Date: 18 Apr 1998 19:23:53
From: aidsnews.org@igc.org
Subject: AIDS Treatment News #293

AIDS TREATMENT NEWS Issue #293, April 17, 1988
   phone 800-TREAT-1-2, or 415-255-0588

CONTENTS:

T-20 and Trimeris

Adefovir Dipivoxil (PREVEON) Improved Expanded-Access Program

Adefovir Dipivoxil (PREVEON) New Results with Hepatitis B, 
HIV

HIV/AIDS Nutrition Book for Clinicians

Treatment Conference Call May 2

Geneva Conference Communication Proposals for Minorities Due 
May 12

New Priority Email Delivery from AIDS TREATMENT NEWS


***** T-20 and Trimeris

by John S. James

T-20 (also knows as pentafuside) a "fusion inhibitor," is an 
entirely new kind of HIV treatment being developed by 
Trimeris, Inc., a small biotechnology company in Durham, 
North Carolina. Because of its complex and unique mechanism 
of action, this drug and its development have not been widely 
understood; they have been "off the radar" of Wall Street and 
the media, even the AIDS press. We think this work is as 
important as anything now happening in AIDS research, for 
several reasons:

* T-20 has successfully shown "proof of principle" in 
patients, with a clear dose response and, at the highest 
dose, antiviral activity at least equivalent to a protease 
inhibitor in all four patients receiving that dose. No human 
toxicity has been seen. A larger trial is about to begin.

* T-20 works differently than any retroviral now in use 
(meaning that it targets a different step in the viral life 
cycle). Therefore, it is unlikely to have any cross 
resistance with existing treatments, and should work equally 
well no matter what treatment history a patient has.

* Both theory and laboratory tests suggest that resistance to 
T-20 will be slow to develop, although it can exist. None has 
been seen in people so far. In the laboratory, resistant 
virus has been produced--but then that virus was used to 
design a new drug like T-20 which was effective against it.

* T-20 is active only against HIV-1; however, the same 
mechanism may lead to the development of similar drugs active 
against other enveloped viruses--a group which includes 
influenza, hepatitis B, hepatitis C, and Ebola fever.

* T-20 is active against all strains of HIV-1 tested so far. 
Since the co-receptor used by the virus does not matter, the 
compound is equally active against both SI (syncytium 
inducing) and NSI (non syncytium inducing) viruses. 
(Incidentally there is a little activity against HIV-2, but 
not enough to be clinically useful. A different drug like T-
20 has been developed against HIV-2.)

* Trimeris has two technologies for finding other drugs in 
the same class as T-20 (that is, which exploit the same viral 
target), either against HIV or other viruses. One analyzes 
viral sequences to find similar compounds which might work 
better than T-20 itself--for example, against resistant 
viruses. The other technology uses laboratory procedures to 
screen chemical libraries to look for small-molecule 
compounds which are chemically unrelated to T-20, but have 
equivalent antiviral action.

T-20 Disadvantages

The main disadvantage of this potential treatment is that it 
must be given by injection. It will probably be delivered 
subcutaneously by a portable infusion pump, which is worn 
like a pager--probably the pump made by MiniMed, Inc., which 
is currently used by tens of thousands of diabetics to inject 
insulin. Eventually, orally bioavailable compounds with the 
same mechanism of action may be developed.

Meanwhile, an injectable drug does have compensating 
advantages, especially for patients with advanced illness. 
Much greater control of blood levels is possible, because the 
pump can be programmed to deliver whatever amount is needed, 
continuously or on any schedule required. There are no daily 
peak and trough blood levels unless those are wanted, and no 
drug variation due to delay or forgetting to take pills.

Also, all problems of drug absorption go away, along with 
this source of unknown variation between patients. Diarrhea 
or other gastrointestinal problems will not affect blood 
levels. And there is never a need to have a full or empty 
stomach for this drug.

Instead, a needle is changed every three days. It is a small 
needle, since T-20 is given continuously, so a very low flow 
rate is required. The pump can be detached for activities 
like showers or swimming--and programmed to give a bolus dose 
first, which can maintain an effective blood level with the 
pump detached for up to several hours. The pump can be worn 
during sleep.

What Is T-20 and How Does It Work?

