The discovery of antibiotics in the early part of 20th century and their spectacular
success in combating infections and deaths created a complacency during the 1960s
and 1970s. Over the past six decades, these ‘wonder drugs’ have played a critical
role in reducing the global burden of communicable diseases. This success was however,
overshadowed by the rapid backlash by the microbes resulting in a “relentless and
dizzying rise of antimicrobial resistance”1. We seem to have come a full circle from
the pre-antibiotic phase through a stage of euphoria to a seemingly frightening era
of patients infected with multidrug resistant bacteria desperate for the elusive magic
bullet2. In the recent past, especially, the emergence and spread of resistance in
several microorganisms have rendered the management of many infectious diseases difficult.
The problem
The wide and indiscriminate use of common anti-infective drugs has contributed substantially
to the persistence of infections, as a major cause of morbidity and mortality. Multidrug
resistant bacteria especially have emerged as a major health problem all over the
world3
4. Resistance poses a growing threat to the treatment and control of endemic, epidemic-prone
as well as pandemic diseases. Resistance in microorganisms costs money, livelihood
and lives and threatens to undermine the effectiveness of health delivery programmes
even in developed countries5. However, developing countries are hit hard with increasing
reports of development of resistance to drugs commonly used to treat most of the communicable
diseases. The emerging threat of resistance in malaria, tuberculosis (TB) and human
immunodeficiency virus (HIV) infection is a huge impediment in achieving the Millennium
Development Goals (MDGs) by 2015.
The genesis and factors responsible
Resistance in microorganisms is defined as their unresponsiveness to the standard
doses of drugs. Once developed, resistance is usually irreversible or very slow to
reverse. Resistance is a naturally occurring, continuous but slow phenomenon. However,
irrational use of antimicrobial agents accelerates this process and selects their
resistant sub-populations which soon become the dominating member of the species.
In fact, the more the usage of antibiotics, greater will the pace of emergence and
selection of resistant bacteria.
The irrational use comprises inappropriate prescriptions which may be because of absence
of standard treatment guidelines or physicians not adhering to these. It is estimated
that 50 per cent of prescriptions by qualified physicians are inappropriate1. The
WHO defines appropriate use of antibiotics as ”the cost-effective use of antibiotics,
which maximizes clinical therapeutic effect while minimizing both drug-related toxicity
and the development of antibiotic resistance”3. Even when the prescriptions are appropriate
the patient may not be able to procure the drugs because of high cost or poor access.
In developing countries an estimated 50 per cent of the those who need antimicrobials
cannot access due to cost6. Many a times these drugs are not taken by the patient
as per the recommended regimen or may be self administered when not required6. While
data are not available from developed countries, in industralized economies, of the
80-90 per cent of antibiotic consumption in the community, almost half is due to incorrect
indications, often viral infections7. Inexpensive and easily accessible testing facilities
are lacking both to distinguish between bacterial and viral infections and, if bacterial,
type the responsible species and its resistance pattern compounds the problem. In
poor countries, almost 50 per cent of the patients fail to adhere to recommended regimen
for various reasons including cost. Moreover, huge quantities of antimicrobials are
used in veterinary sector for therapeutic as well as non-therapeutic purposes3. In
some countries, more than 50 per cent of the national consumption of antimicrobials
is for promoting the growth of food animals6. All these factors have the potential
to provide an environment that selects out resistant subpopulations.
Antimicrobial resistance (AMR) now is far from being a local problem. It has international
ramifications. In modern era of travel and trade, resistant organisms rapidly cross
the man-made boundaries8 through humans or food chain. Resistant Salmonella species
have entered several countries through food9
10.
Situation of antimicrobial resistance in the South-East Asia (SEA) Region
Systematic studies to understand the epidemiology of antimicrobial resistance have
not been undertaken in the SEA Region. However, information and data available for
selected diseases/organisms show it to be a burgeoning and often neglected problem.
Resistance to first-line anti-TB drugs has become a concern for national TB control
programmes11. The population weighted mean of multi-drug resistant tuberculosis (MDR-TB)
in the Region is 208 per cent (1.9-3.6%) among new cases and 18.8 per cent (13.3-24.3%)
among previously treated cases11. It is estimated that around 180, 000 cases of MDR-TB
reside/occur annually in this Region with more than 80 per cent of these being in
Bangladesh, India, Indonesia, Myanmar and Thailand11. The drugs needed to treat MDR-TB
are over 100 times more expensive than the first-line drugs used to treat non-resistant
forms11. In some countries, the high cost of such replacement drugs is prohibitive,
with the result that some of the MDR-TB cases can no longer be treated11.
