates than industrialized countries like the United States and countries in Northern Europe. The risk of infection for HSV-1 is associated with lower income and a more crowded living environment. HSV-2 seroprevalence is also highest in Sub-Saharan Africa, affecting as more than 80% of the population in some countries. Levels of HSV-2 infections are much lower in the U.S., affecting approximately 20-30% of the adult population, but this is still high compared to other industrialized countries such as Australia (12%), the United Kingdom (4%) and Germany (14%).  Females appear to be more at risk than males, for acquiring HSV-2, and the chance of being infected increases with age, and with commencing sexual activity at a younger age.
Various treatments are available to reduce the symptoms and speed up the healing process of herpes outbreaks but there is currently no cure for herpes. Antiviral mediations, such as aciclovir and valaciclovir, taken orally, reduce viral reproduction and shedding, and some topical creams, such as Docosanol and Tromantadine prevent the virus from entering the skin. Some other drugs reduce herpetic symptoms by synergising with oral antiviral medication; Cimetidine and probenecid can reduce aciclovir clearance and aspirin can reduce inflammation associated with viral infection. Some natural remedies may have potential benefits in reducing herpes outbreaks and/or their symptoms. No vaccine is currently available to prevent or treat herpes. However, trials are currently underway to identify a suitable vaccine against HSV-2.
Several distinct disorders are caused by HSV infection of the skin or mucosa including those that affect the face and mouth (orofacial herpes), genitalia (genital herpes), or hands (herpes whitlow). More serious problems arise when the virus infects and damages the eye (herpes keratitis) or invades the central nervous system to damage the brain (herpes encephalitis). Newborn infants, with reduced capacity to fight viral infections, are also prone to serious complications following HSV infection (neonatal herpes).
Infection by HSV-1 is the most common cause of herpes that affects the face and mouth (orofacial herpes) although recent years are seeing an increase in oral HSV-2 infections. A majority of primary HSV-1 infections occur during childhood and, if the virus has come into contact with the mucosa or abraded skin, can cause acute herpetic gingivostomatitis (inflammation of the mucosa of the cheek and gums) within 5–10 days. Some other symptoms may also develop, including fever and sore throat, and painful ulcers may appear. Primary HSV infection in adolescents frequently manifests a severe pharyngitis with lesions developing on the cheek and gums. Some individuals develop difficulty in swallowing (dysphagia) and swollen lymph nodes (lymphadenopathy). Primary HSV infections in adults often presents as pharyngitis similar to that observed in glandular fever (infectious mononucleosis), but gingivostomatitis is less likely. The symptoms of primary HSV infection generally resolve within two weeks.
Once a primary infection has resolved, the HSV enters the nerves surrounding the primary lesion, migrates to the cell body of the neuron, and becomes latent. In some people, the virus reactivates to cause recurrent infection - this is more common with HSV-1 than HSV-2. Prodromal symptoms often precede a recurrence, which typically begins with reddening of the skin around the infected site, with eventual ulceration to form fluid-filled blisters that affect the lip (labial) tissue and the area between the lip and skin (vermilion border). The recurrent infection is thus often called herpes simplex labialis. Rare occasions of reinfections occur inside the mouth (intraoral HSV stomatitis) affecting the gums, alveolar ridge, hard palate, and the back of the tongue - this may be accompanied with herpes labialis. Oral herpes is spread by direct contact with an active sore in an infected person, for instance, during kissing. However virus can be transmitted through the skin in the absence of a lesion. Oral herpes and cold sores can sometimes be confused with canker sores.
Clusters of inflammed papules and vesicles on the outer surface of the genitals represent the typical symptoms of a primary HSV-1 or HSV-2 genital infection. These usually appear 4–7 days after sexual exposure to HSV for the first time, and may resemble cold sores. In males, the lesions occur on the shaft of the penis or other parts of the genital region, on the inner thigh, buttocks, or anus. In females, lesions appear on or near the pubis, labia, clitoris, vulva, buttocks or anus. Other common symptoms include pain, itching, and burning. Less frequent, yet still common, symptoms include discharge from the penis or vagina, fever, headache, muscle pain (myalgia), swollen and enlarged lymph nodes and malaise. Women often experience additional symptoms that include painful urination (dysuria) and cervicitis, while herpetic proctitis (inflammation of the anus and rectum) is common for individuals participating in anal intercourse. After 2–3 weeks, existing lesions progress into ulcers and then crust and heal, although lesions on mucosal surfaces may never form crusts. The virus is not removed from the body by immune system, but enters nerve ganglia that serve the infected dermatome where it becomes dormant.
Many HSV infected people experience a recurrence within the first year of infection, when the virus reactivates from its latent state. Development of lesions follows prodrome - which warns of a recurrence and includes tingling (paresthesia), itching, and pain where lumbosacral nerves innervate the skin - by hours to days. In some individuals, starting to take antiviral treatment when prodrome is experienced can reduce the appearance and duration of lesions. Fewer lesions are likely to develop that cause less pain and heal faster (5–10 days without antiviral treatment) than during the primary infection. Subsequent outbreaks tend to be periodic or episodic, occur on average four to five times a year when not using antiviral therapy, and may be triggered by stress, illness, fatigue, menstruation. HSV-2 is widespread, affecting an estimated 1 in 4 females and 1 in 5 males in the United States. Although certain therapies can prevent outbreaks or reduce the risk of transmission to partners, no cure is yet available.
Herpes whitlow (herpetic whitlow) is a painful infection that typically manifest itself on fingers or thumbs and occasionally on the toes, or on the nail cuticle, and is caused by HSV-1 or HSV-2. It is typically contracted by healthcare workers that come in contact with the virus; it is most commonly contracted by dental workers and medical workers exposed to oral secretions. Again, the HSV seronegative person is at highest risk of acquiring this condition. Herpes whitlow is also caused by autoinoculation of HSV into broken skin prior to an infected person having antibodies against the virus (e.g. during primary infection). It is often observed in thumb-sucking children with primary HSV-1 infection, and in adults aged 20 to 30 following contact with by HSV-2-infected genitals.
Symptoms of herpetic whitlow include swelling, reddening and tenderness of the the skin of infected finger. This may be accompanied by fever and swollen lymph nodes. Small, clear vesicles initially form that merge and becomes cloudy. Associated pain often seems large relative to the physical symptoms. The herpes whitlow lesion usually heals in two to three weeks.
Individuals that participate in contact sports such as wrestling, rugby, and soccer sometimes acquire a condition caused by HSV-1 known as herpes gladiatorum, scrumpox, wrestler’s herpes or mat herpes. Abraded skin caused by contacts sports provides an area of entry for HSV-1. Symptoms present within 2 weeks of direct skin-to-skin contact with an infected person, and include skin ulceration on the face, ears, and neck. This disorder may cause fever, headache, sore throat and swollen glands, and occasionally affects the eyes. Physical symptoms sometimes recur in the skin.
Ocular herpes is generally caused by HSV-1 and is a special case of facial herpes infection known as herpes keratitis. It begins with infection of epithelial cells on the surface of the eye and retrograde infection of nerves serving the cornea. Primary infection typically presents as swelling of the conjunctiva and eye-lids (blepharoconjunctivitis), accompanied by small white itchy lesions on the surface of the cornea, which vary from minor damage to the epithelium (superficial punctate keratitis) to formation of dendritic ulcers. Infection is unilateral, affecting one eye at a time. Additional symptoms include dull pain deep inside the eye, mild to acute dryness and sinusitis. Most primary infections resolve spontaneously in a few weeks or with the use of oral and topical antivirals. However, the virus continues to inhabit the neurons of the eye and to multiply.
Subsequent recurrences may be more severe, with infected epithelial cells showing larger dendritic ulceration and lesions forming white plaques. The epithelial layer is sloughed off as the dendritic ulcer grows and mild inflammation (iritis) may occur in the underlying stroma of iris. Sensation loss occurs in lesional areas producing generalised corneal anaesthesia with repeated recurrences. This may be accompanied by chronic dry eye, low grade intermittent conjunctivitis or chronic unexplained sinusitis. When the concentration of viral DNA reaches a critical limit, the presence of the virus can trigger a massive autoimmune response in the eye, resulting in an individual's immune system destroying the corneal stroma. This usually results in loss of vision due to opacification of the cornea and is a result of an antibody responses against the viral antigen expression in the stroma following persistent infection. This is known as immune-mediated stromal keratitis.