T-20 was discovered several years ago at Duke University by 
Thomas Matthews, Ph.D., in the Laboratory of Dani P. 
Bolognesi, Ph.D. Dr. Bolognesi's team, working to develop 
candidates for an HIV vaccine, compared viral sequences from 
different strains of HIV, looking for a part of the virus 
which changed very little from strain to strain. The idea was 
to use this piece of the virus for a vaccine which could 
provide immunity against many different variants of HIV from 
around the world. This search for a conserved sequence in the 
virus led to a part of gp41, the HIV protein which penetrates 
uninfected cells as the first step in viral entry. This 36-
amino acid piece of gp41 was manufactured for further tests. 
It failed to work for a vaccine, however.

But before moving on, Dr. Matthews tested this piece of the 
virus against live HIV, and found that it was highly 
effective in stopping the virus from infecting new cells.(1) 
The potential drug which is code-named T-20 is therefore a 
piece of the HIV virus itself.

Exactly how T-20 works involves complex protein 
biochemistry.(2) But basically, at one step in the entry 
process, the T-20 portion of gp41 must bind with a 
complementary sequence which is also in gp41; this binding 
changes the shape of gp41 and exposes the portion which first 
penetrates the membrane of the cell. The binding is part of 
an elaborate process which recognizes the cell's receptors, a 
process HIV and other enveloped viruses have evolved in order 
to be selective. Otherwise these viruses would be likely to 
enter cells where they could not reproduce, or try to enter 
debris which was not a cell at all.

T-20 is believed to interfere with this cell entry process by 
binding to its target first, displacing the T-20 sequence 
within HIV. Therefore the gp41 cannot change its shape into 
that which is required to enter the cell.

Viral Resistance to T-20

HIV resistant to T-20 has been created in laboratory tests.
This resistance may be slow to develop, however, because the 
sequence which T-20 binds to in gp41 is highly conserved 
among different strains of HIV. When part of a virus stays 
much the same from strain to strain, it usually means that 
the region is critical, and changes there could produce a 
defective virus which is not viable. The T-20 sequence can 
vary somewhat, but HIV seems to have less freedom here than 
it does elsewhere.

When HIV resistant to T-20 does occur, it appears 
straightforward to develop a new inhibitor like T-20 against 
it. Since there may be few options for resistance to this 
drug, due to the T-20 sequence being highly conserved, it 
might be possible to make T-20 drug variants to block any 
resistant virus which becomes a problem in practice. Much 
more research is needed, however, to find out to what extent 
T-20 resistance will occur in people, and to what extent this 
problem can be overcome.

Manufacturing and Supply

T-20 is a 36-mer peptide (a sequence of 36 amino acids). It 
is relatively easy to manufacture small amounts, enough for 
the initial clinical trials, by a technology called solid 
phase synthesis. Large quantities for major trials or for 
marketing will require a more difficult manufacturing 
process--either solution phase synthesis, or genetic 
engineering (creation of a genetically modified cell which 
produces the drug). Development is now proceeding on both of 
these approaches.

Use of an infusion pump to inject the drug continuously will 
greatly reduce the amount of T-20 needed. It is estimated 
that using the pump instead of twice-daily injections will 
allow the same amount of drug to treat up to 14 times as many 
patients, while maintaining the same minimum (trough) blood 
level. This is because T-20 has a relatively short half life 
in the blood, about 2.0 hours; if it is administered twice a 
day, a large excess must be given so that the required 
minimum blood level will still be present just before the 
next shot.

Toxicity

No toxicity of T-20 has been seen in human trials so far. In 
the laboratory, the drug inhibits HIV at concentrations 
10,000 to 100,000 lower than those harmful to cells.

T-20 does not enter cells, which further reduces the 
likelihood of toxicity. This is because drugs which get into 
cells have many more opportunities to create mischief than 
those which do not.

Clinical Trial Results

The only human results so far are from a phase I trial 
reported at the IDSA (Infectious Diseases Society of America) 
meeting September 1997 in San Francisco.(3) In this study, T-
20 was injected intravenously twice a day, for 14 days. Four 
different doses were tested: 3 mg, 10 mg, 30 mg, and 100 mg 
every 12 hours--and four volunteers received each dose. There 
was a clear dose response, with little viral load change at 
the two lower levels, a half log drop at the 30 mg dose, and 
at 100 mg, all patients became undetectable (a mean change of 
1.5 logs, but since the viral load became undetectable in 
every case, this number was the maximum possible in the 
design of this experiment; the drug clearly produced a larger 
change, but it could not be measured here). The average CD4 
count increased by 52 cells at the high dose, increased by 21 
cells at the 30 mg dose, and decreased at the two smaller 
doses.

