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Is acyclovir available as a generic drug?
GENERIC AVAILABLE: Yes
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Pregnancy & Lactation
Pregnancy category: B
Lactation: Drug enters breast milk; use with caution
A:Generally acceptable. Controlled studies in pregnant women show no evidence of fetal risk.
B:May be acceptable. Either animal studies show no risk but human studies not available or animal studies showed minor risks and human studies done and showed no risk.
C:Use with caution if benefits outweigh risks. Animal studies show risk and human studies not available or neither animal nor human studies done.
D:Use in LIFE-THREATENING emergencies when no safer drug available. Positive evidence of human fetal risk.
X:Do not use in pregnancy. Risks involved outweigh potential benefits. Safer alternatives exist.
NA:Information not available.
Mechanism of Action
Interferes with DNA polymerase to inhibit DNA replication via chain termination
Absorption: PO, 15-30%
Peak serum time: 1.5-2 hr (PO); 1 hr (IV)
Distributed widely (brain, kidney, lungs, liver, spleen, muscle, uterus, vagina, cerebrospinal fluid [CSF])
Protein bound: 9-33%
Vd: 0.8 L/kg (63.6 L)
Metabolized by liver (in small amounts)
Half-life: 4 hr (Neonates); 2-3 hr (children 1-12 years); 3 hr (adults)
Excretion: Urine (62-90% as unchanged drug)
Action And Clinical Pharmacology
Mechanism Of Action
ZOVIRAX® (acyclovir), a synthetic acyclic purine nucleoside analog, is a substrate with a high degree of specificity for herpes simplex and varicella-zoster specified thymidine kinase. Acyclovir is a poor substrate for host cell-specified thymidine kinase. Herpes simplex and varicella-zoster specified thymidine kinase transform acyclovir to its monophosphate which is then transformed by a number of cellular enzymes to acyclovir diphosphate and acyclovir triphosphate. Acyclovir triphosphate is both an inhibitor of, and a substrate for, herpesvirus-specified DNA polymerase. Although the cellular α-DNA polymerase in infected cells may also be inhibited by acyclovir triphosphate, this occurs only at concentrations of acyclovir triphosphate which are higher than those which inhibit the herpesvirus-specified DNA polymerase. Acyclovir is selectively converted to its active form in herpesvirus-infected cells and is thus preferentially taken up by these cells. Acyclovir has demonstrated a very much lower toxic potential in vitro for normal uninfected cells because: 1) less is taken up; 2) less is converted to the active form; and 3) cellular α-DNA polymerase has a lower sensitivity to the action of the active form of the drug. A combination of the thymidine kinase specificity, inhibition of DNA polymerase and premature termination of DNA synthesis results in inhibition of herpes virus replication. No effect on latent non-replicating virus has been demonstrated. Inhibition of the virus reduces the period of viral shedding, limits the degree of spread and level of pathology, and thereby facilitates healing. During suppression there is no evidence that acyclovir prevents neural migration of the virus. It aborts episodes of recurrent herpes due to inhibition of viral replication following reactivation.
The pharmacokinetics of acyclovir after oral administration have been evaluated in 6 clinical studies involving 110 adult patients.Absorption
In one study of 35 immunocompromised patients with herpes simplex or varicella-zoster infection given ZOVIRAX® Capsules in doses of 200 to 1,000 mg every 4 hours, 6 times daily for 5 days, the bioavailability was estimated to be 15 to 20%. In this study, steady-state plasma levels were reached by the second day of dosing. Mean steady-state peak and trough concentrations following the last 200 mg dose were 0.49 μg/mL (0.47 to 0.54 μg/mL) and 0.31 μg/mL (0.18 to 0.41 μg/mL), respectively and following the last 800 mg dose were 2.8 μg/mL (2.3 to 3.1 μg/mL) and 1.8 μg/mL (1.3 to 2.5 μg/mL). In another study, 20 immunocompetent patients with recurrent genital herpes simplex infections given ZOVIRAX® Capsules in dose of 800 mg every 6 hours, 4 times daily for 5 days, the mean steady-state peak and trough concentrations were 1.4 μg/mL (0.66 to 1.8 μg/mL) and 0.55 μg/mL (0.14 to 1.1 μg/mL).
In a multiple-dose crossover study where 23 volunteers received ZOVIRAX® as one 200 mg capsule, one 400 mg tablet and one 800 mg tablet 6 times daily, absorption decreased with increasing dose and the estimated bioavailabilities of acyclovir were 20, 15 and 10%, respectively. The decrease in bioavailability is believed to be a function of the dose and not the dosage form. It was demonstrated that acyclovir is not dose proportional over the dosing range 200 to 800 mg. In this study, steady-state peak and trough concentrations of acyclovir were 0.83 and 0.46 μg/mL, 1.21 and 0.63 μg/mL, and 1.61 and 0.83 μg/mL for the 200, 400 and 800 mg dosage regimens, respectively.
In another study in 6 volunteers, the influence of food on the absorption of acyclovir was not apparent.
A single oral dose bioavailability study in 23 normal volunteers showed that ZOVIRAX® Capsules 200 mg are bioequivalent to 200 mg acyclovir in aqueous solution. In a separate study in 20 volunteers, it was shown that ZOVIRAX® Suspension is bioequivalent to ZOVIRAX® Capsules. In a different single-dose bioavailability/ bioequivalence study in 24 volunteers, one ZOVIRAX® 800 mg Tablet was demonstrated to be bioequivalent to four ZOVIRAX® 200 mg Capsules.Distribution
Plasma protein binding is relatively low (9 to 33%) and drug interactions involving binding site displacement are not anticipated.Elimination
Following oral administration, the mean plasma half-life of acyclovir in volunteers and patients with normal renal function ranged from 2.5 to 3.3 hours. The mean renal excretion of unchanged drug accounts for 14.4% (8.6 to 19.8%) of the orally administered dose. The only urinary metabolite (identified by high performance liquid chromatography) is 9-[(carboxymethoxy)methyl]guanine.
Special Populations And ConditionsPediatrics
In general, the pharmacokinetics of acyclovir in children is similar to adults. Mean half-life after oral doses of 300 and 600 mg/m², in children aged 7 months to 7 years, was 2.6 hours (range 1.59 to 3.74 hours).
Orally administered acyclovir in children less than 2 years of age has not yet been fully studied.Geriatrics
In the elderly, total body clearance falls with increasing age, associated with decreases in creatinine clearance, although there is little change in the terminal plasma half-life. Dosage reduction may be required in geriatric patients with reduced renal function (see DOSAGE AND ADMINISTRATION).Renal Insufficiency
The half-life and total body clearance of acyclovir are dependent on renal function.
A dosage adjustment is recommended for patients with reduced renal function (see DOSAGE AND ADMINISTRATION).
