Tuesday, December 26, 1995 12:39:07
               Puget Sound EMSForum Item
       From:           Sylvia Feder,Medic One OnLine
       Subject:        Occupational HIV infection in HCWs
       To:             KC EMSForum,Medic One OnLine
                       Puget Sound EMSForum
                       
       Cc:             
I doubt that a lot of you will want to read the entire article, but just in case, here it is, hot off the presses of the CDC's Morbidity and Mortality Weekly Report. This study was a case-control study examining health care workers who became infected with HIV after an accidental needlestick or other exposure. The study also looked at the rate of seroconversion in health care workers who were given prophylactic AZT. The conclusions (most of which are quite common-sense) are as follows: 
€  Risk of seroconversion is greatest if the exposure involved a larger quantity of blood injected into the health care worker. 
€  The risk increased for exposures to blood from source patients with terminal illness,
probably reflecting the higher titer of HIV in blood late in the course of AIDS (and possibly other factors)
€  Post-exposure prophylaxis with AZT (zidovidine) may have a protective effect. (this was the really interesting part of the study for me)

For those who are interested in that last tidbit of information, it is worth noting that a case-control study is not an efficient way to study this problem, since there may be other differences between the "cases" [the people who seroconverted] and the "controls" [the people who didn't]. However, the ideal study (a randomized placebo trial) was attempted several years ago but never finished because of the small numbers of seroconversions and the reluctance of people to agree to the possibility of getting placebo rather than AZT. In fact, for those who have followed this issue, AZT is gaining more support in terms of its protective effect in preventing infection of babies born to HIV-infected moms. So perhaps its protective effect after a needlestick is not so surprising. And, after saying all this time that if I ever got a high risk needlestick, I would never take AZT after seeing how sick it makes people, maybe I'd put up with that now!! In terms of post-exposure prophylaxis, the CDC makes the following recommendations: the health care worker should be counselled about possible complications and side-effects of AZT (most commonly GI problems, other complications are rarer). If the decision is made to start AZT, it should be given as soon as possible after the exposure. The CDC and the Public Health Service will be reviewing this study and others and coming up with definitive guidelines in the future. So stay tuned.... 

[Study follows.....]

syl

*****
for those who want to read the real thing......

December 22, 1995/Vol. 44/No. 50

*   Case-Control Study of HIV Seroconversion in Health-Care Workers 
    After Percutaneous Exposure to HIV-Infected Blood --- France, 
    United Kingdom, and United States, January 1988--August 1994 

[and now the fine print....]
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CDC's official MMWR electronic copy of record is the MMWR in Adobe
Acrobat portable document format (.pdf). The .pdf MMWR is identical
in content to the paper copy of record. The MMWR text that follows
is in ASCII text file format and has not been proofread. An
adequate ASCII translation does not exist for each character
possibly present in the .pdf file, and there may be other
significant character translation errors. Also, the ASCII text that
follows lacks the figures and tables of the electronic .pdf and
paper format of MMWR. Therefore, CDC does not consider this ASCII
text file to represent a copy of record of the MMWR. 

Notice to Readers
     Because of the furlough of U.S. government employees, CDC has
restricted its activities to responses to emergencies and other
public health matters of extreme urgency. This issue of MMWR
contains two reports with immediate public health implications: one
report provides measures for the prevention of hypothermia-related
morbidity and death, and the other report summarizes the findings
of a new study of factors associated with risk for and prevention
of human immunodeficiency virus (HIV) infection in health-care
workers following percutaneous exposure to HIV-infected blood.
Other reports of public health importance and findings from the
ongoing National Notifiable Disease Surveillance System will be
published at a later date, and printed versions of this issue will
be available to CDC's subscribers at a later date. The next
scheduled issue will be Volume 44, Numbers 51 and 52, dated January
5, 1996, and will include the figure and tables on notifiable
diseases for the weeks ending December 16, 23, and 30, 1995.
David Satcher, M.D., Ph.D.
Director, CDC


Case-Control Study of HIV Seroconversion in Health-Care Workers
After Percutaneous Exposure to HIV-Infected Blood -- France, United
Kingdom, and United States, January 1988-August 1994