In this trial the cutoff for undetectable viral load was 500 
copies. Later analysis with a more sensitive test found that 
none of the volunteers went as low as 50 copies. But since 
they started with an average viral load over 10,000, they 
probably could not have reached 50 copies in 14 days even if 
new infection was completely shut off, because of the time 
required to clear the virus from the body.

According to Trimeris, outside experts looked at the data and 
agreed that the speed of viral decline may be greater than 
any published results with combinations of RT (reverse 
transcriptase) and protease inhibitors. Of course this 
conclusion is tentative, since only four patients have yet 
been treated with the most active dose.

One factor that may have contributed to these results is that 
T-20 gets into the lymphatic system very well. This is where 
most of the virus is and most of its replication occurs. A 
second factor could be that T-20 blocks both mechanisms by 
which HIV enters a cell--virus to cell infection, and fusion 
of an infected cell with uninfected cells.

Clinical Trial Plans

Trimeris is about to start a larger trial at several sites. 
Forty patients who have failed at least one protease 
inhibitor combination will receive different doses of T-20, 
all of which are calculated to be effective. For 10 days they 
will use T-20 alone, so that the effect on the virus can be 
seen; then they will combine it with a new protease-inhibitor 
combination. After the first 10 days, the combination phase 
of this trial will last for 24 weeks--and after that, no one 
will be denied the drug if they want to continue it.

The first goal of this trial--in the first 10 days--will be 
to confirm the dose of T-20 when given subcutaneously with an 
infusion pump (the previous trial gave it intravenously twice 
a day). While the drug is likely to get into the serum and 
lymphatic fluid regardless of how it is injected, the dose 
must be checked because the twice-daily injections had huge 
peak levels of the drug. The available information for this 
and other antiretrovirals suggests that it is the trough 
level--the minimum blood level--which is important for 
controlling HIV, and that the extra drug in the peaks is not 
required. But with some antibiotics, the peak level, or the 
total amount of drug, does matter; therefore it is important 
to confirm quickly that a proper T-20 dose has been selected 
for continuous use.

Later trials being planned include a large phase II with 360 
patients, pediatric trials for children who have failed 
protease inhibitors, another large phase II trial in adults 
beginning HIV therapy, and a test of using T-20 for induction 
of combination treatment in patients with a very high viral 
load (to lower the viral load quickly in order to help avoid 
resistance to the protease inhibitors and other conventional 
treatments being started). There are also plans to test T-20 
as a topical microbicide for prevention of HIV transmission 
in discordant couples.

A number of possible short-course uses of T-20 have been 
discussed; these would be most important in the hopefully 
unlikely case that long-term use is not feasible, either 
because of side effects, development of antibodies which 
could make the drug ineffective, or manufacturing 
difficulties which delay production of an adequate supply. 
Such short-course uses could be for patients who have to go 
off all oral medications, for example due to surgery, or when 
oral medications cannot be absorbed temporarily because of 
other gastrointestinal problems; when a drug holiday from 
conventional treatments is necessary due to their toxicity; 
when viral load increases greatly due to an opportunistic or 
other infection; for prevention of maternal transmission, 
possibly in the first trimester if the inability of T-20 to 
get into cells reduces its risk to the fetus; and for post-
exposure prophylaxis (reducing the chance of HIV infection by 
short-term antiretroviral treatment shortly after accidental 
exposure).

Because the clinical research on T-20 is still in such an 
early stage, Trimeris does not expect to be able to file for 
marketing approval at least until the first quarter of 2000.

Technologies for Developing New Drugs Like T-20

Trimeris has two different technologies for creating or 
discovering new drugs with the same mechanism of action.