Treatment with corneal transplants was once ineffective (with only 14%-61% rate of survival without antiviral therapy), as reinfection of the transplant is common when the virus reactivates. However, with concurrent use of antivirals the chance of graft acceptance has improved.
Herpes simplex encephalitisEdit
- Main article: Herpesviral encephalitis
Herpes simplex encephalitis (HSE) is a very serious disorder and one of the most severe viral infections of the human central nervous system. It is estimated to affect at least 1 in 500,000 individuals per year. HSE is thought to be caused by the retrograde transmission of HSV from a peripheral site on the face to the brain along a nerve axon. Approximately 50% of individuals that develop HSE are over 50 years of age. About 1 in 3 cases of HSE result from primary HSV-1 infection predominantly occuring in individuals under the age of 18. Although 2 in 3 cases occur in seropositive persons, few of these individuals have history of recurrent orofacial herpes. It is believed these seropositive individuals develop HSE as a consequence of HSV-1 reactivation. The virus lies dormant in the ganglion of the trigeminal or fifth cranial nerve but the reason for reactivation, and its pathway to gain access to the brain, remains unclear. The olfactory nerve may also be involved in HSE.
Without treatment, HSE results in rapid death in around 70% of cases. Even with the best modern treatment, it is fatal in around 20% of cases treated, and causes serious long-term neurological damage in over half the survivors. For unknown reasons the virus seems to target the temporal lobes of the brain. Only a small population of survivors (2.5%) regain completely normal brain function. Most individuals with HSE show a decrease in their level of consciousness and an altered mental state presenting as confusion and changes in personality. Increased numbers of white blood cells can be found in their cerebrospinal fluid without the presence of pathogenic bacteria and fungi, and they typically have a fever. Approximately 2 in patients with HSE will have seizures. The electrical activity of the brain (detected using EEG, CT, or MRI scans) changes as the disease progresses, first showing abnormalities in one temporal lobe of the brain, which spread to the other temporal lobe 7–10 days later.
Neonatal herpes simplexEdit
Neonatal HSV disease is a rare but serious condition, usually the consequence of vertical transmission of the virus from mother to newborn child, although an estimated 10% of cases may be acquired postnatally from a parent, caretaker, or sibling. Approximately 22% of pregnant women have had a previous exposure HSV-2, and a further 2% or more women acquire the virus during pregnancy. Particularly among young adults, genital herpes infections are increasing caused by HSV-1. The virus is transmitted in 30-57% cases of primary infection acquisition in the mother during the third trimester of pregnancy. Infection in a mother with existing antibodies for both HSV-1 and HSV-2 has a much lower (1-3%) transmission rate. This in part is due to the presence of signifigant titer of protective maternal antibodies in the fetus from about the seventh month of pregnancy. However, shedding of HSV-1 from both primary genital infection and reactivation is associated with high transmission from mother to infant.
Herpes simplex virus infection in the newborn can be "devastating," and carries "high mortality and morbidity rates from central nervous system involvement," according to Harrison's Principles of Internal Medicine, which recommends that pregnant women with active genital herpes lesions at the time of presentation in labor be delivered by cesarean section. Women whose herpes is not active can be managed with acyclovir.From 1/3,000 to 1/20,000 of live births are infected with neonatal herpes. Mortality with untreated disease is 50-85%, and 95% of survivors have "severe neurologic sequelae." Treatment with acyclovir decreases the mortality by 50% and increases the percentage who develop normally from 10% to 50%.
HSV-1 neonatal herpes is extremely rare in developing countries because primary exposure to HSV-1 (and therefore development of HSV-1 specific antibodies) usually occurs in childhood or adolescence, precluding a genital HSV-1 infection; HSV-2 infections are much more common in these countries. In industrialized nations the adolescent HSV-1 seroprevalance has been steadily dropping for the last 5 decades as a result of better hygiene, less over-crowding, and smaller family size. The resulting increase in the number of young women entering the sexually active/child bearing years as HSV-1 seronegative, has been a harbinger of increased HSV-1 genital herpes, and as a result, HSV-1 neonatal herpes in developed nations. A recent three year study in Canada revealed neonatal HSV infecions in 5.9 per 100,000 live births. HSV-1 was the cause of 62.5% of cases and 98.7% of transmission was asymptomatic.
Neonatal herpes manifests itself in three forms: skin, eyes and mouth (SEM) herpes, disseminated (DIS) herpes, and central nervous system (CNS) herpes. SEM herpes is characterized by external lesions but no internal organ involvement, and has the best prognosis. Lesions are likely to appear on trauma sites such as the attachment site of fetal scalp electrodes, forceps or vacuum extractors that are used during delivery, in the margin of the eyes, the nasopharynx, and in areas associated with trauma or surgery (including circumcision). DIS herpes affects internal organs, especially the liver. CNS herpes is an infection of the nervous system and the brain that can lead to encephalitis. Infants with CNS herpes present with seizures, tremors, lethargy, and irritability, they feed poorly, have unstable temperatures, and their fontanelle (soft spot of the skull) may bulge. CNS herpes is associated with highest morbidity, and DIS herpes has a higher mortality rate. Untreated, SEM herpes may spread to the internal organs and cause DIS or CNS herpes resulting in higher mortality or morbidity. Death from neonatal HSV disease in the US is currently decreasing; as high as 85% of HSV infected neonates died a few decades ago whereas the current death rate is about 25%. Reduction in mortality is due to the use of antiviral treatments such as vidarabine and acyclovir. However, morbidity and mortality still remain high due to diagnosis of DIS and CNS herpes coming too late for effective antiviral adminstration; early diagnosis is difficult in 20-40% of infected neonates that have no visible lesions.
HSV-2 is the most common cause of recurrent viral meningitis called Mollaret's meningitis. This condition was first described in 1944 by French neurologist Pierre Mollaret. Recurrences usually last a few days or a few weeks, and resolve without treatment. They may recur weekly or monthly for approximately 5 years following primary infection.
A type of facial paralysis called Bell's palsy has been linked to the presence and reactivation of latent HSV-1 inside the sensory nerves of the face known as geniculate ganglia, particularly in a mouse model. This is supported by findings that show the presence of HSV-1 DNA in saliva at a higher frequency in patients with Bell's palsy relative to those without the condition. However, since HSV can also be detected in these ganglia in large numbers of individuals that have never experienced facial paralysis, and high titers of antibodies for HSV are not found in HSV-infected individuals with Bell's palsy relative to those without, this theory has been contested. Other studies, which fail to detect HSV-1 DNA in the cerebrospinal fluid of Bell's palsy sufferers, also question whether HSV-1 is the causative agent in this type of facial paralysis. The potential effect of HSV-1 in the etiology of Bell's palsy has prompted the use of antiviral medication to treat the condition. The benefits of acyclovir and valacyclovir have been studied.
Recurrences and triggersEdit
Following active infection, herpes viruses become quiescent to establish a latent infection in sensory and autonomic ganglia of the nervous system. The double-stranded DNA of the virus is incorporated into the cell physiology by infection of the cell nucleus of a nerve's cell body. HSV latency is static - no virus is produced - and is controlled by a number of viral genes including Latency Associated Transcript (LAT).
The causes of reactivation from latency are uncertain but several potential triggers have been documented. Physical or psychological stress can trigger an outbreak of herpes. Local injury to the face, lips, eyes or mouth, trauma, surgery, wind, radiotherapy, ultraviolet light or sunlight are well established triggers. Some studies suggest changes in the immune system during menstruation may play a role in HSV-1 reactivation. In addition, concurrent infections, such as viral upper respiratory tract infection or other febrile diseases, can cause outbreaks, hence the historic terms "cold sore" and "fever blister".
The frequency and severity of recurrent outbreaks may vary greatly depending upon the individual. Outbreaks may occur at the original site of the infection or in close proximity to nerve endings that reach out from the infected ganglia. In the case of a genital infection, sores can appear near the base of the spine, the buttocks, back of the thighs, or they may appear at the original site of infection. Immunocompromised indiduals may experience episodes that are longer, more frequent and more severe. The human body is able to build up an immunity to the virus over time and antiviral medication has been proven to shorten the duration and/or frequency of the outbreaks.