The generic antiretroviral (ART) drugs available in the Region are contributing greatly
towards improving the survival rate of patients worldwide and in rendering HIV as
a chronic but a manageable condition. Although the response to ART drugs is excellent
when these are delivered at health facilities12, there are reports of the emergence
of resistance13 that is a serious cause of concern.
There has been a substantial change in the antimicrobial susceptibility of Neisseria
gonorrhoeae. Thirty years back, gonorrhoea used to respond effectively to penicillin.
Now the resistance to penicillin and fluoroquinolones is widespread across the Region14.
Resistant malaria has already become a major issue for a population of 400 million
living in areas that expose them to a high risk of contracting it. Artemisinin-based
combination therapies (ACT) have recently been introduced in virtually all countries
in which malaria is endemic15. However, surveillance data from the Thai Ministry of
Public Health indicate that clinical failures of artemisinin-based therapies exist
in the Thai-Cambodian border, whereas efficacy with artesunate-mefloquine along the
western borders of Thailand remains high16.
Pentavalent antimonials (SbV) have been successfully used for treatment of kala-azar
since the last six decades. Since the 1970s, however, their conventional dosages have
failed to achieve the desired results with 60 per cent unresponsiveness being reported
with the WHO regimen in Bihar (India). Pentamidine initially used as a second-line
drug, acquired resistance (25%) even with prolonged dosage17. The newer oral drug,
miltefosine is a potent antileishmanial drug with a longer half-life, a property likely
to delay resistance17. The evolution of resistance to this drug will cause havoc to
the regional efforts to combat this disease.
Cholera bacilli have acquired resistance to a number of antimicrobials. The resistance
spectrum varies in different locales. In areas around New Delhi (India) extensive
resistance to furazolidone, co-trimoxazole and nalidixic acid has been noted18 while
tetracycline has remained effective. On the other hand, in Bangladesh, tetracycline
resistance has been found to be frequent in prevalent Vibrio cholera.19
Streptococcus pneumoniae is the most common causative agent of pneumonias in children
and adults in Asia20. Till the1980s, almost all isolates of this organism used to
be susceptible to penicillin. In 2006, in a hospital in Thailand, almost 69 per cent
isolates of this bacterium were found to be penicillin resistant21.
Typhoid and paratyphoid fever continue to be important causes of illness and death,
particularly among children and adolescents in the SEA Region where this disease is
associated with poor sanitation and unsafe food and water. Shortly after the emergence
of multidrug-resistant S. Typhi in this Region, case fatality rates approaching 10
per cent (close to 12.8% recorded in pre-antibiotic era) were reported22.
More than 50 per cent isolates of Staphylococcus aureus in hospital settings are now
methicillin resistant. In a study undertaken in a 1000 bedded hospital in Thailand,
48 per cent patients with bacteraemia due to resistant S. aureus died23. Methicillin-resistant
S. aureus (MRSA) is a major problem in hospital-associated infections in almost all
countries in the SEA Region24.
Multiresistant klebsiellae, Pseudomonas and Acinetobacter species have given new dimensions
to the problem of hospital-associated infections. A. baumannii has become an important
pathogen in intensive care units. In a study done in Thailand, mortality in admitted
patients due to imipenem-resistant A. baumannii was 52 per cent as compared to 19
per cent in those who were infected with the sensitive variant25. Presence of a drug
resistant gene bla
NDM-1 in several members of the family Enterbacteriaceae has given rise to organisms
that are resistant to a large number of commonly used antimicrobial agents26.
Several salmonellae were isolated from chicken carcasses imported into Bhutan, 40
of 42 Salmonella enteritidis exhibited resistance to more than 2 drugs9. From clinically
healthy cows in Thailand, 68 per cent of isolates of S. enterica were resistant to
at least one antimicrobial and 6 per cent were multiresistant27. A spread of multiresistant
S. schwarzengrund from chickens to humans in Thailand and from imported Thai food
products to persons in Denmark and the United States has been well documented10.
Consequences of AMR
AMR has several and severe consequences. The patient remains sick for a longer period
thus requiring prolonged treatment usually with expensive and at times toxic drugs.
Not only there is greater morbidity and mortality but the burden on health system
also increases. The impact of modern technological and complex surgeries gets negated
when the patient after successful intervention gets infected with resistant microorganisms.
From the public health perspective, the patient acts as a reservoir of infection for
a longer period thus putting at risk more members of community and health care workers.
All these have substantial effect on economy at individual and societal levels. In
fact, it is difficult to imagine effective newer surgical procedures, transplantations,
prolonged chemotherapy for various cancers, care of critically ill young and the old,
or prolonged treatment of the HIV-infected in the absence of measures towards effective
containment of AMR.