One uses a computer analysis of viral sequences to suggest 
new peptides which may be effective; these peptides can 
easily be manufactured in small quantities for initial tests. 
This methodology (called C.A.S.T.--Computerized Anti-Fusion 
Searching Technology(4)) has already been used to develop a 
drug which in the laboratory was 100 to 1000 times more 
powerful than T-20 against HIV. This particular compound, 
called T-1052, failed in animal studies, however, probably 
because it was inactivated by something in the blood. But 
even though this drug did not work, it illustrates the power 
of the methodology to design new sequences which are much 
better than the natural one found in the target virus--not 
surprising, since in the virus the binding must be weak 
enough to be reversible, while in a drug, the stronger it is, 
the better. T-20 may be the first example of a new area of 
drug development which is only now coming into view.

The other drug-development technology consists of laboratory 
tests to screen existing chemicals--usually small molecules, 
not peptides--to find any which happen to work like T-20. 
This screening procedure sets up a laboratory situation where 
T-20 binds to its target--a process which must happen 
naturally in HIV, aside from any treatment--and then 
determines if the chemical being tested can block this 
binding. Trimeris is beginning to screen chemical libraries, 
looking for potential drugs which could substitute for T-20, 
and might be orally available so that they would not need to 
be injected.

The Company

Trimeris currently employs about 45 people. It's scientific 
advisors include: Dani P. Bolognesi, Ph.D., whose laboratory 
at Duke University discovered T-20; Michael S. Saag, M.D., of 
the University of Alabama, who ran the phase I clinical 
trial; Joe Pagono, M.D., Chairman of the University of North 
Carolina Lineberger Comprehensive Cancer Center; Thomas 
Matthews, Ph.D., who discovered T-20; and Eric Hunter, Ph.D., 
chairman of the University of Alabama Center for AIDS 
Research. The president and CEO of Trimeris, M. Ross Johnson, 
has 25 years experience in major pharmaceutical companies.

Wall Street, however, has not been enthusiastic so far. 
Trimeris first issued stock last October, priced at 12.00. 
The price went up as high as 17, then down as low as 7, and 
at this writing is 8.

What seems to have happened is that the financial community 
has not understood what the company is doing. The only human 
data so far--the results of the phase I study--were presented 
at the IDSA conference last September; this happened during 
the SEC-mandated "quiet period," so the company was unable to 
explain these results or tell its story. Since then there has 
been no significant news about Trimeris or T-20, and no in-
depth background article about the company or its technology. 
Publication of the phase I trial is expected in the next few 
weeks.

References

1. Wild CT, Shugars DC, Greenwell TK, McDanal, CB, and 
Matthews TJ. Peptides corresponding to a predictive alpha-
helical domain of human immunodeficiency virus type 1 gp41 
are potent inhibitors of virus infection. PROCEEDINGS OF THE 
NATIONAL ACADEMY OF SCIENCES, USA October 1994; volume 91, 
pages 9770-9774.

2. Lawless MK, Barney S, Guthrie KI, Bucy TB, Petteway SR, 
and Merutka G. HIV-1 membrane fusion mechanism: Structural 
studies of the interactions between biologically-active 
peptides from gp41. BIOCHEMISTRY. 1996; volume 35, number 42, 
pages 13697-13708.

3. Saag M, Alldredge L, Kilby M, Venetta T, DiMassimo B, 
Lambert D, Johnson MR, and Hopkins S. A short-term assessment 
of the safety, pharmacokinetics, and antiviral activity of T-
20, an inhibitor of gp41 mediated membrane fusion. Infectious 
Diseases Society of America 35th Annual Meeting, San 
Francisco, September 13-16, 1997 [abstract #771].

4. Lambert DM, Barney S, Lambert AL and others. Peptides from 
conserved regions of paramyxovirus fusion (F) proteins are 
potent inhibitors of viral fusion. PROCEEDINGS OF THE 
NATIONAL ACADEMY OF SCIENCES, USA March 1996; volume 93, 
pages 2186-2191.


***** Adefovir Dipivoxil (PREVEON) Improved Expanded-Access 
Program

Gilead Sciences has significantly broadened the entry 
criteria for access to PREVEON(TM) (adefovir dipivoxil), an 
experimental antiviral being tested for treatment of HIV. The 
new program will no longer require specific viral load or CD4 
values, but is open to patients who have failed at least two 
nucleoside analogs and one protease inhibitor, who need new 
therapeutic options for treatment of HIV, and who are not 
excluded due to illnesses or laboratory values which raise 
safety concerns with the drug. This program resulted from 
discussions between Gilead and AIDS advocates, who wanted 
entry criteria based on the patient's overall medical 
condition, without automatic exclusions due to viral load or 
CD4 numbers (see AIDS TREATMENT NEWS #288, February 6, 1998).