Transmission and preventionEdit
Herpes can be contracted through direct contact with an active lesion or body fluid of an infected person. Infected people that show no visible symptoms may still shed and transmit virus through their skin, and this asymptomatic shedding may represent the most common form of HSV-2 transmission. There are no documented cases of infection via an inanimate object (e.g. a towel, toilet seat, drinking vessels). To infect a new individual, HSV travels through tiny breaks in the skin or mucous membranes in the mouth or genital areas. Even microscopic abrasions on mucous membranes are sufficient to allow viral entry. Herpes transmission occurs between discordant partners; a person with a history of infection (HSV seropositive) can pass the virus to an HSV seronegative person. Antibodies that develop following an initial infection with that type of HSV prevents reinfection with the same herpes type - a person with a history of a cold sore caused by HSV-1 cannot contract a herpes whitlow or genital infection caused by HSV-1. In a monogamous couple, a seronegative person runs a 30% per year risk of contracting an HSV-1 infection from a seropositive partner. If an oral HSV-1 infection is contracted first, seroconversion will have occurred after 6 weeks to provide protective antibodies against a futue genital HSV-1 infection.
For genital herpes, condoms are a highly effective in limiting transmission of herpes simplex infection. However, condoms are by no means completely effective. The virus cannot get through latex, but their effectiveness is somewhat limited on a public health scale by the limited use of condoms in the community, and on an individual scale because the condom may not completely cover blisters on the penis of an infected male, or base of the penis or testicles not covered by the condom may come into contact with free virus in vaginal fluid of an infected female. In such cases, abstinence from sexual activity, or washing of the genitals after sex, is recommended. The use of condoms or dental dams also limits the transmission of herpes from the genitals of one partner to the mouth of the other (or vice versa) during oral sex. When one partner has herpes simplex infection and the other does not, the use of antiviral medication, such as valaciclovir, in conjunction with a condom, further decreases the chances of transmission to the uninfected partner. Topical microbicides contain chemicals that directly inactivate the virus and block viral entry are currently being investigated. Vaccines for HSV are currently undergoing trials. Once developed, they may be used to help with prevention or minimize initial infections as well as treatment for existing infections. 
Women are more susceptible to acquiring genital HSV-2 than men; in the US, 11% of men and 23% of women carry HSV-2. On an annual basis, without the use of antivirals or condoms, the transmission risk of HSV-2 from infected male to female is approximately 8-10%. This is believed to be due to the increased exposure of mucosal tissue to potential infection sites. Transmission risk from infected female to male is approximately 4-5% annually. Suppressive antiviral therapy reduces these risks by 50%. Antivirals also help prevent the development of symptomatic HSV in infection scenarios by about 50%, meaning the infected partner will be seropositive but symptom free. Condom use also reduces the transmission risk by 50%. Condom use is much more effective at preventing male to female transmission than vice-versa.  The effects of combining antiviral and condom use is roughly additive, thus resulting in approximately a 75% combined reduction in annual transmission risk. These figures reflect experiences with subjects having frequently-recurring genital herpes (>6 recurrences per year). Subjects with low recurrence rates and those with no clinical manifestations were excluded from these studies.
To prevent neonatal infections, seronegative women are recommended to avoid unprotected oral-genital contact during the last trimester of pregnancy. Mothers infected with HSV, are advised to avoid procedures that would cause trauma to the infant during birth (e.g. fetal scalp electrodes, forceps and vacuum extractors) and, should lesions be present, to elect caesarean section to reduce exposure of the child to infected secretions in the birth canal. The use of antiviral treatments, such as aciclovir, given from the 36th week of pregnancy prevents HSV recurrence and shedding during childbirth, thereby reducing the need for caesarean section.
HSV asymptomatic shedding occurs at some time in most individuals infected with herpes. It is believed to occur on 2.9% of days while on antiviral therapy, versus 10.8% of days without and is estimated to account for one third of the total days of viral shedding. Asymptomatic shedding is more frequent within the first 12 months of acquiring HSV-2, and concurrent infection with HIV also increases the frequency and duration of asymptomatic shedding. It can occur more than a week before or after a symptomatic recurrence in 50% of cases. There are some indications that some individuals may have much lower patterns of shedding, but evidence supporting this is not fully verified - no significant differences are seen in the frequency of asymptomatic shedding when comparing persons with 1 to 12 annual recurrences to those that have no recurrences.
Primary orofacial herpes is readily identified by clinical examination in persons without a previous history of lesions, and with reported contact with an individual with known HSV-1 infection. The appearance and distribution of sores, in these individuals, typically presents as multiple, round, and superficial oral ulcers, accompanied by acute gingivitis. Adults with non-typical presentation are more difficult to diagnose. However, prodromal symptoms that occur before the appearance of herpetic lesions helps to differentiate HSV symptoms from the similar symptoms of, for example, allergic stomatitis. Occasionally, when lesions do not appear inside the mouth, primary orofacial herpes is mistaken for a bacterial infection known as impetigo. Common mouth ulcers (aphthous ulcer), also resemble intraoral herpes, but do not present a vesicular stage.
Genital herpes is more difficult to diagnose than oral herpes since most HSV-2-infected persons have no classical signs and symptoms. To confuse diagnosis, several other conditions resemble genital herpes, including lichen planus, atopic dermatitis, or urethritis. Laboratory testing is, therefore, often used to confirm genital herpes. Laboratory tests include culture of the virus, direct fluorescent antibody (DFA) studies to detect virus, skin biopsy, polymerase chain reaction (PCR) to test for presence of viral DNA and serology assays to detect the presence of antibodies the blood that react against the virus. A Tzanck test (or smear), can also be performed although this cannot differentiate between herpes simplex or herpes zoster (the causative virus of chicken pox and shingles). Although these procedures produce highly sensitive and specific diagnoses, their high costs and time constraints limit their regular use in clinical practice.
|Seroprevalence estimates for HSV-1 and HSV-2 |
* Central African Republic
* The Gambia
* Mali 
* Morrocco 
* South Africa
* South Korea
* Thailand 
* New Zealand
|Central/South America |
* Columbia 
* Costa Rica
* Peru 
* Bulgaria 
|North America |
|# in children|
Large differences in HSV-1 seroprevalence are seen in different European countries. HSV-1 seroprevalence is high in Bulgaria (83.9%) and The Czech Republic (80.6%) and lower in Belgium (67.4%), The Netherlands (56.7%) and Finland (52.4%). The typical age at which HSV-1 infection is acquired ranges from 5–9 years in Eastern European countries like Bulgaria and the Czech Republic to over 25 years of age in Northern European countries such as Finland, The Netherlands, Germany, and England and Wales. Young adults in Northern European countries are less likely to be infected with HSV-1. However, European women are more likely to be HSV-1 seropositive than men. HSV-2 seropositivity is widely distributed in Europeans older than 12, although there are large differences percentage of the population that had been exposed to HSV-2. Bulgaria has a high (23.9%) HSV-2 seroprevalence relative to other European countries: Germany (13.9%), Finland (13.4%), Belgium (11.1%), The Netherlands (8.8%), the Czech Republic (6.0%) and England and Wales (4.2%). Women are more likely to be seropositive than men, and likely acquire the virus at an earlier age. In each country of Europe, HSV-2 seropositivity becomes more common from adolescence onwards and increases in the population with age, with a decline in the older age groups in some countries.
In healthy adults, HSV-2 infection occurs more frequently in the USA than in Europe, and appears to be increasing; in individuals over 12 years old, HSV-2 seroprevalence has increased from 16.4% in 1976 to 21.8% from in 1994 and is still rising. Thus, the current incidence of genital herpes caused by HSV-2 in the U.S. is roughly one in four or five adults, with approximately 50 million people infected with genital herpes and an estimated 0.5 million new genital herpes infections occurring each year. African Americans appear more susceptible to HSV-2, although the presence of active genital symptoms are more likely in Caucasian Americans. The largest increase in HSV-2 acquistion during the past few years is in white adolescents. People with many lifetime sexual partners and those who are sexually active from a young age are also at higher-risk for the transmission of HSV-2 in the U.S. Women are at higher risk than men for acquiring HSV-2 infection, and the chance of being infected increases with age.