The need for new antibiotics
The need for new antibiotics to address the emerging resistance microorganisms cannot
be overstated. A recent analysis by the European Centre for Diseases Prevention and
Control and European Medicine Agency suggests of a near-empty antibiotic pipeline28.
Only one or two drugs are under development that too in very early stages5. This is
primarily because the industry is reluctant to invest in new antimicrobial drug development.
There are various reasons for this some of which include5 (i) use of equally effective
generic antibiotics for most infections as first line of treatment and use of new
antibiotics generally as the last resort; (ii) antibiotics are used only for short
duration as they are primarily used for curative purpose as compared to the drugs
for chronic conditions used over long periods, even for a life time; (iii) emergence
of rapid drug resistance rendering the antibiotic ineffective and hence less life
span and lower returns on investment; (iv) difficulty in recruiting and conducting
clinical trials due to several gray areas; and (v) relatively more regulatory hurdles
for clinical trials. In fact all the global policies have consistently advocated the
containment of resistance, rational and restricted use of antibiotics which are not
industry-friendly.
There is some light at the end of the tunnel with some significant new initiatives.
Some antimicrobial agents are under development and awaiting approval of the Food
and Drug Administration, USA2. The European Commission has sought proposals for new
antibiotic R&D for multidrug resistant Gram negative pathogens that was quickly followed
with a joint EU-US Transatlantic Taskforce on Antimicrobial Resistance. Many other
incentives to the industry to encourage antibiotic development are under various stages
of global discussions29. As the overall returns of investments on antibiotics is never
likely to touch a typical blockbuster drug for the large manufacturers, a model that
could be considered is to engage small and medium pharmaceutical companies and develop
antibiotics on a product development partnership models somewhat akin to those suggested
for the development of drugs for neglected diseases. Public funding for new antibiotic
R&D even in the rich countries has been negligible until recently. The call by the
Infectious Diseases Society of America for a 10x20 initiative viz., development of
10 new antibiotics by 202030 should trigger new R&D by the pharma companies.
The future
We should recognize that the emergence of antimicrobial resistance is an inevitable
consequence of the use of these life saving agents. And that the tools available are
remarkably few and the pipeline for new products is near dry and it will be some time
before new antimicrobials will become available. The emergence of the superbugs as
the NDM 1 once again underscores the need for vigilance at community, local and national
levels for the constant monitoring of AMR. There is a clear need for concerted action
from all concerned in academia, hospitals and other health care settings, industry
and the governments to work together in combating the emerging AMR, a cross cutting
problem. Action is required on better diagnostics, educating the care givers and patients
of the need for rational prudent use of antibiotics, work towards standard treatment
protocols, dosage regimens and treatment durations. The problem of resistance is complex
and encompasses biological, behavioural, technical, economic, regulatory and educational
dimensions that require a comprehensive response.
A critical issue at the Regional level is the need for and difficulty in taking effective
measures as the responsibility for health remains essentially a national problem.
Accordingly, it requires ownership and active participation by several stakeholders,
and a strategic approach with objectives that include establishment of a national
alliance for prevention and control of antimicrobial resistance; institution of a
surveillance system that captures the emergence of resistance, as well as the trends
of its spread; and the utilization of antimicrobial agents in different settings;
promotion of rational use of antimicrobial agents at all levels of health care and
veterinary settings; strengthening infection control measures to reduce the disease
burden; and supporting basic and operational research. The SEARO/WHO has recently
developed one such strategy31.
Four areas which will need attention of national authorities pertain to governance,
regulatory mechanisms, building national capacity in this area and mobilizing active
participation of communities. A governance mechanism comprises establishment of a
national alliance against AMR, designation of national focal point and establishment
of a multi-sectoral National Steering Committee to guide national efforts.
The development and application of standard treatment guidelines in health and veterinary
sectors, banning non-therapeutic use of drugs in animals and imposing restrictions
on over-the-counter sale of antimicrobial agents are major activities for national
regulatory agencies. Building core national capacity for monitoring antimicrobial
use and resistance through national surveillance networks, rational use of antimicrobials
by the prescribers, in reducing disease burden and undertaking appropriate operational
research is critical. Finally educating communities for promoting adherence to recommended
regimen and discouraging self prescription are equally important steps in mankind’s
fight against AMR. At the country level, there is a need to integrate infection surveillance,
prevention and control strategies and regulate and promote rational use of antibiotics.
International agencies are also gearing up to combat this problem but some co-ordination
towards orchestration of these global efforts could help. Recognizing the emerging
importance of this subject and to enhance its visibility for an early action, “Antimicrobial
Resistance” shall be the theme of World Health Day 2011. Far too long, antimicrobial
resistance has been an unrecognized and neglected problem. The time to act is now.