Clinical TrialsInitial Genital Herpes
Double blind, placebo controlled studies have demonstrated that orally administered ZOVIRAX® significantly reduced the duration of acute infection and duration of lesion healing. The duration of pain and new lesion formation was decreased in some patient groups.Recurrent Genital Herpes
In a study of patients who received ZOVIRAX® 400 mg twice daily for 3 years, 45, 52, and 63% of patients remained free of recurrences in the first, second, and third years, respectively. Serial analyses of the 3 month recurrence rates for the patients showed that 71 to 87% were recurrence free in each quarter.Herpes Zoster Infections
In a double blind, placebo controlled study of immunocompetent patients with localized cutaneous zoster infection, ZOVIRAX® (800 mg 5 times daily for 10 days) shortened the times to lesion scabbing, healing, and complete cessation of pain, and reduced the duration of viral shedding and the duration of new lesion formation.
In a similar double blind, placebo controlled study, ZOVIRAX® (800 mg 5 times daily for 7 days) shortened the times to complete lesion scabbing, healing, and cessation of pain, and reduced the duration of new lesion formation.
Treatment was begun within 72 hours of rash onset and was most effective if started within the first 48 hours. Adults greater than 50 years of age showed greater benefit.Chickenpox
Three randomized, double-blind, placebo-controlled trials were conducted in 993 pediatric patients aged 2 to 18 years with chickenpox. All patients were treated within 24 hours after the onset of rash. In two trials, ZOVIRAX® was administered at 20 mg/kg four times daily (up to 3,200 mg per day) for 5 days. In the third trial, doses of 10, 15, or 20 mg/kg were administered four times daily for 5 to 7 days. Treatment with ZOVIRAX® shortened the time to 50% healing, reduced the maximum number of lesions, reduced the median number of vesicles, decreased the median number of residual lesions on day 28, and decreased the proportion of patients with fever, anorexia, and lethargy by day 2. Treatment with ZOVIRAX® did not affect varicella zoster virus specific humoral or cellular immune responses at 1 month or 1 year following treatment.
See Action And Clinical Pharmacology.Virology
The quantitative relationship between the in vitro susceptibility of herpes simplex virus (HSV) and varicella-zoster viruses (VZV) to acyclovir and the clinical response to therapy has not been established in man, and virus sensitivity testing has not been standardized. Sensitivity testing results, expressed as the concentration of drug required to inhibit by 50% the growth of virus in cell culture (ID50), vary greatly depending upon the particular assay used, the cell type employed, and the laboratory performing the test. The ID50 of acyclovir against HSV-1 isolates may range from 0.02 μg/mL (plaque reduction in Vero cells) to 5.9-13.5 μg/mL (plaque reduction in green monkey kidney [GMK] cells). The ID50 against HSV-2 ranges from 0.01 to 9.9 μg/mL (plaque reduction in Vero and GMK cells, respectively).
Using a dye-uptake method in Vero cells, which gives ID50 values approximately 5 to 10-fold higher than plaque reduction assays, 1,417 HSV isolates (553 HSV-1 and 864 HSV-2) from approximately 500 patients were examined over a 5-year period. These assays found that 90% of HSV-1 isolates were sensitive to ≤ 0.9 μg/mL acyclovir and 50% of all isolates were sensitive to ≤ 0.2 μg/mL acyclovir. For HSV-2 isolates, 90% were sensitive to ≤ 2.2 μg/mL and 50% of all isolates were sensitive to ≤ 0.7 μg/mL of acyclovir. Isolates with significantly diminished sensitivity were found in 44 patients. It must be emphasized that neither the patients nor the isolates were randomly selected and, therefore, do not represent the general population. Most of the less sensitive HSV clinical isolates have been relatively deficient in the viral thymidine kinase (TK). Strains with alterations in viral TK or viral DNA polymerase have also been reported.
The ID50 against VZV ranges from 0.17-1.53 μg/mL (yield reduction, human foreskin fibroblasts) to 1.85-3.98 μg/mL (foci reduction, human embryo fibroblasts [HEF]). Reproduction of EBV genome is suppressed by 50% in superinfected Raji cells or P3HR-1 lymphoblastoid cells by 1.5 μg/mL acyclovir. Cytomegalovirus (CMV) is relatively resistant to acyclovir with ID50 values ranging from 2.3-17.6 μg/mL (plaque reduction, HEF cells) to 1.82-56.8 μg/mL (DNA hybridization, HEF cells). The latent state of the genome of any of the human herpesviruses is not known to be sensitive to acyclovir.Resistance
Prolonged exposure of HSV to subinhibitory concentrations (0.1 μg/mL) of acyclovir in cell culture has resulted in the emergence of a variety of acyclovir-resistant strains. The emergence of resistant strains is believed to occur by “selection” of naturally occurring viruses with relatively low susceptibility to acyclovir. Such strains have been reported in pre-therapy isolates from several clinical studies.
Two resistance mechanisms involving viral thymidine kinase (required for acyclovir activation) have been described. These are: (a) selection of thymidine-kinase-deficient mutants that induce little or no enzyme activity after infection, and (b) selection of mutants possessing a thymidine kinase of altered substrate specificity that is able to phosphorylate the natural nucleoside thymidine but not acyclovir. The majority of less susceptible viruses arising in vitro are of the thymidine-kinase-deficient type which have reduced infectivity and pathogenicity and less likelihood of inducing latency in animals.
However, an acyclovir-resistant HSV infection in an immunosuppressed bone marrow transplant recipient on extended acyclovir therapy was found to be due to a clinical isolate which had a normal thymidine kinase but an altered DNA polymerase. This third mechanism of resistance involving herpes simplex virus DNA polymerase is due to the selection of mutants encoding an altered enzyme, which is resistant to inactivation by acyclovir triphosphate.
VZV appears to manifest resistance to acyclovir via mechanisms similar to those seen in HSV.
However, limited clinical investigation has revealed no evidence of a significant change in in vitro susceptibility of VZV with acyclovir therapy, although resistant mutants of this virus can be isolated in vitro in a manner analogous to HSV. Analysis of a small number of clinical isolates from patients who received oral acyclovir or placebo for acute herpes zoster suggests that in vivo emergence of resistant VZV may occur infrequently. Prolonged acyclovir treatment of highly immunocompromised patients with acquired immunodeficiency syndrome and severe VZV may lead to the appearance of resistant virus.
Cross-resistance to other antivirals occurs in vitro in acyclovir-resistant mutants. HSV mutants which are resistant to acyclovir due to an absence of viral thymidine kinase are cross-resistant to other agents which are phosphorylated by herpesvirus thymidine kinase, such as bromovinyldeoxyuridine, ganciclovir and the 2'-fluoropyrimidine nucleosides, such as, 2'-fluoro-5-iodoarabinosyl-cytosine (FIAC).
The clinical response to acyclovir treatment has usually been good for patients with normal immunity from whom HSV having reduced susceptibility to acyclovir has been recovered, either before, during or after therapy. However, certain patient groups, such as the severely immunocompromised (especially bone marrow transplant recipients) and those undergoing chronic suppressive regimens have been identified as being most frequently associated with the emergence of resistant herpes simplex strains, which may or may not accompany a poor response to the drug. The possibility of the appearance of less sensitive viruses must be recognized when treating such patients, and susceptibility monitoring of clinical isolates from these patients should be encouraged.