African Americans and immigrants from developing countries typically have an HSV-1 seroprevalance in their adolescent population that is two or three times higher than that of Caucasian Americans, possibly reflecting differences in their socioeconomic backgrounds. Many white Americans enter sexual activity, marriage and child bearing years seronegative for HSV-1. The absence of antibodies from a prior oral HSV-1 infection leaves these individuals susceptible to primary HSV-1 genital infections. This brings with it a risk of vertical transmission to the neonate if the mother contracts a primary infection during the third trimester of pregnancy. A seronegative mother has up to a 57% chance of conveying an HSV infection to her baby during childbirth whereas a woman seropositive for both HSV-1 and HSV-2 has around a 1-3% chance of passing reactivated virus to her infant. Women that are`seropositive for only one type of HSV fall somewhere in between but are still only half as likely to transmit HSV as a seronegative mother. Genital infection caused by HSV-1, in the U.S, is now thought to be about 50% and contributes to a rate of 6 to 20 per 100,000 live births in the U.S. depending on region and demographics. 
Following a study in Ontario, up to 55% of Canadians age of 15 to 16, and 89% of individuals in their early forties are estimated have antibodies to HSV-1. Teenagers are less likely to be seropositive for HSV-2 - antibodies against this virus is only found in 0-3.8% of 15-16 year olds. However, 21% of individuals in their early forties have antibodies against HSV-2 reflecting the sexually transmitted nature of this virus. When standardising for age, HSV-2 seroprevalence in Ontario, for individuals between the ages of 15 to 44, was 9.1%. This is much lower than estimated levels of HSV-2 seroprevalence in people of a similar age range in the United States. HSV-2 seroprevalence in pregnant women, between the ages of 15-44, in British Columbia is similar, with 57% having antibodies for HSV-1 and 13% having antibodies for HSV-2.
HSV-2 in more common in some countries, such as those of Sub-Saharan Africa, than in Europe or the North America. Between 30%-80% of women, and from 10-50% of men in Sub-Saharan Africa are seropositive for HSV-2, representing the highest levels of HSV-2 infection in the world. In most African countries, HSV-2 prevalence increases with age. However, age-associated decreases in HSV-2 seroprevalence has been observed for women in Uganda and Zambia, an in men in Ethiopia, Benin and Uganda.
Genital herpes appears less common in Northern Africa compared to Sub-Saharan Africa, with only 26% of middle-aged women having antibodies for HSV-2 in Morocco. Woman are more likely to be infected with HSV-2 once they are over the age of 40. Children in Egypt are often infected with HSV from a young age - HSV-1 or HSV-2 antibodies are estimated in 54% in children under the age of 5 years and 77% in children over 10 years of age. Algerian children are also likely to acquire HSV-1 infection at a young age (under 6) and 81.25% of the population has antibodies to HSV-1 by the age of 15.
Central and South AmericaEdit
HSV-2 seroprevalency is high in Central and South America, relative to rates in Europe and North America with levels estimated between 20-60%. During the mid 1980s, HSV-2 prevalence was 33% in 25–29 years old women and 45% in those aged 40 and over in Costa Rica, and, in the early 1990s, was approximately 45% among women over 60 in Mexico. The highest HSV-2 prevalence (60%) in Central or South America has been found Colombian middle-aged women although similar HSV-2 prevalence (54%) has been observed in younger women in Haiti. HSV-2 infects about 30% in women more than 30 years old from Colombia, Costa Rica, Mexico, and Panama and steadily increases to 52% in an age-associated manner in those aged 50–59. HSV-2 antibodies were found in more than 41% of women of childbearing age in Brazil. However, no increase in seroprevalence was associated with age in women over 40 years old in this country - HSV-2 prevalence was estimated at 50% among women aged 40–49 years, 33% among women 50–59, and 42% among women over 60. Women in Brazil are more likely to acquire an HSV-2 infection if their male partners had history of anal sex and had many sexual partners in his lifetime. In Peru, HSV-2 prevalence is also high among women in their 30s but is lower in men.
Eastern and South East Asia
HSV-2 seroprevalence in developing Asian countries is comparable (10-30%) to that observed in North America and Northern Europe. HSV-1 seroprevalence in some Asian countries is low, relative to other countries worldwide, with only 51% women in Thailand and between 50-60 persons in Japan possessing antibodies against this virus. However, estimates of HSV-2 infectivity, in Thailand, is higher than observed in other Eastern Asian countries - total HSV-2 seroprevalence is approximately 37% in this country. HSV-2 seroprevalence is low in women in the Philippines (9%), although commencing activity while young is associated with an increase risk of acquiring HSV-2 infection; woman starting sexual activity by the time they reach 17 are seven times more likely to be HSV-2 seropositive that those starting sexual activity when over 21. In South Korea, incidence of HSV-2 infection in those under the age of 20 is low at only 2.7% in men and 3.0% in women. Seroprevalence levels increase in older South Koreans, however, such that the population over 20 that has antibodies against HSV-2 is 21.7% of men and 28% of women, with increasing HSV-2 prevelence becoming significant once individuals reached their 30's.
In India, 33.3% of individual are seropositive for just HSV-1 and 16.6% are seropositive for only HSV-2. Those with both HSV-1 and HSV-2 antibodies are estimated at 13.3% of the population. Indian men are more likely to be infected with HSV-2 than women, and increasing seroprevalence of this virus is associated with an increasing age.
High levels of HSV-2 (42%) and HSV-1 (97%) were found amongst pregnant women in the city of Erzurum in Eastern Anatolia Region, Turkey. In Istanbul, a city in the Marmara Region in North West Turkey, however, lower HSV-2 seroprevalence was observed; HSV-2 antibodies were found in 4.8% of sexually active adults, and HSV-1 antibodies were found in 85.3%. Only 5% of pregnant women were infected with HSV-2, and 98% were infected with HSV-1. Prevalence of these viruses was higher in sex workers of Istanbul, reaching levels of 99% and 60% for HSV-1 and HSV-2 prevalence respectively. The prevalence of HSV-2 in Jordan is 52.8% for men and 41.5% for women. HSV-1 seroprevalence is 59.8% in the population of Israel and increases with age in both genders. An estimated 9.2% of Israelian adults are infected with HSV-2. Infection of either HSV-1 or HSV-2 is higher in females; HSV-2 seroprevalence reaches 20.5% in females in their 40s. These values are similar to levels in HSV infection in Europe. Antibodies for HSV-1 or HSV-2 are also more likely to be found individuals born outside of Israel, and individuals residing in Jerusalem and Southern Israel. People from Jewish origin, living in Israel, are less likely to possess antibodies against herpes. HSV-1 causes 66.3% of genital herpes in individuals living in Tel Aviv, Israel. Genital herpes infection from HSV-2 is predicted to be low in Syria although HSV-1 levels are high. HSV-1 infections is common (95%) among healthy Syrians over the age of 30, whilst HSV-2 prevalence is low in healthy individuals (0.15%), and persons infected with other sexually transmitted diseases (9.5%). High risk groups for acquiring HSV-2, in Syria, include prostitutes and bar girls that have 34% and 20% seroprevalence respectively.
In Australia, the seroprevalence of HSV-1 is 76%, with differences associated with age, gender and Indigenous status. An estimated 12% of Australian adults are seropositive for HSV-2, with higher prevalence in women (16%) than in men (8%). Larger cities have higher HSV-2 seroprevalence (13%) than rural populations (9%) in this country. Higher prevalence is found in Indigenous Australians (18%) than non-Indigenous Australians (12%) but is lower than HSV-2 prevalence observed in the United States. As in the U.S., HSV-1 is increasingly identified as the cause of genital herpes in Australians; HSV-1 was identified in the anogenital area of only 3% of the population in 1980, but had risen to 41% in 2001. This was most common in females and persons under 25.
The number of genital herpes infections appears to be rising in New Zealand with three times more cases in 1993 compared to 1977. In this country, HSV-2 affects 60% more women than men of similar age.
Currently, there is no treatment that can eradicate any of the herpes viruses from the body. Non-prescription analgesics can reduce pain and fever during initial outbreaks. Topical anesthetic treatment (such as prilocaine, lidocaine or tetracaine) can relieve itching and pain.
Antiviral medications work by interfering with viral replication, effectively slowing the replication rate of the virus and providing a greater opportunity for the immune response to intervene. All drugs in this class depend on the activity of the viral thymidine kinase to convert the drug to a monophosphate form and subsequently interfere with viral DNA replication.