The new program will also allow patients to either (a) be 
randomly assigned to the 60 mg or 120 mg dose, or (b) choose 
to be assigned to the higher dose. The drug is given as one 
tablet per day.

For more information about the expanded-access program for 
PREVEON, call 800-GILEAD-5 from 8:30 a.m. to 5:00 p.m. 
Pacific time.


***** Adefovir Dipivoxil (PREVEON) New Results with Hepatitis 
B, HIV

by John S. James

On April 6 Gilead Sciences released results of two clinical 
trials of adefovir dipivoxil (PREVEON(TM)) for the potential 
treatment of HIV, and another trial of adefovir dipivoxil at 
a lower dose (30 mg) for hepatitis B. The hepatitis trial 
(which used HIV-negative volunteers) was clearly a major 
success, with a reduction of hepatitis B viral load of 4 logs 
(99.99%) in the 12-week trial, with adefovir dipivoxil once 
daily as the only treatment.

The two trials of adefovir dipivoxil (PREVEON) for HIV both 
produced positive results; however, the sizes of the viral 
load and CD4 differences were small. It is possible that 
adefovir could be more important than the numbers indicate, 
since it is metabolized differently than nucleoside analogs, 
and may be effective in cells where those are not. However, 
the information released recently does not answer this 
question, which may be crucial for determining the role of 
the drug in HIV clinical practice.

One trial, called GS 411, assigned 85 treatment-naive 
patients to one of five regimens, all of which included 
indinavir (Crixivan(R)):

indinavir + adefovir + AZT, or

indinavir + adefovir + d4T, or

indinavir + adefovir + 3TC, or

indinavir + adefovir + AZT + 3TC, or

indinavir + AZT + 3TC. (The last one is a control regimen, 
including only standard treatments.) An interim analysis at 
20 weeks found all of these groups were equivalent in viral 
load decline (2.1 to 2.5 logs viral load drops in the 
adefovir groups, vs. 2.15 logs in the control group), 
suggesting that adefovir may substitute for some approved 
nucleoside analogs, while providing an easier regimen (one 
pill a day), different side effects, and different drug 
resistance.

The other HIV trial, GS 408, randomly assigned 442 volunteers 
who were already receiving anti-HIV treatment to add either 
adefovir or a placebo to their existing regimen. At 24 weeks 
the average viral load drop was -0.39 logs in the adefovir 
group vs. -.01 logs in the placebo group, a statistically 
significant difference--about a 0.4 log benefit from adding 
adefovir in these pre-treated patients.

Comment

Adefovir dipivoxil has advantages of easy administration, and 
activity against other viruses besides HIV (including 
hepatitis B, CMV, HHV6, and Epstein-Barr virus). Also, it 
could provide a new treatment option, which is important 
because patients are different and many are not succeeding 
with the available regimens.

A central question is whether this drug can contribute to 
*long-term* control of HIV. Adefovir dipivoxil is active in 
many cell types, including lymphocytes, monocytes, and 
macrophages, and it works in both resting and activated T-
cells. Even a small viral load drop compared to conventional 
treatment alone could be important, if this drop is accounted 
for by viral suppression in a small reservoir of cells not 
reached effectively by the other treatments, since otherwise 
these cells would allow HIV replication and therefore 
development of drug-resistant virus.

HIV drug development is moving too fast to wait several years 
to see which regimens give the best long-term suppression of 
HIV; a drug would already be obsolete by the time the answer 
is found. But a reasonable way to estimate long-term viral 
control, without waiting for a long time to see it, would be 
to look at how many patients reach a viral load below 20 
copies (or even less, as even more sensitive tests become 
available). It is known that if viral replication is almost 
completely shut off, patients are less likely to have a 
rebound of resistant virus, compared to those who only get 
slightly below the 400-copy quantification limit of the 
currently approved viral load test.

Therefore--assuming a regimen can be tolerated indefinitely--
the proportion of patients undetectable on the best viral 
load tests, at perhaps three months to a year, may be the 
best indicator of long-term antiretroviral activity, and 
important for determining the place of new treatment regimens 
in HIV clinical practice.