In summary, the quantitative relationship between the in vitro susceptibility of HSV and VZV to acyclovir and the clinical response to therapy has not been clearly established in man. Standardized methods of virus sensitivity testing are required to allow more precise correlations between in vitro virus sensitivity and clinical response to acyclovir therapy.
ToxicologyAcute Toxicity Studies
Adult Mice and Rats: The acute toxicity of oral acyclovir was determined as shown in Table 6.
Table 6 : Acute Toxicity Studies
|Species||Sex||Route||LD50 (mg/kg)||95% Conf. Level||Signs|
|Mouse||M||Oral||> 10 000||-||None|
|Rat||M||Oral||> 20 000||-||None|
Groups of 10 male and 10 female Charles River CD (Sprague-Dawley) rats were given single large doses (5 different dose levels) of a solution (pH 11.0) of acyclovir by subcutaneous injection when they were 3, 10, 28 and 71 days of age. They were observed for 14 days after treatment and LD50 values were calculated by the Litchfield and Wilcoxon method (see Table 7 below). This study was done to determine if age at exposure affects the acute toxicity of acyclovir; there was no evidence that young rats were more sensitive than older rats to the acute toxic effects of acyclovir.
Table 7 :LD50 in Rats
|Age When Treated||LD50 (mg/kg body weight)|
|71 Days||650||1 477|
There was no apparent relationship between length of survival after treatment and age at which treatment was given. Clinical signs for the rats treated at 3 and 10 days of age included red and purple cutaneous blisters, blue areas, scabs, scars, necrotic and sloughed skin, open wounds, body tremors and alopecia. Decreased activity, lacrimation, closed eyelids, red-brown or brown material around the eyes, nose and mouth, ataxia, prostration, body tremors, urine stains around the abdomen or genital area, scabbed or necrotic areas and alopecia were observed in rats treated at 28 and 71 days of age.
Subchronic Oral Toxicity StudyMice
Four groups each consisting of 28 male and 28 female Charles River CD-1 (ICR) mice were orally dosed by stomach tube for 33 days with suspensions of acyclovir. Daily dose levels were 0, 50, 150 and 450 mg/kg. Hematology and clinical chemistry measurements were made on an additional 8 male and 8 female mice per group (dosed in the same manner) after the first and fourth weeks of dosing and during the 3rd postdose week.
Plasma drug concentrations were measured in pooled samples from an additional 4 male and 4 female mice per group on dose days 1, 15 and 30.
Based on preliminary experiments with rats and mice, the high dose of 450 mg/kg was selected to produce the highest drug plasma levels attainable, in a practical manner, by oral dosing in a rodent species. Averaged drug plasma concentrations ranged from approximately 3.4 (at the low dose) to 11.0 (at the high dose) μg/mL of plasma one hour after oral dosing.
No changes in health, growth rate, hematology and clinical chemistry measurements occurred that could be definitely attributed to dosing with acyclovir. Gross and histopathologic examinations of 16 male and 16 female rats from the high-dose and control groups at the end of the dose period revealed nothing remarkable.
Chronic Toxicity StudiesLifetime Oral Toxicity Study in Rats Given Acyclovir by Gastric Intubation
Charles River CD (Sprague-Dawley) rats were given suspensions of acyclovir by gavage. There were 50 male and 50 female rats at each of the following dose levels: 0, 50, 150 and 450 mg/kg. After 30 and 52 weeks of treatment, 10 male and 10 female rats from each group were necropsied. The remaining rats were dosed each day until natural mortality decreased a group size to approximately 20% of the number of animals of that sex present in the test groups when the study was started. All remaining rats were killed and necropsied when the 20% cut-off point was reached. This was during week 110 for the male rats and week 122 for the female rats. Tissues from control rats and those in the high-dose group were evaluated by light microscopy. Tissues from rats in the low and mid-dose groups having masses, nodules or unusual lesions were also examined by light microscopy. Fixed tissues from rats that were found dead during the first 52 weeks of the study were also evaluated by light microscopy.
No signs of toxicosis were observed. Plasma samples were collected 1.5 hours after dosing on days 7, 90, 209, 369, 771 (males only) and 852 (females only). Mean plasma levels found in high-dose males (450 mg/kg/day) at the times indicated above were as follows: 1.54, 1.63, 1.39, 1.60 and 1.70 μg/mL (6.84, 7.26, 6.17, 7.10 and 7.56 μM). Corresponding mean plasma levels for the high-dose females for the corresponding time periods were 1.76, 2.38, 2.12, 1.71 and 1.81 μg/mL (7.82, 10.58, 9.44, 7.62 and 8.03 μM). Plasma levels in both males and females at all dose levels after one year of treatment were generally comparable to plasma levels obtained at earlier samplings. Values for laboratory tests including hematology, clinical chemistry and ophthalmoscopy were all within the normal range. There were no drug-induced gross or microscopic lesions and there was no evidence that acyclovir affected survival.Lifetime Oral Carcinogenicity Study in Rats
There were no signs of toxicosis in Charles River CD (Sprague-Dawley) rats (100 rats/sex/dose group) given acyclovir by oral gavage at 50, 150 and 450 mg/kg in a lifetime oral carcinogenicity study. Mean plasma levels obtained in high-dose males 1.5 hours after dosing at various sampling times during the study were as follows: 1.54, 1.63, 1.39, 1.60 and 1.70 μg/mL (6.84, 7.26, 6.17, 7.10 and 7.56 μM) at days 7, 90, 209, 369 and 771, respectively. Corresponding mean values for the high-dose females were 1.76, 2.38, 2.12, 1.71 and 1.81 μg/mL (7.82, 10.58, 9.44, 7.62 and 8.03 μM) at days 7, 90, 209, 369 and 852, respectively.
Values for clinical laboratory tests including hematology, clinical chemistry, urinalysis, body weight, food consumption and ophthalmoscopy were all within normal ranges. There were no drug-induced gross or microscopic lesions and there was no evidence that acyclovir affected survival, temporal patterns of tumor incidence or tumor counts for benign or malignant neoplasms.
Most of the relatively few rats found dead or moribund during the first 52 weeks of this study suffered dosing accidents as evidenced by postmortem findings of esophageal perforation causing pleural effusion, pneumonia, or mediastinitis.Lifetime Oral Carcinogenicity Study in Mice
There were no signs of toxicosis in Charles River CD-1 (ICR) mice (115 mice/sex/dose group) given acyclovir by oral gavage at 50, 150 and 450 mg/kg/day in a lifetime oral carcinogenicity study. Mean plasma levels obtained in high-dose males 1.5 hours after dosing at various sampling times during the study were as follows: 2.83, 3.17 and 1.82 μg/mL (12.59, 14.10 and 8.10 μM) at days 90, 365 and 541, respectively. Corresponding mean values for the high-dose females were 9.81, 5.85 and 4.0 μg/mL (43.60, 26.0 and 17.79 μM).