There are several prescription antiviral medications for controlling herpes simplex outbreaks, including aciclovir (Zovirax), valaciclovir (Valtrex), famciclovir (Famvir), and penciclovir. Aciclovir was the original and prototypical member of this drug class and is now available in generic brands at a greatly reduced cost. Valaciclovir and famciclovir are prodrugs of aciclovir and penciclovir respectively, with improved oral bioavailability (55% vs 20% and 75% vs 5% respectively). Some herpes antiviral treatments may cause diarrhea requiring additional the use of diarrhea medication. Aciclovir is the recommended antiviral for suppressive therapy in the last months of pregnancy to prevent transmission of herpes simplex to the neonate. The use of valaciclovir and famciclovir, while potentially improving treatment compliance and efficacy, are still undergoing safety evaluation in this context. There is evidence in mice that treatment with famciclovir, rather than aciclovir, during an initial outbreak can help lower the incidence of future outbreaks by reducing the amount of latent virus in the neural ganglia. This potential effect on latency over aciclovir drops to zero a few months post-infection.
Topical antiviral creams are available for treating recurrent labial outbreaks but their effectiveness is disputed. Penciclovir's primary advantage over aciclovir cream is that it has a far longer cellular half-life – 10 hours (HSV-1)/20 hours (HSV-2) for penciclovir versus 3 hours (HSV-1/2) for aciclovir.
Docosanol (Abreva) is available as a cream for direct application to the affected area of skin. Docosanol prevents the virus from fusing to cell membranes, thus barring the entry of the virus into the skin. Docosanol was approved for use after clinical trials by the FDA in July 2000. Marketed by Avanir Pharmaceuticals under the brand name Abreva, it was the first over-the-counter antiviral drug approved for sale in the United States and Canada. In March, 2007 it was the subject of a US nationwide class-action suit against Avanir and GlaxoSmithKline as the claim that it cut recovery times in half was found to have been misleading in a California court. Tromantadine is available as a gel that inhibits entry and spreading of the virus by altering the surface composition of skin cells and inhibiting release of viral genetic material. Zilactin is a topical analgesic barrier treatment. It forms a "shield" at the area of application that prevents a sore from increasing in size and stops spreading of the virus by breakage or oozing during the healing process. Aloe Vera is available as cream or gel which makes affected area heal faster, and may even prevent recurrences.
Cimetidine, a common component of heartburn medication, has been shown to lessen the severity of herpes zoster outbreaks in several different instances, and offered some relief from herpes simplex. This is an off-label use of the drug. It and probenecid have been shown to reduce the renal clearance of aciclovir. The study showed these compounds reduce the rate, but not the extent, at which valaciclovir is converted into aciclovir. Renal clearance of aciclovir was reduced by approximately 24% and 33% respectively. In addition, respective increases in the peak plasma concentration of acyclovir of 8% and 22% were observed. The authors concluded that these effects were "not expected to have clinical consequences regarding the safety of valaciclovir". Due to the tendency of aciclovir to precipitate in renal tubules, combining these drugs should only occur under the supervision of a physician.
Limited evidence suggests that low dose aspirin (125 mg daily) might be beneficial in patients with recurrent HSV infections. It reduces the level of prostaglandins which are essential in creating an inflammation. A small study of 21 volunteers with recurrent HSV indicated a significant reduction in duration of active HSV infections, milder symptoms, and longer symptom-free periods as compared to a control group.  A recent animal study found that aspirin inhibited thermal stress-induced ocular viral shedding of HSV-1, and a possible benefit in reducing recurrences.  Aspirin is not recommended in persons under 18 years of age with herpes simplex due to the increased risk of Reye's syndrome. Long term daily doses of aspirin have a side effect of reduced blood coagulation, facilitating bruising. A single 81 mg "daily dose" aspirin is a safer regimen given that there are no studies of the correlation between dosage and antiviral effects of aspirin.
The National Institutes of Health (NIH) in the United States is currently in the midst of phase III trials of a vaccine against HSV-2, called Herpevac. The vaccine has only been shown to be effective for women who have never been exposed to HSV-1. Overall, the vaccine is approximately 48% effective in preventing HSV-2 seropositivity and about 78% effective in preventing symptomatic HSV-2. Assuming FDA approval, a commercial version of the vaccine is estimated to become available around 2008. During initial trials, the vaccine did not exhibit any evidence in preventing HSV-2 in males. Additionally, the vaccine only reduced the acquisition of HSV-2 and symptoms due to newly acquired HSV-2 among women who did not have HSV-2 infection at the time they got the vaccine. Because about 20% of persons in the United States have HSV-2 infection, this further reduces the population for whom this vaccine might be appropriate.
|Some individuals seek benefits in natural products and dietary supplements for treatment of herpes|
Certain dietary supplements and alternative remedies are believed beneficial in the treatment of herpes when used in conjunction with conventional antiviral therapy. However, there is currently insuffient scientific and clinical evidence to support the safe or effective use of these compounds to treat herpes in humans.
Lactoferrin, a component of whey protein, has been shown to have a synergistic effect with aciclovir against HSV in vitro. Lysine supplementation has been proposed for the prophylaxis and treatment of herpes simplex when used at doses exceeding 1000 mg per day. A small randomised controlled trial, of daily 1248 mg of lysine monohydrochloride use, showed a decrease in recurrence rates in immunocompetant patients, although no effect was observed wtih 624 mg, and no evidence of decreasing the healing time was observed. Another small randomised controlled trial suggested benefit of taking 3000 mg lysine daily to reduce HSV reccurrence, severity and healing time. Lemon balm (Melissa officinalis), has antiviral activity against HSV-2 in cell culture. A cream made with lemon balm extract is a popular treatment for cold sores and genital herpes in Germany and the UK where it is known as Lomaherpan and Lomabrit respectively. In a small randomized trial, this treatment was observed to reduce HSV symptoms based on self-reporting from patients. However, this trial was supported by the drug company that makes Lomaherpan and therefore, may be subject to bias in data reporting. Carrageenans - linear sulphated polysaccharides extracted from red seaweeds - have been shown to have antiviral effects in HSV-infected cells. A carrageenan based gel prevents HSV-2 infection (at a rate of 85%) in a mouse model, potentially by binding to viral receptors that HSV uses when infecting cells. Natural carrageenans (called 1T1, 1C1, 1C3) isolated from the red alga Gigartina skottsbergii inhibit the replication activity of HSV-1 and HSV-2 in mouse models and cell culture experiments, however, there is no evidence for efficacy of this compound in humans. There are conflicting reports about the effectiveness of extracts from the plant echinacea in treating herpes infections, suggesting a possible benefit for treating oral, but not genital, herpes. Resveratrol, a compound in red wine, prevents HSV replication in vitro by inhibiting a protein needed by the virus to replicate. Resveratrol alone is not considered potent enough to be an effective treatment. A more recent study in mice showed the efficacy of topical resveratrol cream in preventing cutaneous HSV lesion formation. Some dietary supplements have been suggested to positively treat herpes. These include vitamin C, vitamin A, vitamin E, and zinc. Extracts from garlic have shown antiviral activity against HSV in cell culture experiments, although the extremely high concentrations of the extracts required to produce an antiviral effect was also toxic to the cells. Butylated hydroxytoluene (BHT), commonly available as a food preservative, has been shown in in-vitro laboratory studies to inactivate the herpes virus. In-vivo studies in animals confirmed the antiviral activity of BHT against genital herpes. However BHT has not been clinically tested and approved to treat herpes infections in humans.
Whether the law can help a person who catches herpes depends on the jurisdiction where it was contracted as legal jurisdictions define their own rules regarding the transmission of STIs such as herpes. There can be both criminal and civil possibilities. For example, in the criminal case of R. v. Sullivan heard in England and Wales, an attempt was made to prosecute Sullivan for sexual assault after his partner experienced a primary outbreak of genital herpes, on the basis that he had failed to reveal the fact that he had herpes. The presiding judge dismissed the prosecution case during preliminary hearings, citing inability to prove prior knowledge and the trial did not take place. Civil claims for transmission of herpes are, for their part, usually based on negligence if transmission was accidental and battery if deliberate. The first successful case to allow such a claim in the United States was Kathleen K. v. Robert B., decided by the California Court of Appeals.
- ↑ 1.00 1.01 1.02 1.03 1.04 1.05 1.06 1.07 1.08 1.09 1.10 1.11 1.12 1.13 Gupta R, Warren T, Wald A (2007). Genital herpes. Lancet 370 (9605): 2127–37.