     Health-care workers (HCWs) are potentially at risk for human
immunodeficiency virus (HIV) infection through occupational
exposures to blood. Although prospective studies indicate that the
estimated risk for HIV infection after a percutaneous exposure to
HIV-infected blood is approximately 0.3% (1,2), factors that
influence this risk have not been determined. To assess potential
risk factors, CDC, in collaboration with French and British public
health authorities, conducted a retrospective case-control study
using data reported to national surveillance systems in the United
States, France, and the United Kingdom. This report describes the
study and summarizes results that suggest that risk factors for HIV
transmission include certain characteristics of the exposure and
the source patient; in addition, postexposure use of zidovudine
(ZDV) by HCWs was associated with a lower risk for HIV
transmission.*
     Case-HCWs had a documented occupational percutaneous exposure
to HIV-infected blood (i.e., a needlestick or a cut with a sharp
object [e.g., scalpel or lancet]), HIV seroconversion temporally
associated with the exposure, and no other concurrent exposure to
HIV. Control-HCWs had a documented occupational percutaneous
exposure to HIV-infected blood and were HIV seronegative at the
time of exposure and at least 6 months later. Case-HCWs were
identified through reports to national surveillance systems for
occupationally acquired HIV infection operated by CDC, in
cooperation with state and local health departments (United
States), the National Public Health Network (Reseau National de
Sante Publique) (France), and the Public Health Laboratory Service
Communicable Disease Surveillance Center (United Kingdom).
Control-HCWs were identified through reports to a passive
surveillance project maintained by CDC since 1983 that includes
data from approximately 300 health-care institutions in the United
States (1).
     The study included all case-HCWs reported in the United States
whose exposure occurred during January 1988-August 1994 and all
control-HCWs exposed after January 1988 whose 6-month follow-up
evaluation was completed as of August 1994. Case- and control-HCWs
reported in the United States before 1988 were excluded from the
analysis because information on some variables was not routinely
collected and because postexposure use of ZDV was infrequent before
1988 (1). For similar reasons, analysis was limited to case-HCWs
reported in France since 1990 and in the United Kingdom since 1989.
     Information obtained about HCWs included age; sex; occupation;
work location; and whether postexposure antiretroviral agents were
offered, whether they were used, how long after the exposure the
first dose was used, daily dosage, and duration of treatment.
Information about source patients included stage of HIV infection
(acquired immunodeficiency syndrome [AIDS], symptomatic, or
asymptomatic), use of antiretroviral drugs at the time of the HCW's
exposure, and presence of terminal illness (i.e., death because of
AIDS within 2 months after the exposure). Information about
exposures included the type of device involved, gauge of
hollow-bore needle, type of procedure being performed, whether the
procedure was an emergency, use of gloves, time from use of the
device to exposure, presence of visible blood from the source
patient on the device, and severity of injury. Severity of injury
was defined as superficial (surface scratch, no blood appeared),
moderate (penetrated skin and blood appeared), or deep (deep
puncture or wound with or without bleeding).
     The study included 31 case-HCWs (23 from the United States,
five from France, and three from the United Kingdom) and 679
control-HCWs (who were from 190 of the reporting health-care
institutions). Of the 31 exposures sustained by case-HCWs, 29 (94%)
were needlesticks (all with hollow needles) and two (7%) involved
other sharp objects. Of the 679 exposures sustained by
control-HCWs, 620 (91%) were needlesticks (including 594 hollow and
26 solid needles) and 59 (9%) involved other sharp objects.
     For both case- and control-HCWs, 74% were exposed during 1990-1994, 
when ZDV postexposure use had become more common (1). During
1990-1994, 17 (81%) of 21 case-HCWs had been offered ZDV, and from
September 1990 (when collection of information on whether ZDV was
offered to control-HCWs became routine) through 1994, 268 (79%) of
338 control-HCWs were offered ZDV. ZDV postexposure prophylaxis was