Values for clinical laboratory tests including hematology, body weight and food consumption were all within normal ranges. There were no drug-induced gross or microscopic lesions. Female mice given 150 and 450 mg/kg acyclovir survived significantly longer than control female mice; survival of treated males was comparable to survival of control males. Patterns of tumor incidence and tumor counts for benign or malignant neoplasms were not affected by treatment with acyclovir.Chronic 12-Month Oral Toxicity Study in Dogs
Purebred Beagle dogs were given 0, 15, 45 or 150 mg/kg/day of acyclovir each day for the first two weeks of a one-year study. There were 9 male and 9 female dogs in each test group. The dogs were given gelatin capsules that contained the appropriate dose. They were treated t.i.d., hence the dosages administered at each of three equally spaced dose periods were 0, 5, 15 and 50 mg/kg. The 45 and 150 mg/kg dose levels induced diarrhea, emesis, decreased food consumption and weight loss in both male and female dogs during the first two weeks of the study. For this reason, during the third week of the study the decision was made to decrease the mid- and high-dosage levels to 30 and 60 mg/kg/day (10 and 20 mg/kg t.i.d.). The low dose of 15 mg/kg/day (5 mg/kg t.i.d.) was unchanged. Dogs given 60 mg/kg/day occasionally vomited and occasionally had diarrhea but did well for the duration of the test, and values for body weight gain and food consumption were comparable to control values.
During the toxicosis induced by the larger doses of acyclovir, plasma levels of the drug were likely very high (as indicated by initial mean values of 24.0 μg/mL (106.6 μM) for high-dose males and 17.4 μg/mL (77.2 μM) for high-dose females when determined 1 hour after the third dose on day 1 of the study). When measured on day 15, plasma levels of acyclovir in high-dose dogs (150 mg/kg/day) were still very high but they decreased later when the dosages were decreased. Values for plasma levels after 12 months of treatment were generally comparable to values recorded after 1, 3 and 6 months of treatment. Thus, there was no indication of enhanced metabolism of acyclovir as a result of chronic treatment.
During the 13th week, some male and female dogs at both the mid- and high-dosage levels had the following signs: tenderness in forepaws, erosion of footpads, and breaking and loosening of nails. Regeneration of lost nails began a few weeks later. Nails regenerated by 6 months (when 3 males and 3 females from each group were killed for an interim sacrifice) and by the end of the study were of generally good quality. There were never any signs of an effect on paws or nails in dogs in the low dose group (15 mg/kg/day).
It is accepted that injury of the corial epithelium that produces nail keratin can result in arrested production of keratin and production of abnormal keratin. The transient toxicosis induced by the large doses (45 and 150 mg/kg/day) of acyclovir given during the first two weeks of the study may have affected the corial epithelium. If there was a transient effect on the corial epithelium (possibly related to direct effects or secondary to drug-induced illness during the first two weeks of the study) later loss of the nail could be a sequella. No discernible effects upon other keratin-producing or keratin-containing tissues were observed. It should be emphasized that the alterations in the nails appeared to be related to the transient toxicosis induced by dose levels of 50 and 150 mg/kg/day tested during the first two weeks of the study and not to the 30 and 60 mg/kg/day dose levels tested subsequently.
There were no important drug-induced alterations in values for serum biochemical tests, urinalyses and electrocardiographic tests done at appropriate intervals during this study. Values for serum albumin and total protein were slightly decreased in dogs treated at 30 and 60 mg/kg/day for 6 and 12 months. However, all values for these parameters remained within limits accepted as normal.
With the exception of residual alterations in old keratin at the tips of the claws, there were no signs of treatment-related effects in any of the tissues examined by light microscopy. Nor were there meaningful alterations in values for the organs weighed at necropsy. Thus, dose levels up to 60 mg/kg/day were well tolerated for one year. The “no dose effect” dose level of acyclovir was 15 mg/kg/day (5 mg/kg t.i.d.); however, the only adverse effects at 30 or 60 mg/kg/day were changes in nails and footpads (30 and 60 mg/kg/day) and mild gastrointestinal signs (60 mg/kg/day).
Reproduction StudiesTeratology – Rats
Acyclovir was administered to pregnant A.R.S. Sprague-Dawley female rats by subcutaneous injection during the period of organogenesis (day 6 through day 15 of gestation) at dose levels of 0.0, 6.0, 12.5 and 25.0 mg/kg body weight twice daily.
Criteria evaluated for compound effect included maternal body weights, weight gains, appearance and behaviour, survival rates, eye changes, pregnancy rates, and reproduction data. Offspring viability and development were also evaluated.
In addition to the above measurements, designated animals were sacrificed 1 hour after the first dose on day 15 in order to collect samples of maternal blood, amniotic fluid and fetuses for measurements of drug concentration. Mean values from these samples are listed in Table 8.
Table 8 : Acyclovir Concentrations in a Teratology Study in Rats
|Dose mg/kg b.i.d., s.c.||Plasma fag/mL)||Acyclovir Concentrations|
|Amniotic Fluid fag/mL)||Fetal Homogenate|
|μg/mL||(nmoles/g wet wt)|
The values obtained for plasma would represent about 30% of initial plasma levels as judged by the plasma half-life in rodents.
No effects attributable to the administration of acyclovir were noted in comparisons of maternal body weight values, appearance and behaviour, survival rates, pregnancy rates, or implantation efficiencies. In addition, no compound-related differences were noted in evaluations of fetal size, sex and development.
Although the incidences of resorption and fetal viability were within the range of normal variability in all of the groups, slightly greater incidences of resorptions were noted in the high-dose animals sacrificed on days 15 and 19 of gestation; however, clear dose-related trends did not eventuate.
Therefore, acyclovir was not considered teratogenic or embryotoxic when administered to rats at levels up to 50.0 mg/kg of body weight per day during organogenesis.Teratology – Rabbits
A teratology study was done in New Zealand White rabbits using essentially the same experimental design as in the rat, except that dosing was from day 6 through day 18 of gestation. Also, collection of fetuses, amniotic fluid and samples of maternal blood occurred on day 18 rather than day 15.
No signs of maternal toxicity were observed at any dose, but there was a statistically significant (p < 0.05) lower implantation efficiency in the high-dose group. While there were a few terata observed in the study (in both control and treated animals), there was no apparent association with drug treatment. There was, however, an apparent dose-related response in the number of fetuses having supernumerary ribs. No similar effect was noted in the rat teratology study (see above) or in a reproduction-fertility experiment in mice.
Concentrations of acyclovir were detected in plasma and amniotic fluid samples, as well as in homogenates of fetal tissues. All samples were taken one hour after the first dose on day 18 of gestation. Drug concentrations in amniotic fluid were substantially higher than that of plasma (see Table 9).
Table 9 : Acyclovir Concentrations in a Teratology Study in Rabbits
|Dose mg/kg b.i.d., s.c.||Plasma fag/mL)||Acyclovir Concentrations (Mean and S.E.)|
|Amniotic Fluid fag/mL)||Fetal Homogenate|
|μg/mL||(nmoles/g wet wt)|
Acyclovir was shown not to impair fertility or reproduction in groups of 15 male and 30 female mice in a two-generation fertility study. The mice in this study were given acyclovir by gastric intubation at dosage levels of 50, 150 and 450 mg/kg/day. Males were dosed for 64 consecutive days prior to mating and females for 21 days prior to mating.