- ↑ 2.0 2.1 2.2 2.3 2.4 2.5 Bruce AJ, Rogers RS (2004). Oral manifestations of sexually transmitted diseases. Clin. Dermatol. 22 (6): 520–7.
- ↑ 3.00 3.01 3.02 3.03 3.04 3.05 3.06 3.07 3.08 3.09 3.10 Fatahzadeh M, Schwartz RA (2007). Human herpes simplex virus infections: epidemiology, pathogenesis, symptomatology, diagnosis, and management. J. Am. Acad. Dermatol. 57 (5): 737–63; quiz 764–6.
- ↑ 4.0 4.1 4.2 4.3 Kimberlin DW, Whitley RJ (2005). Neonatal herpes: what have we learned. Semin Pediatr Infect Dis 16 (1): 7–16.
- ↑ 5.0 5.1 5.2 5.3 Koelle DM, Corey L (2008). Herpes Simplex: Insights on Pathogenesis and Possible Vaccines. Annu Rev Med 59: 381–395.
- ↑ Xu F, Sternberg MR, Kottiri BJ, et al (2006). Trends in herpes simplex virus type 1 and type 2 seroprevalence in the United States. JAMA 296 (8): 964–73.
- ↑ [attribution needed]
- ↑ 8.0 8.1 8.2 STD Facts - Genital Herpes. URL accessed on 2008-02-22.
- ↑ 9.0 9.1 Clark DC (2003). Common acute hand infections. Am Fam Physician 68 (11): 2167–76.
- ↑ Lewis MA (2004). Herpes simplex virus: an occupational hazard in dentistry. Int Dent J 54 (2): 103–11.
- ↑ Avitzur Y, Amir J (2002). Herpetic whitlow infection in a general pediatrician--an occupational hazard. Infection 30 (4): 234–6.
- ↑ Wu IB, Schwartz RA (2007). Herpetic whitlow. Cutis 79 (3): 193–6.
- ↑ Anonymous (1971). Herpetic whitlow: a medical risk. Br Med J 4 (5785): 444.
- ↑ Carr DJ, Härle P, Gebhardt BM (2001). The immune response to ocular herpes simplex virus type 1 infection. Exp. Biol. Med. (Maywood) 226 (5): 353–66.
- ↑ 15.0 15.1 15.2 15.3 15.4 Suresh PS, Tullo AB (1999). Herpes simplex keratitis. Indian J Ophthalmol 47 (3): 155–65.
- ↑ Halberstadt M, Machens M, Gahlenbek KA, Böhnke M, Garweg JG (2002). The outcome of corneal grafting in patients with stromal keratitis of herpetic and non-herpetic origin. Br J Ophthalmol 86 (6): 646–52.
- ↑ 17.0 17.1 17.2 17.3 17.4 Whitley RJ (2006). Herpes simplex encephalitis: adolescents and adults. Antiviral Res. 71 (2-3): 141–8.
- ↑ 18.0 18.1 Whitley RJ, Gnann JW (2002). Viral encephalitis: familiar infections and emerging pathogens. Lancet 359 (9305): 507–13.
- ↑ Dinn J (1980). Transolfactory spread of virus in herpes simplex encephalitis.. Br Med J 281 (6252): 1392. PMID 7437807.
- ↑ Brown ZA, Gardella C, Wald A, Morrow RA, Corey L (2005). Genital herpes complicating pregnancy. Obstet Gynecol 106 (4): 845–56.
- ↑ Baker DA (2007). Consequences of herpes simplex virus in pregnancy and their prevention. Curr. Opin. Infect. Dis. 20 (1): 73–6.
- ↑ 22.0 22.1 22.2 22.3 Brown ZA, Wald A, Morrow RA, Selke S, Zeh J, Corey L (2003). Effect of serologic status and cesarean delivery on transmission rates of herpes simplex virus from mother to infant. JAMA 289 (2): 203–9.
- ↑ Ch. 6, "Medical Disorders during Pregnancy," in Harrison's Principles of Internal Medicine, 16th ed., 2005
- ↑ The Merck Manual, Neonatal Herpes Simplex Virus (HSV) Infection
- ↑ Brocklehurst P, Kinghorn GA et al.. randomised placebo controlled trial of suppressive acyclovir in late pregnancy in women with recurrent genital herpes infection 105 (3): 275-80.
- ↑ Kropp RY., Wong T, et al (2006). Neonatal Herpes Simplex Virus Infections in Canada: Results of a 3-Year National Prospective Study. Pediatrics 117 (61): 1955-1962. PMID 16740836.
- ↑ Kesson AM (2001). Management of neonatal herpes simplex virus infection. Paediatr Drugs 3 (2): 81–90.
- ↑ Jacobs RF (1998). Neonatal herpes simplex virus infections. Semin. Perinatol. 22 (1): 64–71.
- ↑ Tyler KL (2004). Herpes simplex virus infections of the central nervous system: encephalitis and meningitis, including Mollaret's. Herpes 11 Suppl 2: 57A–64A.
- ↑ Sendi P, Graber P (2006). Mollaret's meningitis. CMAJ 174 (12): 1710.
- ↑ Takasu T, Furuta Y, Sato KC, Fukuda S, Inuyama Y, Nagashima K (1992). Detection of latent herpes simplex virus DNA and RNA in human geniculate ganglia by the polymerase chain reaction. Acta Otolaryngol. 112 (6): 1004–11.
- ↑ Sugita T, Murakami S, Yanagihara N, Fujiwara Y, Hirata Y, Kurata T (1995). Facial nerve paralysis induced by herpes simplex virus in mice: an animal model of acute and transient facial paralysis. Ann. Otol. Rhinol. Laryngol. 104 (7): 574–81.
- ↑ Lazarini PR, Vianna MF, Alcantara MP, Scalia RA, Caiaffa Filho HH (2006). [Herpes simplex virus in the saliva of peripheral Bell's palsy patients]. Rev Bras Otorrinolaringol (Engl Ed) 72 (1): 7–11.
- ↑ Linder T, Bossart W, Bodmer D (2005). Bell's palsy and Herpes simplex virus: fact or mystery?. Otol. Neurotol. 26 (1): 109–13.
- ↑ Kanerva M, Mannonen L, Piiparinen H, Peltomaa M, Vaheri A, Pitkäranta A (2007). Search for Herpesviruses in cerebrospinal fluid of facial palsy patients by PCR. Acta Otolaryngol. 127 (7): 775–9.
- ↑ Stjernquist-Desatnik A, Skoog E, Aurelius E (2006). Detection of herpes simplex and varicella-zoster viruses in patients with Bell's palsy by the polymerase chain reaction technique. Ann. Otol. Rhinol. Laryngol. 115 (4): 306–11.
- ↑ Tiemstra JD, Khatkhate N (2007). Bell's palsy: diagnosis and management. Am Fam Physician 76 (7): 997–1002.
- ↑ Stumpf MP, Laidlaw Z, Jansen VA (2002). Herpes viruses hedge their bets. Proc. Natl. Acad. Sci. U.S.A. 99 (23): 15234–7.
- ↑ Sainz B, Loutsch JM, Marquart ME, Hill JM (2001). Stress-associated immunomodulation and herpes simplex virus infections. Med. Hypotheses 56 (3): 348–56.
- ↑ Chambers A, Perry M (2008). Salivary mediated autoinoculation of herpes simplex virus on the face in the absence of "cold sores," after trauma. J. Oral Maxillofac. Surg. 66 (1): 136–8.
- ↑ Perna JJ, Mannix ML, Rooney JF, Notkins AL, Straus SE (1987). Reactivation of latent herpes simplex virus infection by ultraviolet light: a human model. J. Am. Acad. Dermatol. 17 (3): 473–8.
- ↑ Rooney JF, Straus SE, Mannix ML, et al (1992). UV light-induced reactivation of herpes simplex virus type 2 and prevention by acyclovir. J. Infect. Dis. 166 (3): 500–6.
- ↑ Oakley C, Epstein JB, Sherlock CH (1997). Reactivation of oral herpes simplex virus: implications for clinical management of herpes simplex virus recurrence during radiotherapy. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 84 (3): 272–8.
- ↑ Ichihashi M, Nagai H, Matsunaga K (2004). Sunlight is an important causative factor of recurrent herpes simplex. Cutis 74 (5 Suppl): 14–8.