used by nine (29%) case-HCWs and 247 (36%) control-HCWs (crude odds
ratio=0.7; 95% confidence interval [CI]=0.3-1.7). Regimens for
case- and control-HCWs generally were 1000 mg/day for 3-4 weeks;
the small number of case-HCWs who used ZDV precluded assessment of
differences in ZDV regimens between case- and control-HCWs.
     All variables that were statistically significant in the
univariate analysis and variables potentially important for
prevention (e.g., use of gloves, whether ZDV was offered, and
whether ZDV was used) were examined using logistic regression
analysis. Based on this analysis, factors associated with HIV
transmission included a deep injury, device visibly contaminated
with the source patient's blood, procedures involving a needle
placed directly in a vein or artery, and terminal illness in the
source patient. In addition, case-HCWs were significantly less
likely to use ZDV than control-HCWs (adjusted odds ratio=0.2, p
less than 0.01) (Table 1)**. The crude odds ratio for ZDV use
differed from the adjusted odds ratio because ZDV use was more
frequent, among both case- and control-HCWs, for exposures
characterized by the other factors. All factors in the model also
were significant when the analysis was restricted to case-HCWs from
the United States.
     The degree of susceptibility to ZDV of HIV strains from source
patients and case-HCWs is unknown. Information about antiretroviral
treatment for source patients was available for seven case-HCWs and
124 control-HCWs who had used ZDV; five (71%) case-HCWs and 87
(70%) control-HCWs were exposed to blood from source patients who
had been receiving ZDV at the time of the exposure.
Reported by: State and territorial health depts. CDC Cooperative
Needlestick Surveillance Group. D Abiteboul, MD, Institut National
de Recherche et de Securite and Groupe d'Etude sur le Risque
d'Exposition au Sang, Paris; F Lot, MD, Reseau National de Sante
Publique, Saint Maurice, France. J Heptonstall, MRCPath, Public
Health Laboratory Service Communicable Disease Surveillance Center,
London, United Kingdom. Div of HIV/AIDS Prevention, National Center
for Prevention Svcs; Hospital Infections Program, National Center
for Infectious Diseases, CDC.
Editorial Note: The findings in this report indicate that, among
the HCWs in this study, an increased risk for HIV infection
following percutaneous exposures to HIV-infected blood was
associated with three factors. First, the risk increased if the
exposure involved a larger quantity of blood, indicated by 1) a
device visibly contaminated with the patient's blood, 2) a
procedure that involved a needle placed directly in a vein or
artery, or 3) a deep injury. Second, the risk increased for
exposures to blood from source patients with terminal illness,
probably reflecting the higher titer of HIV in blood late in the
course of AIDS or other factors, such as the presence of
syncytia-inducing strains of HIV (3,4). Finally, the analysis of
these data suggested that use of ZDV postexposure may be protective
for HCWs. After controlling for other factors associated with HIV
transmission risk, the model indicates that the risk for HIV
infection among HCWs who used ZDV was reduced by approximately 79%
(95% CI=43%-94%) (based on adjusted odds ratio=0.21; 95% CI=0.06-0.57). 
However, the limitations of the study design must be
considered when interpreting these results.
     A retrospective case-control study is not the optimal study
design for assessing ZDV efficacy. The optimal approach--a
prospective, placebo-controlled trial--has not been possible
because of the requirement for a large number of HCWs and the
relatively low rate of HIV seroconversion following occupational
exposure (1). The findings of this study also are subject to at
least five potential limitations. First, case- and control-HCWs
were identified using different data sources. Second, if
control-HCWs were more likely to have been offered or encouraged to
use ZDV, then use of the drug might be statistically associated
with lack of HIV seroconversion, even if ZDV is not truly
protective; however, available evidence does not suggest that
control-HCWs were more likely than case-HCWs to have been offered
ZDV. Third, reporting bias may have resulted if HCWs preferentially
reported exposures that they believed were more likely to result in
HIV transmission; this tendency presumably would be similar for
case-HCWs and control-HCWs. Fourth, ascertainment bias may have