In a rat fertility study where groups of 20 male and 20 female rats were given 0, 12.5, 25.0 and 50.0 mg/kg/day by subcutaneous injection, acyclovir was shown not to have an effect on mating or fertility. The males were dosed for 60 days prior to mating and until their mating schedule was completed. Female rats were dosed for 14 days prior to mating and until day 7 of pregnancy. At 50 mg/kg/day s.c. there was a statistically significant increase in post-implantation loss, but no concomitant decrease in litter size.
In 25 female rabbits treated subcutaneously with 50 mg/kg/day acyclovir on days 6 to 18 of gestation, there was a statistically significant decrease in implantation efficiency but no concomitant decrease in litter size. There was also a dose-related increase in the number of fetuses with supernumerary ribs in all drug-treated groups. This increase was not dose-related when the incidence of supernumerary ribs per litter was examined.
In 15 female rabbits treated intravenously with 50 mg/kg/day acyclovir on days 6 to 18 of gestation, there was no effect on either implantation efficiency or litter size.
In a rat peri- and postnatal study (20 female rats per group), acyclovir was given subcutaneously at 0, 12.5, 25 and 50 mg/kg/day from 17 days of gestation to 21 days postpartum. At 50 mg/kg/day s.c. there was a statistically significant decrease in the group mean numbers of corpora lutea, total implantation sites and live fetuses in the F1 generation. Although not statistically significant, there was also a dose-related decrease in group mean numbers of live fetuses and implantation sites at 12.5 mg/kg/day and 25 mg/kg/day s.c.
In a dose-range finding study with 5 female rabbits the intravenous administration of acyclovir at a dose of 100 mg/kg/day from days 6 to 8 of pregnancy, a dose known to cause obstructive nephropathy, caused a significant increase in fetal resorptions and a corresponding decrease in litter size. At a maximum tolerated intravenous dose of 50 mg/kg/day in rabbits there were no drug-related reproductive effects.
In a subchronic toxicity study where groups of 20 male and 20 female rats were given intraperitoneal doses of acyclovir at 0, 20, 80 or 320 mg/kg/day for one month, and followed for a one-month postdose period, there was testicular atrophy. Some histologic evidence of recovery of sperm production was evident 30 days postdose, but this was insufficient time to demonstrate full reversibility.
Groups of 25 male and 25 female rats were administered intraperitoneal doses of acyclovir at 0, 5, 20 or 80 mg/kg/day for 6 months. Ten male and 10 female rats in each group were continued undosed for 13 weeks. Testicular atrophy was limited to high-dose rats given 80 mg/kg/day for 6 months. Organ weight data and light microscopy defined full reversibility of the testicular atrophy by the end of the postdose recovery period.
In a 31-day dog study (16 males and 16 females per group) where acyclovir was administered intravenously at levels of 50, 100 and 200 mg/kg/day, testicles were normal in dogs at 50 mg/kg. Doses of 100 or 200 mg/kg/day caused death of some dogs due to cytostatic effects (bone marrow and gastrointestinal epithelium) and aspermic testes or testes with scattered aspermic tubules. It cannot be ruled out that the testicular change may have been primary, however, similar changes can be observed secondary to severe stress in moribund dogs.
Developmental Toxicity StudiesNeonatal Rats - Subchronic Study
Acyclovir dissolved in 0.4% sterile saline was given by subcutaneous injection to Charles River CD (Sprague-Dawley) neonatal rats for 19 consecutive days, beginning on the 3rd post-partum day. The dose levels tested were 0, 5, 20 and 80 mg/kg body weight. There were 12 litters (each consisting of 5 male and 5 female neonates nursing the natural dam) at each dose level. The dams were not treated. Neonates were removed from each group for necropsy and microscopic evaluation of a wide variety of tissues, including eyes and multiple sections of brain, after they had been treated for 5, 12 or 19 days and after a 3-week postdose drug-free period (at which time they were 45 days of age). Hematologic (hemoglobin, packed cell volume, RBC, WBC and differential cell counts) and clinical chemistry (BUN) tests were done after 16 days of treatment and repeated 18 days after the last (19th) dose was given.
Blood was collected from some neonates 30 minutes after treatment on day 1, on day 9 and at the end of the dose period for the determination of concentrations of acyclovir in plasma. The largest concentration of acyclovir in plasma was 99.1 μg/mL (440.5 μM) found in pooled plasma collected from 6 female high-dose (80 mg/kg) neonates 30 minutes after the first dose was given. Treatment with acyclovir did not increase mortality in the neonatal period.
Rats in the low-dose group gained as much body weight as the respective control rats. Significant (p < 0.05) reductions in mean body weight values were observed in mid- and high-dose group male and female neonates during the treatment period. Rats in the high-dose group partially compensated by gaining significantly more body weight than the controls during the postdose recovery period. There was a minimal but significant increase in BUN for male (p < 0.01) and female (p < 0.05) neonates in the high-dose group on dose day 16. This finding may be of biological importance because there were minimal accumulations of nuclear debris in renal collecting ducts and loops of Henle in kidney sections taken from high-dose neonates after 19 days of treatment and examined by light microscopy. This was the only time period (and the kidney was the only organ) in which minimal effects on developing organ systems were detected. Thus, 5 mg/kg was clearly a no effect dose level and 20 mg/kg caused only minimal decreases in body weight gain.
Eye examinations and light microscopy did not reveal adverse effects on ocular development. It should be emphasized that there was no morphologic or functional evidence of adverse effects on developing brain or other portions of the central nervous system. Thus, acyclovir is distinctly different than cytosine arabinoside which was reported to produce prominent cerebellar and retinal dysplasia in neonatal rats.Mutagenicity And Other Short-Term Studies
Acyclovir has been tested for mutagenic potential in a number of in vitro and in vivo systems:November 10, 2014 Page 27 of 38Microbial
Acyclovir was tested for mutagenic activity in the Ames Salmonella plate assay; in a preincubation modification of the Ames assay; in the Rosenkrantz E. coli polA+/polA- DNA repair assay; and in the eukaryote S. cerevisiae, D-4. All studies were performed both in the presence and absence of exogenous mammalian metabolic activation. Acyclovir gave no positive responses in any of these systems.
The previous Salmonella studies were extended to extremely high concentrations in order to achieve toxicity. No positive effects were observed either in the presence or absence of exogenous mammalian metabolic activation, at concentrations of acyclovir up to 300 mg/plate or 80 mg/mL.Mammalian Systems
Acyclovir was tested for mutagenic activity in cultured L5178Y mouse lymphoma cells, heterozygous at the thymidine kinase (TK) locus, by measuring the forward mutation rate to TK-deficiency (TK+/- → TK-/-; additional studies were performed at the HGPRT locus and at the Ouabain-resistance marker in these same cells. All studies were performed in the presence and in the absence of exogenous mammalian metabolic activation. The test compound was mutagenic at the TK locus at high concentrations (400 -2,400 μg/mL). (By comparison, the upper limit of acyclovir peak plasma levels following oral dosing of 200 mg q4h is 0.9 μg/mL). It was negative at the HGPRT locus and Ouabain-resistance marker. Identical results were obtained with and without metabolic activation.