- ↑ Myśliwska J, Trzonkowski P, Bryl E, Lukaszuk K, Myśliwski A (2000). Lower interleukin-2 and higher serum tumor necrosis factor-a levels are associated with perimenstrual, recurrent, facial Herpes simplex infection in young women. Eur. Cytokine Netw. 11 (3): 397–406.
- ↑ Segal AL, Katcher AH, Brightman VJ, Miller MF (1974). Recurrent herpes labialis, recurrent aphthous ulcers, and the menstrual cycle. J. Dent. Res. 53 (4): 797–803.
- ↑ Martinez V, Caumes E, Chosidow O (2008). Treatment to prevent recurrent genital herpes. Curr Opin Infect Dis 21 (1): 42–48.
- ↑ AHMF: Preventing Sexual Transmission of Genital Herpes. URL accessed on 2008-02-24.
- ↑ 50.0 50.1 50.2 50.3 Leone P (2005). Reducing the risk of transmitting genital herpes: advances in understanding and therapy. Curr Med Res Opin 21 (10): 1577–82.
- ↑ 51.0 51.1 Wald A, Langenberg AG, Link K, Izu AE, Ashley R, Warren T, Tyring S, Douglas JM Jr, Corey L. (2001). Effect of condoms on reducing the transmission of herpes simplex virus type 2 from men to women. JAMA 285 (24): 3100-3106. PMID 11427138.
- ↑ Casper C, Wald A. (2002). Condom use and the prevention of genital herpes acquisition.. Herpes 9 (1): 10-14. PMID 11916494.
- ↑ de Visser RO, Smith AM, Rissel CE, Richters J, Grulich AE. (2003). Sex in Australia: safer sex and condom use among a representative sample of adults. Aust. N. Z. J. Public Health. 27 (2): 223-229. PMID 14696715.
- ↑ includeonly>Seppa, Nathan. "One-Two Punch: Vaccine fights herpes with antibodies, T cells", Science News, 2005-01-05, pp. 5. Retrieved on 2007-03-29. (in English)
- ↑ includeonly>Carla K. Johnson. "Percentage of people with herpes drops", Associated Press, August 23, 2006.
- ↑ Kim H, Meier A, Huang M, Kuntz S, Selke S, Celum C, Corey L, Wald A (2006). Oral herpes simplex virus type 2 reactivation in HIV-positive and -negative men.. J Infect Dis 194 (4): 420-7. PMID 16845624.
- ↑ 57.00 57.01 57.02 57.03 57.04 57.05 57.06 57.07 57.08 57.09 57.10 57.11 Smith JS, Robinson NJ (2002). Age-specific prevalence of infection with herpes simplex virus types 2 and 1: a global review. J. Infect. Dis. 186 Suppl 1: S3–28.
- ↑ 58.0 58.1 58.2 58.3 58.4 58.5 58.6 58.7 58.8 58.9 Patnaik P, Herrero R, Morrow RA, et al (2007). Type-specific seroprevalence of herpes simplex virus type 2 and associated risk factors in middle-aged women from 6 countries: the IARC multicentric study. Sex Transm Dis 34 (12): 1019–24.
- ↑ 59.0 59.1 59.2 Shin HS, Park JJ, Chu C, et al (2007). Herpes simplex virus type 2 seroprevalence in Korea: rapid increase of HSV-2 seroprevalence in the 30s in the southern part. J. Korean Med. Sci. 22 (6): 957–62.
- ↑ 60.0 60.1 60.2 60.3 60.4 Pebody RG, Andrews N, Brown D, et al (2004). The seroepidemiology of herpes simplex virus type 1 and 2 in Europe. Sex Transm Infect 80 (3): 185–91.
- ↑ Malkin JE (2004). Epidemiology of genital herpes simplex virus infection in developed countries. Herpes 11 Suppl 1: 2A–23A.
- ↑ Herpes simplex. (HTML) University of Maryland Medical Center. URL accessed on 2007-09-03.
- ↑ LEARN ABOUT HERPES > Fast Facts. (HTML) ASHA Herpes Resource Center. URL accessed on 2007-09-03.
- ↑ STD Facts - Genital Herpes. (HTML) Centers for Disease Control and Prevention. URL accessed on 2007-09-03.
- ↑ Herpes. (HTML) Stanford University Sexual Health Peer Resource Center. URL accessed on 2007-09-03.
- ↑ Elliott E, Rose D. (2003). Australian Paediatric Surveillance Unit. Reporting of communicable disease conditions under surveillance by the APSU, 1 January to 30 September 2003. Commun. Dis. Intell. 28 (1): 90-91. PMID 15072162.
- ↑ Jones CA (2004). Vaccines to prevent neonatal herpes simplex virus infection. Expert Rev. Vaccines 3 (4): 363-364. PMID 15270635.
- ↑ Howard M, Sellors JW, Jang D, et al (2003). Regional distribution of antibodies to herpes simplex virus type 1 (HSV-1) and HSV-2 in men and women in Ontario, Canada. J. Clin. Microbiol. 41 (1): 84–9.
- ↑ 69.0 69.1 69.2 Weiss H (2004). Epidemiology of herpes simplex virus type 2 infection in the developing world. Herpes 11 Suppl 1: 24A–35A.
- ↑ Loutfy SA, Alam El-Din HM, Ibrahim MF, Hafez MM (2006). Seroprevalence of herpes simplex virus types 1 and 2, Epstein-Barr virus, and cytomegalovirus in children with acute lymphoblastic leukemia in Egypt. Saudi Med J 27 (8): 1139–45.
- ↑ Meguenni S, Djenaoui T, Bendib A, et al (1989). [Herpes simplex virus infections in Algiers]. Arch Inst Pasteur Alger 57: 61–72.
- ↑ Smith JS, Herrero R, Muñoz N, et al (2001). Prevalence and risk factors for herpes simplex virus type 2 infection among middle-age women in Brazil and the Philippines. Sex Transm Dis 28 (4): 187–94.
- ↑ Kaur R, Gupta N, Baveja UK (2005). Seroprevalence of HSV1 and HSV2 infections in family planning clinic attenders. J Commun Dis 37 (4): 307–9.
- ↑ 74.0 74.1 Dolar N, Serdaroglu S, Yilmaz G, Ergin S (2006). Seroprevalence of herpes simplex virus type 1 and type 2 in Turkey. J Eur Acad Dermatol Venereol 20 (10): 1232–6.
- ↑ Abuharfeil N, Meqdam MM (2000). Seroepidemiologic study of herpes simplex virus type 2 and cytomegalovirus among young adults in northern Jordan. New Microbiol. 23 (3): 235–9.
- ↑ 76.0 76.1 Davidovici BB, Green M, Marouni MJ, Bassal R, Pimenta JM, Cohen D (2006). Seroprevalence of herpes simplex virus 1 and 2 and correlates of infection in Israel. J. Infect. 52 (5): 367–73.
- ↑ Samra Z, Scherf E, Dan M (2003). Herpes simplex virus type 1 is the prevailing cause of genital herpes in the Tel Aviv area, Israel. Sex Transm Dis 30 (10): 794–6.
- ↑ Ibrahim AI, Kouwatli KM, Obeid MT (2000). Frequency of herpes simplex virus in Syria based on type-specific serological assay. Saudi Med J 21 (4): 355–60.
- ↑ 79.0 79.1 79.2 Cunningham AL, Taylor R, Taylor J, Marks C, Shaw J, Mindel A (2006). Prevalence of infection with herpes simplex virus types 1 and 2 in Australia: a nationwide population based survey. Sex Transm Infect 82 (2): 164–8.
- ↑ 80.0 80.1 Haddow LJ, Dave B, Mindel A, et al (2006). Increase in rates of herpes simplex virus type 1 as a cause of anogenital herpes in western Sydney, Australia, between 1979 and 2003. Sex Transm Infect 82 (3): 255–9.
- ↑ Lyttle PH (1994). Surveillance report: disease trends at New Zealand sexually transmitted disease clinics 1977-1993. Genitourin Med 70 (5): 329–35.
- ↑ (1988) Local anesthetic creams. BMJ 297 (6661): 1468.
- ↑ Kaminester LH, Pariser RJ, Pariser DM, et al (1999). A double-blind, placebo-controlled study of topical tetracaine in the treatment of herpes labialis. J. Am. Acad. Dermatol. 41 (6): 996–1001.