affected some data, particularly subjective variables such as
severity of injury, because information for control-HCWs was
obtained prospectively soon after exposure but information for most
case-HCWs was obtained after HIV seroconversion; however, for most
variables evaluated, objective documentation from incident reports
and medical records was available. Finally, number of case-HCWs
evaluated was small.
     Although failures of postexposure ZDV to prevent HIV infection
in HCWs have been documented (1), this is the first study of HCWs
exposed to HIV that assesses the effectiveness of ZDV as
postexposure prophylaxis. Studies involving animals have yielded
inconclusive results (5). In studies involving humans, ZDV was
reported to reduce the rate of perinatal HIV transmission (6) and
to be beneficial in treating early HIV infection (7); however, the
implications of these results for postexposure prophylaxis are
uncertain. The short-term toxicity of ZDV in HCWs primarily has
been gastrointestinal discomfort and fatigue (1,2,5,8).
     ZDV is not approved by the Food and Drug Administration for
use as postexposure prophylaxis. In a previous statement, the
Public Health Service (PHS) concluded that a recommendation could
not be made for or against the use of ZDV postexposure prophylaxis
because of limited knowledge regarding its efficacy and toxicity
(9). PHS recommends that HCWs who may be at risk for occupational
exposure to HIV infection be informed of the considerations
pertaining to the use of ZDV for postexposure prophylaxis,
including the risk for HIV transmission after the exposure, factors
that may increase or decrease this risk, and the limited knowledge
regarding the potential efficacy and toxicity of ZDV postexposure
prophylaxis (9). If a decision is made to use postexposure
prophylaxis, it should be initiated promptly (9). PHS is evaluating
the implications of the study summarized in this report and other
available information in assessing the possible need for revision
of recommendations for managing occupational exposure to HIV--
particularly regarding postexposure use of antiretroviral agents.
References
1. Tokars JI, Marcus R, Culver DH, et al. Surveillance of HIV
infection and zidovudine use among health care workers after
occupational exposure to HIV-infected blood. Ann Intern Med
1993;118:913-9.
2. Henderson DK. HIV-1 in the health care setting. In: Principles
and practice of infectious diseases. 4th ed. Mandel GL, Bennett JE,
Dolan R, eds. New York: Churchill Livingstone, 1995:2632-56.
3. Ho DD, Mougil T, Alam M. Quantitation of HIV type 1 in the blood
of infected persons. N Engl J Med 1989;321:1621-5.
4. Richman DD, Bozzette S. The impact of syncytium-inducing
phenotype of human immuno-deficiency virus on disease progression.
J Infect Dis 1994;169:968-74.
5. Gerberding JL. Management of occupational exposures to
blood-borne viruses. N Engl J Med 1995;332:444-51.
6. CDC. Recommendations of the U.S. Public Health Service task
force on the use of zidovudine to reduce perinatal transmission of
HIV. MMWR 1994;43(no. RR-11):1-20.
7. Ho DD. Time to hit HIV, early and hard [Editorial]. N Engl J Med
1995;333:450-1.
8. Puro V, Ippolito G, Guzzanti E, et al. Zidovudine prophylaxis
after accidental exposure to HIV: the Italian experience. AIDS
1992;6:963-9.
9. CDC. Public Health Service statement on management of
occupational exposure to human immunodeficiency virus, including
considerations regarding zidovudine postexposure use. MMWR
1990;39(no. RR-1).
* Single copies of this report will be available free until
December 21, 1996, from the CDC National AIDS Clearinghouse, P.O.
Box 6003, Rockville, MD 20849-6003; telephone (800) 458-5231 or
(301) 217-0023.
** Information on terminal illness in the source patient was
missing for 19% of case-HCWs and 48% of control-HCWs; information
on visible blood on device was missing for 3% of case-HCWs and 6%
of control-HCWs. By recoding the missing values to zero and
including missing value indicator variables for these factors in
the model, these HCWs were retained in the analysis and their
potential confounding influence could be assessed. No significant
interactions were found among the risk factors in the model or
between the risk factors and the missing value indicators. When all
HCWs with missing values for any of the factors were excluded from
the analysis, all of the factors remained significant, with similar
adjusted odds ratios but larger confidence intervals.