Inconclusive results with no apparent dose-related response were obtained when acyclovir mutagenicity was studied at each of 3 loci (APRT, HGPRT and Ouabain-resistance) in Chinese hamster ovary (CHO) cells, both in the presence and absence of exogenous metabolic activation.
Acyclovir, at a concentration of 50 μg/mL (222 μM) for a 72-hour exposure, has been shown to cause a statistically significant increase in the incidence of morphologically-transformed foci resulting from treating BALB/C-3T3 cells in vitro in the absence of exogenous metabolic activation. The morphologically transformed foci have been shown to grow as tumours following transplantation into immunosuppressed, syngeneic, weanling mice. Tumour tissues were diagnosed as being either undifferentiated sarcomas or lymphosarcomas.
Acyclovir, at concentrations between 8 and 64 μg/mL for 18 hours' exposure, did not induce any morphologically-transformed foci among C3H/10T ½ cells treated in vitro in the absence of exogenous metabolic activation.
Acyclovir, at concentrations of 62.5 and 125 μg/mL for a 48-hour exposure, did not induce any chromosome aberrations in cultured human lymphocytes in the absence of exogenous metabolic activation. At higher concentrations, 250 and 500 μg/mL for 48 hours exposure, acyclovir caused a significant increase in the incidence of chromosome breakage. There was also a significant dose-related decrease in mitotic index with exposure to acyclovir.
Acyclovir, at doses of 25 and 50 mg/kg/day i.p. for 5 consecutive days, did not produce a dominant lethal effect in male BKA (CPLP) mice. Further, there was no evidence of a dominant lethal effect on Charles River CD-1 (ICR) male and female mice treated orally at dose levels of 50, 150 and 450 mg/kg/day as summarized for the Two Generation Reproduction/ Fertility Study.
Acyclovir, at single intraperitoneal doses of 25, 50 and 100 mg/kg, failed to induce chromosome aberrations in bone marrow cells of Chinese hamsters when examined 24 hours after dosing. At higher nephrotoxic doses (500 and 1,000 mg/kg), a blastogenic effect was seen. (An intraperitoneal dose of 500 mg/kg produces mean peak plasma levels in Chinese hamsters of 611 μg/mL (2.72 mM) which is 680 times higher than the upper limit of human peak plasma levels during oral dosing of 200 mg q4h).
Acyclovir, at single intravenous doses of 25, 50 and 100 mg/kg, failed to induce chromosome aberrations in bone marrow cells of male and female rats when examined at 6, 24 and 48 hours after treatment.
Thus, all these studies showed that acyclovir does not cause single-gene mutations but is capable of breaking chromosomes.
Acyclovir was subjected to a number of in vitro and in vivo immunological tests.
In two in vivo tests, lymphocyte-mediated cytotoxicity and neutrophil chemotaxis, acyclovir showed no inhibitory effects at concentrations as high as 135 μg/mL (600 μM). The compound inhibited rosette formation approximately 50% at 0.9 μg/mL (4 μM).
In four in vivo tests in mice which measured cell-mediated immunity (complement-dependent cellular cytotoxicity, complement-independent cellular cytotoxicity, delayed hypersensitivity and graft vs. host reaction) acyclovir showed no inhibitory effects at single doses up to 200 mg/kg given on day 2 after antigenic stimulation.
Four daily doses of 100 mg/kg/day had no significant effect on Jerne hemolysin plaques or circulating antibody on day 7 after antigenic stimulation. When the Jerne hemolysin plaques and antibody titers were examined four days after antigenic challenge and one day after the last drug dose, 100 mg/kg showed only a slight suppressive effect. However, 200 mg/kg produced some weight loss (-2.2 g), a moderate reduction in the number of Jerne hemolysin plaques (PFC/spleen were reduced to 33% of control, PFC/107 WBC to 46.5% of control). However, there was only a small reduction in the circulating hemagglutinin titer (from 8.3 to 6.5) and the circulating hemolysin titer (from 9.5 to 8.3) at 200 mg/kg.
In experiments in mice designed to test whether acyclovir would potentiate the immunosuppressive effect of azathioprine on antibody formation, it was found that the effects of the two drugs were no more than additive. Only the 200 mg/kg dose of acyclovir showed an increased suppression of antibody response when given in combination with azathioprine at doses above 25 mg/kg.
Studies were carried out to evaluate the influence of acyclovir in vitro on human lymphocyte function. Inhibitory effects on blastogenesis were seen only in assays examining peak concentrations of potent mitogens, phytohemagglutinin (PHA) and concanavalin A (Con A), and only at concentrations of drug above 50 μg/mL (222 μM) and were much less with monilia and tetanus toxoid antigens, where the blastogenic response is characteristically less vigorous. There was very little effect on cytotoxicity or LIF production except at concentrations of 200 μg/mL (890 μM) where there has already been demonstrated to be a direct cytotoxic effect. These inhibitory concentrations are far in excess of anticipated levels from doses selected for clinical application and over 1,000-fold higher than the concentration required to inhibit herpesvirus multiplication in vitro.
The effect of acyclovir on human cells was measured. A concentration of 11.2 - 22.5 μg/mL (50-100 μM) inhibits the division of fibroblasts to a variable extent, depending on the experimental design and the confluency of the monolayer. The magnitude of this effect was less than that caused by adenine arabinoside or human leukocyte interferon when these three antiviral agents were compared at clinically relevant concentrations. Acyclovir also inhibited thymidine incorporation by peripheral blood mononuclear cells stimulated by PHA or three different herpesvirus antigens. A linear dose-response curve was observed with these cells, and their proliferation was 50% inhibited by 22.5 μg/mL (100 μM) acyclovir. Inhibition was exerted on T-cell proliferation without apparent effect on the release of lymphokines or on monocyte function.
It should also be mentioned that there was no evidence of adverse effects on the immune system in the detailed subchronic and chronic animal tests covered earlier in this summary except at excessively high doses (50 to 100 mg/kg b.i.d.) in dogs where marked lymphoid hypoplasia occurred.