***** HIV/AIDS Nutrition Book for Clinicians

A CLINICIAN'S GUIDE TO NUTRITION IN HIV AND AIDS, written by 
three registered dietitians and peer-reviewed and published 
by the American Dietetic Association, is an authoritative 
guide that any AIDS medical professional should be familiar 
with and have available for reference. About half of the 178-
page book is easily readable narrative text, the other half 
is charts, tables, lists, patient worksheets, and references.

The major sections are: Overview and Nutritional Implications 
in HIV and AIDS; Nutrition Screening and Assessment; Oral 
Nutrition Interventions; Enteral and Parenteral Nutrition 
Strategies; Assessment and Intervention Issues in Various 
Health Care Settings; and the appendices: Glossary of 
HIV/AIDS Terminology; Nutrition Assessment; Selected In-
service Outlines; and Resources.

A CLINICIAN'S GUIDE TO NUTRITION IN HIV AND AIDS, by Cade 
Fields-Gardner, M.S., R.D., Cynthia A. Thompson, M.S., R.D., 
and Sara S. Rhodes, R.D., can be purchased through online 
bookstores, or ordered for $26 plus $5 shipping and handling 
from: The American Dietetic Association, P.O. Box 97215, 
Chicago IL 60678-7215; or call the ADA Customer Service, 
phone 800-877-1600, ext. 5000.


***** Treatment Conference Call May 2

People with HIV/AIDS and health-care professionals are 
invited to participate in a May 2 conference call at which 
they can ask questions of leading HIV/AIDS treatment experts.

The call, sponsored by the San Francisco AIDS Foundation and 
supported by an educational grant from Roche Laboratories, 
Inc., will take place Saturday, May 2, at 2:30 p.m. Pacific 
time (4:30 Central,, 5:30 Eastern). You must pre-register and 
reserve your place by calling 800-707-BETA; if space is 
available, you can pre-register up until a few minutes before 
the call begins. A recording of the call will probably be 
available later at 800-550-9235, and a transcript at 
www.sfaf.org/betalive.html.

Guest experts on this call will include Drs. Joel Gallant, 
Johns Hopkins University School of Medicine, David Hardy, 
UCLA School of Medicine, Robert Murphy, Northwestern Memorial 
Hospital, and Steven Becker, a San Francisco physician in 
private practice.


***** Geneva Conference Communication Proposals for 
Minorities Due May 12

"Non-profit organizations that provide services to people 
with HIV and AIDS are eligible to apply for funding for 
communications initiatives that extend the distribution of 
information and simplify data presented at the 12th World 
AIDS Conference being held in Geneva, Switzerland, June 28-
July 3. This nationwide request for proposals is a special 
funding opportunity issued by Glaxo Wellcome Inc." (Quoted 
from Glaxo Wellcome press release, April 9, 1998.)

 "Through the Request for Proposals (RFP) process, Glaxo 
Wellcome will fund a variety of communication initiatives, 
including treatment newsletters, which extend the 
distribution of information and simplify data presented at 
the international conference in Geneva. These initiatives 
should target African-American and Hispanic audiences. The 
number of grants and the amount of each grant will be 
determined during the proposal review process. Grant sizes 
are expected to range from $10,000 to $50,000."

This program is open to non-profit organizations in the 
United States.

The RFP was sent to more than 160 organizations. You can 
obtain a copy from Glaxo Wellcome's Health Care Coalitions 
office, 919-483-8584.


***** New Priority Email Delivery from AIDS TREATMENT NEWS

Starting with our next issue, AIDS TREATMENT NEWS will begin 
a priority email delivery service at no additional charge.

Subscribers with priority email delivery will receive an 
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newsletter. They will also receive their printed copies as 
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Priority email delivery is available for business and non-
profit subscribers. We will also "grandfather" individual 
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rate for at least one year.

To request priority email delivery, new or renewing business 
or non-profit subscribers need only include an email address, 
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there. Other subscribers should mail us their email address, 
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receive AIDS TREATMENT NEWS.

Subscribers with priority email delivery may ask us to send 
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If you have any questions about this service, call the AIDS 
TREATMENT NEWS office at 800-TREAT-1-2, or 415-255-0588, 
Monday through Friday 10 a.m. to 4 p.m. Pacific time.


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Treatment News does not recommend particular 
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