- ↑ Leung DT, Sacks SL. (2003). Current treatment options to prevent perinatal transmission of herpes simplex virus. Expert Opin. Pharmacother. 4 (10): 1809-1819. PMID 14521490.
- ↑ Thackray AM, Field HJ. (1996). Differential effects of famciclovir and valaciclovir on the pathogenesis of herpes simplex virus in a murine infection model including reactivation from latency. J. Infect. Dis. 173 (2): 291-299. PMID 8568288.
- ↑ Worrall G (1996). Evidence for efficacy of topical acyclovir in recurrent herpes labialis is weak. BMJ 313 (7048): 46.
- ↑ Spruance SL, Rea TL, Thoming C, Tucker R, Saltzman R, Boon R (1997). Penciclovir cream for the treatment of herpes simplex labialis. A randomized, multicenter, double-blind, placebo-controlled trial. Topical Penciclovir Collaborative Study Group. JAMA 277 (17): 1374–9.
- ↑ Drug Name: ABREVA (docosanol) - approval. centerwatch.com. URL accessed on 2007-10-17.
- ↑ California Court Upholds Settlement Of Class Action Over Cold Sore Medicationl. BNA Inc.. URL accessed on 2007-10-17.
- ↑ Vogler BK and Ernst E.. Aloe vera: a systematic review of its clinical effectiveness.. British Journal of General Practice 49: 823-828.
- ↑ Another treatment, if not very medical, is the use of vaseline, or any other type of fat. This will ban water, or saliva, from reaching the cold sore. as the cold sore "feeds" itself from water, this will end its existence in a day or two. Kapinska-Mrowiecka M, Toruwski G (1996.). Efficacy of cimetidine in treatment of herpes zoster in the first 5 days from the moment of disease manifestation.. Pol Tyg Lek. 51 (23-26): 338-339. PMID 9273526.
- ↑ Hayne ST, Mercer JB (1983). Herpes zoster:treatment with cemetidine.. Can Med Assoc J 129 (12): 1284-1285. PMID 6652595.
- ↑ Komlos L, Notmann J, Arieli J, et.al. (1994). In vitro cell-mediated immune reactions in herpes zoster patients treated with cimetidine.. Asian Pac J Allelrgy Immunol 12 (1): 51-58. PMID 7872992.
- ↑ De Bony F, Tod M, Bidault R, On NT, Posner J, Rolan P. (2002). Multiple interactions of cimetidine and probenecid with valaciclovir and its metabolite acyclovir. Antimicrob. Agents Chemother. 46 (2): 458-463. PMID 11796358.
- ↑ Karadi I, Karpati S, Romics L. (1998). Aspirin in the management of recurrent herpes simplex virus infection. Ann. Intern. Med. 128 (8): 696-697. PMID 9537952.
- ↑ Gebhardt BM, Varnell ED, Kaufman HE. (2004). Acetylsalicylic acid reduces viral shedding induced by thermal stress. Curr. Eye Res. 29 (2-3): 119-125. PMID 15512958.
- ↑ 97.0 97.1 97.2 97.3 97.4 Herpevac Trial for Women. URL accessed on 2008-02-25.
- ↑ Perfect MM, Bourne N, Ebel C, Rosenthal SL (2005). Use of complementary and alternative medicine for the treatment of genital herpes. Herpes 12 (2): 38–41.
- ↑ Andersen JH, Jenssen H, Gutteberg TJ. (2003). Lactoferrin and lactoferricin inhibit Herpes simplex 1 and 2 infection and exhibit synergy when combined with acyclovir. Antiviral Res. 58 (3): 209-215. PMID 12767468.
- ↑ McCune MA, Perry HO, Muller SA, O'Fallon WM. (2005). Treatment of recurrent herpes simplex infections with L-lysine monohydrochloride. Cutis. 34 (4): 366-373. PMID 6435961.
- ↑ Griffith RS, Walsh DE, Myrmel KH, Thompson RW, Behforooz A. (1987). Success of L-lysine therapy in frequently recurrent herpes simplex infection. Treatment and prophylaxis. Dermatologica. 175 (4): 183-190. PMID 3115841.
- ↑ Griffith RS, Norins AL, Kagan C. (1978). A multicentered study of lysine therapy in Herpes simplex infection. Dermatologica. 156 (5): 257-267. PMID 640102.
- ↑ Allahverdiyev A, Duran N, Ozguven M, Koltas S. (2004). Antiviral activity of the volatile oils of Melissa officinalis L. against Herpes simplex virus type-2.. Phytomedicine. 11 (7-8): 657-661. PMID 15636181.
- ↑ 104.0 104.1 Koytchev R, Alken RG, Dundarov S (1999). Balm mint extract (Lo-701) for topical treatment of recurring herpes labialis. Phytomedicine 6 (4): 225–30.
- ↑ Zacharopoulos VR, Phillips DM. (1997). Vaginal formulations of carrageenan protect mice from herpes simplex virus infection. Clin. Diagn. Lab. Immunol. 4 (4): 465-468. PMID 9220165.
- ↑ Carlucci MJ, Scolaro LA, Damonte EB. (1999). Inhibitory action of natural carrageenans on Herpes simplex virus infection of mouse astrocytes. Chemotherapy 45 (6): 429-436. PMID 10567773.
- ↑ Binns SE, Hudson J, Merali S, Arnason JT (2002). Antiviral activity of characterized extracts from echinacea spp. (Heliantheae: Asteraceae) against herpes simplex virus (HSV-I). Planta Med. 68 (9): 780–3.
- ↑ Vonau B, Chard S, Mandalia S, Wilkinson D, Barton SE (2001). Does the extract of the plant Echinacea purpurea influence the clinical course of recurrent genital herpes?. Int J STD AIDS 12 (3): 154–8.
- ↑ Docherty JJ, Fu MM, Stiffler BS, Limperos RJ, Pokabla CM, DeLucia AL. (1999). Resveratrol inhibition of herpes simplex virus replication. Antiviral Res. 43 (3): 145-155. PMID 10551373.
- ↑ Docherty JJ, Smith JS, Fu MM, Stoner T, Booth T. (2004). Effect of topically applied resveratrol on cutaneous herpes simplex virus infections in hairless mice. Antiviral Res. 61 (1): 19-26. PMID 14670590.
- ↑ Gaby AR (2006). Natural remedies for Herpes simplex. Altern Med Rev 11 (2): 93–101.
- ↑ Yazici AC, Baz K, Ikizoglu G (2006). Recurrent herpes labialis during isotretinoin therapy: is there a role for photosensitivity?. J Eur Acad Dermatol Venereol 20 (1): 93–5.
- ↑ Weber ND, Andersen DO, North JA, Murray BK, Lawson LD, Hughes BG (1992). In vitro virucidal effects of Allium sativum (garlic) extract and compounds. Planta Med. 58 (5): 417–23.
- ↑ Snipes W, Person S, Keith A, Cupp J. "Butylated hydroxytoluene inactivates lipid-containing viruses" Science. 1975;188(4183):64-6
- ↑ Richards JT, Katz ME, Kern ER. "Topical butylated hydroxytoluene treatment of genital herpes simplex virus infections of guinea pigs" Antiviral Res 1985;5(5):281-90
- ↑ Webpage on social aspects of genital herpes
- ↑ Error on call to template:cite web: Parameters url and title must be specified URL accessed on 2008-03-05.
- ↑ Gold-bikin, L.Z.. [?hl=en&lr=&ie=UTF-8&q=info:5smAUslPm8sJ:scholar.google.com/&output=viewport Herpes Breeds New Legal Epidemic: Fraud and Negligence Suits]. Family Advocate 7: 26.
- Genital Herpes Fact Sheet at The Centers for Disease Control and Prevention
- Paper - Genital Herpes: A Hidden Epidemic at FDA
- Links to genital herpes pictures (Hardin MD/University of Iowa
- Herpes photo library at Dermnet
- Pictures of Orofacial Herpes (Coldsores) (VisualDxHealth)
- Genital Herpes Pictures
- STI - Herpes (HSV) from Young and Healthy
- Herpes Blood Tests Quick Reference Guide
- Updated Herpes Handbook from Westover Heights Clinic
- "The Importance and Practicalities of Patient Counseling in the Prevention and Management of Genital Herpes" (2004) at Medscape
- International Herpes Management Forum
- Provides Ratios of Lysine to Arginine in Common Foods
|This page uses Creative Commons Licensed content from Wikipedia (view authors).|