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Uses for Acyclovir
Mucocutaneous, Ocular, and Systemic Herpes Simplex Virus (HSV) Infections
Treatment of initial and recurrent mucocutaneous HSV-1 and HSV-2 infections (e.g., orofacial, esophageal, genital, nasal, labial) in immunocompromised adults, adolescents, and children, including HIV-infected individuals.322 381 396 409 410 412 413 Drug of choice.322 381 396 410 412 413
Chronic suppressive or maintenance therapy (secondary prophylaxis) of recurrent HSV infections† in immunocompromised adults, adolescents, and children, including HIV-infected individuals who have frequent or severe recurrences.322 392 404 412
Treatment of orolabial HSV infections (including gingivostomatitis) in immunocompetent† adults and children;322 381 418 generally ineffective or minimally effective for prevention of recurrence of herpes labialis† in immunocompetent individuals.322 422
Treatment of eczema herpeticum† in patients with a history of atopic dermatitis.223 224
Treatment of HSV keratitis† in HIV-infected patients.407
Prophylaxis against recurrence of ocular HSV disease† in immunocompetent adults and children ≥12 years of age who had ocular HSV disease (blepharitis, conjunctivitis, epithelial keratitis, stromal keratitis, iritis) in one or both eyes within the preceding 12 months.408 419 Has been used for prophylaxis after penetrating keratoplasty for herpetic keratitis.420
Drug of choice for treatment of HSV encephalitis.211 212 246 248 322 381 395 409 410 412 413
Drug of choice for treatment of neonatal HSV infections, including mucocutaneous infections, infections involving skin, eyes, and mouth, and disseminated or CNS infections.244 322 324 353 356 381 395 408 409 410 413
Drug of choice for prevention of HSV recurrence† in hematopoietic stem cell transplant (HSCT) recipients seropositive for HSV; such prophylaxis not indicated in those seronegative for HSV.414
Treatment of initial episodes of genital herpes in adults and adolescents,206 207 208 244 305 313 322 381 403 409 including HIV-infected individuals.412
Treatment of first episodes of herpes proctitis†.305
Episodic treatment of recurrent episodes of genital herpes in adults and adolescents,244 313 322 381 403 including HIV-infected individuals.244 412
Chronic suppressive therapy of recurrent episodes of genital herpes in adults and adolescents,202 203 210 242 244 313 317 318 319 320 321 322 381 384 386 403 including HIV-infected individuals.244 412
CDC and others recommend oral acyclovir, oral famciclovir, or oral valacyclovir as drugs of choice for treatment of initial episodes of genital herpes and for episodic treatment or chronic suppressive therapy of recurrent genital herpes.244 313 381 412
Treatment of varicella (chickenpox) in immunocompromised adults, adolescents, and children, including HIV-infected individuals.249 277 279 322 352 353 368 403 409 410 412 413 Drug of choice.249 277 279 322 352 353 368 410 412 413
Treatment of varicella (chickenpox) in immunocompetent adults, adolescents, and children.239 322 337 338 340 344 348 352 353 368 381 394 403 410 415 Varicella usually is a self-limited disease in otherwise healthy individuals and the role of acyclovir for treatment in these individuals is controversial;239 329 330 331 332 333 335 336 337 338 344 349 350 355 368 routine use not recommended by AAP and other clinicians.322 331 332 335 344 345 368
Treatment of herpes zoster (shingles, zoster) in immunocompetent261 284 285 309 353 or immunocompromised adults, adolescents, and children, including HIV-infected individuals.322 358 359 381 403 409 410 412 413 Drug of choice for serious or disseminated herpes zoster in immunocompromised patients.381 413
Treatment of herpes zoster ophthalmicus† in HIV-infected patients.407 412
Treatment of dermatomal herpes zoster in immunocompromised patients† including transplant recipients225 and HIV-infected patients.219 407 412
Alternative to varicella-zoster immune globulin (VZIG) for postexposure prophylaxis of VZV infection† in HSCT recipients.414 Although long-term prophylaxis not routinely recommended for prevention of recurrent VZV infections in HSCT recipients, such prophylaxis may be considered in those with severe, long-term immunodeficiency.414
Prevention of Cytomegalovirus (CMV) Disease in Transplant Recipients
Has been used for prevention of CMV disease† in solid organ transplant recipients354 360 363 364 365 366 367 398 399 414 and bone marrow transplant (BMT) recipients at risk for the disease; data regarding efficacy are conflicting.354 360 365 367 382
Has been used for prevention of CMV disease† in HSCT recipients; generally ineffective after autologous HSCT.414 Ganciclovir is drug of choice for prevention of CMV following autologous or allogeneic HSCT in adults, adolescents, and children.414
Not effective for prevention of CMV disease in HIV-infected individuals.404
Epstein-Barr Virus Infections and Disorders
Treatment of uncomplicated or complicated infectious mononucleosis, chronic infectious mononucleosis, and various disorders (e.g., oral hairy leukoplakia) associated with Epstein-Barr virus infections†;262 270 271 272 369 396 efficacy appears to be variable.230 262 272 273 274 275 276 369
Actions and Spectrum
Active against various Herpesviridae including herpes simplex virus types 1 and 2 (HSV-1 and HSV-2), varicella-zoster virus (VZV), Epstein-Barr virus, herpes virus simiae (B virus), and cytomegalovirus (CMV).354 403 409 Less active against CMV than many other Herpesviridae.354
In cells infected with herpes virus, is converted to acyclovir triphosphate,354 403 which inhibits viral DNA synthesis and viral replication by incorporating into viral DNA and by competing with deoxyguanosine triphosphate for viral DNA polymerase.a 403 409
Acyclovir resistance may result from qualitative or quantitative changes in thymidine kinase and/or DNA polymerase (e.g., absence or low concentrations of enzyme, alterations in substrate specificity).a 403 409
Resistance to acyclovir reported in HSV and VZV.244 381 413
Acyclovir-resistant HSV or VZV usually resistant to famciclovir and valacyclovir, but may be susceptible to foscarnet.244 381 413
Acyclovir side effects
Get emergency medical help if you have any signs of an allergic reaction to acyclovir: hives; difficult breathing; swelling of your face, lips, tongue, or throat.
Call your doctor at once if you have:
easy bruising or bleeding, purple or red pinpoint spots under your skin; or
signs of a kidney problem -little or no urinating; painful or difficult urination; swelling in your feet or ankles; feeling tired or short of breath.
Common acyclovir side effects may include:
general ill feeling;
mouth pain while using an acyclovir buccal tablet.
This is not a complete list of side effects and others may occur. Call your doctor for medical advice about side effects. You may report side effects to FDA at 1-800-FDA-1088.
Usual Adult Dose for Herpes Simplex Labialis
Apply 50 mg (1 buccal tablet) as a single-dose to the upper gum region (canine fossa)
-Tablet should be applied within 1 hour after the onset of prodromal symptoms and before the appearance of any signs of herpes labialis lesions.
-Tablet should be applied on the same side of the mouth as the herpes labialis symptoms.
-Use of buccal tablets has not been studied in immunocompromised subjects.
Concomitant HIV infection:
Oral tablets: 400 mg orally 3 times a day for 5 to 10 days
Comment: Guidelines for the Prevention and Treatment of Opportunistic Infections Among HIV- Infected Adults and Adolescents may be consulted for additional guidance.
Use: For the treatment of herpes simplex labialis (cold sores).
Usual Adult Dose for Herpes Simplex - Suppression
Daily Suppressive Therapy for Recurrent Disease: 400 mg orally 2 times a day
-Alternative regimens from 200 mg orally 3 times a day to 200 mg orally 5 times a day have been used
Concomitant HIV infection: 400 to 800 mg orally 2 to 3 times a day
-Suppressive therapy has been shown to reduce the frequency of recurrences by 70% to 80% in patients who have frequent recurrences.
-The frequency of recurrences has been shown to decrease over time and therefore continued therapy should be reevaluated at least annually.
-Experience has shown immunocompromised persons (i.e. hematopoietic stem-cell recipients) who received daily suppressive antiviral therapy were less likely to develop drug-resistant
HSV compared with those receiving episodic therapy; however, resistance is possible and should be suspected and investigated if lesions persist or recur.
-CDC STD Treatment Guidelines and the Guidelines for the Prevention and Treatment of Opportunistic Infections Among HIV- Infected Adults and Adolescents may be consulted for additional guidance.
Use: For secondary prophylaxis and treatment of recurrent HSV disease.
Renal Dose Adjustments
For CrCl 0 to 10 mL/min/1.73 m2:
-If normal dose is 200 mg orally every 4 hours 5 times a day: Reduce dose to 200 mg orally every 12 hours
-If normal dose is 400 mg orally every 12 hours: Reduce dose to 200 mg orally every 12 hours
-If normal dose is 800 mg orally every 4 hours 5 times a day: Reduce dose to 800 mg orally every 12 hours
For CrCl 10 to 25 mL/min/1.73 m2:
-If normal dose is 800 mg orally every 4 hours 5 times a day: Reduce dose to 800 mg orally every 8 hours
For CrCl 0 to 10 mL/min/1.73 m2: Give 50% of dose every 24 hours
For CrCl 10 to 25 mL/min/1.73 m2: Give 100% of dose every 24 hours
For CrCl 25 to 50 mL/min/1.73 m2: Give 100% of dose every 12 hours
For CrCl greater than 50 mL/min/1.73 m2: Give 100% of dose every 8 hours
Liver Dose Adjustments
No adjustment recommended
Safety and efficacy of oral formulations have not been established in patients younger than 2 years.
Safety and efficacy of buccal tablets have not been established in pediatric patients.
Consult WARNINGS section for additional precautions.
What happens if I miss a dose?
Take the missed dose as soon as you remember. Skip the missed dose if it is almost time for your next scheduled dose. Do not take extra medicine to make up the missed dose.
What other drugs will affect acyclovir?
Acyclovir can harm your kidneys. This effect is increased when you also use certain other medicines, including: antivirals, chemotherapy, injected antibiotics, medicine for bowel disorders, medicine to prevent organ transplant rejection, injectable osteoporosis medication, and some pain or arthritis medicines (including aspirin, Tylenol, Advil, and Aleve).
Other drugs may interact with acyclovir, including prescription and over-the-counter medicines, vitamins, and herbal products. Tell each of your health care providers about all medicines you use now and any medicine you start or stop using.
Remember, keep this and all other medicines out of the reach of children, never share your medicines with others, and use this medication only for the indication prescribed.
Always consult your healthcare provider to ensure the information displayed on this page applies to your personal circumstances.
Copyright 1996-2018 Cerner Multum, Inc. Version: 5.08.
Dosing & Uses
Dosage Forms & Strengths
injection, lyophilized powder for reconstitution
Initial treatment: 200 mg PO q4hr while awake (5 times daily) for 10 days or 400 mg PO q8hr for 7-10 days
Intermittent treatment for recurrence: 200 mg PO q4hr while awake (5 times daily) for 5 days; initiate at earliest sign or symptom of recurrence
Chronic suppression for recurrence: 400 mg PO q12hr for up to 12 months; alternatively, 200 mg 3-5 times daily
Herpes Simplex Virus Encephalitis
10-15 mg/kg IV q8hr for 10 days; up to 14-21 days reported
Mucocutaneous Herpes Simplex Virus Infection
Treatment in immunocompromised patients
IV: 5 mg/kg q8hr for 7 days; dosing up to 14 days reported
PO (off-label): 400 mg q4hr while awake (5 times daily) for 7 days
Herpes Zoster (Shingles)
Acute treatment: 800 mg PO q4hr while awake (5 times daily) for 7-10 days
- 10 mg/kg IV q8hr for 7 days
- CrCl 25-50 mL/min: Full recommended IV dose q12hr
- CrCl 10-25 mL/min: Full recommended IV dose once daily
- CrCl 0-10 mL/min: 50% of recommended IV dose once daily
Varicella Zoster (Chickenpox)
>40 kg (immunocompetent): 800 mg PO q6hr for 5 days
Immunocompromised patients: 10-15 mg/kg IV q8hr for 7-10 days
Dose adjustment based on renal clearance and normal dosage regimen
200 mg every 4 hr
- ≥10 mL/min/1.73 m²: 200 mg q4hr (five times daily)
400 mg every 12 hr
- ≥10 mL/min/1.73 m²: 400 mg q12hr
800 mg every 4 hr
- 10-25 mL/min/1.73 m²: 800 mg q8hr
- >25 mL/min/1.73 m²: 800 mg q4hr (five times daily)
Dose adjustment based on dosage form
Renal impairment (IV)
- CrCl 25-50 mL/min/1.73 m²: Give recommended dose q12hr
- CrCl 10-25 mL/min/1.73 m²: Give recommended dose q24hr
Renal impairment (PO)
- Normal dosage 200 mg q4hr or 400 mg q12hr and CrCl
- Normal dosage 800 mg q4hr and CrCl 10-25 mL/min/1.73 m²: Decrease to 800 mg q8hr
- Normal dosage 800 mg q4hr and CrCl
Herpetic Keratitis (Orphan)
Orphan designation for treatment of herpetic keratitis
- Cumulus Pharmaceuticals LLC; 1712 Pioneer Avenue, Suite 1377; Cheyenne, Wyoming 82001
Dosage Forms & Strengths
injection, lyophilized powder for reconstitution
powder for injection
Neonatal Herpes Simplex Virus Infection
Following doses based on research of the NIH National Institute of Child Health and Human Development (NICHD) that updated prescribing information was based on
Infuse IV over 1 hr
PMA ≥34 weeks: 20 mg/kg IV q8hr for 21 days
Caution if renal function beyond the effect of prematurity occurs
Herpes Simplex Virus Encephalitis
3 months-12 years: 20 mg/kg IV q8hr for 10 days; up to 14-21 days reported
≥12 years: 10-15 mg/kg IV q8hr for 14-21 days
Mucocutaneous Herpes Simplex Virus Infection
Treatment in immunocompromised patients
≥12 years: 5-10 mg/kg/day IV divided q8hr for 5-7 days; up to 14 days reported
Herpes Zoster (Shingles)
≥12 years (immunocompetent): 800 mg PO q4hr while awake (5 times daily) for 7-10 days
≥12 years (immunocompromised): 30 mg/kg/day IV divided q8hr for 7-10 days
Varicella Zoster (Chickenpox)
≥2 years and
≥40 kg: 800 mg PO q6hr for 5 days
- ≥12 years: 10 mg/kg/dose IV q8hr for 7 days
Use ideal body weight (IBW) for obese patients