Hernia is a common disease that can affect any body from his childhood to old age. Operation is the only remedy to get relief from this disease. Patient will not mind to get operated if he is sure that he is going to be hernia free after surgery. But this does not happen in many patients because rate of relapse or reappearance of hernia at the same place is also quite high and unacceptable. Different surgeons recommend different operations to repair the hernia. Therefore, there is confusion in the mind of patients as to which operation they should prefer for their hernia surgery. This article gives details of different types of groin hernia operations done worldwide for knowledge of those patients.

Groin anatomy in hernia patients: All the vessels, lymphatics, vas, nerves along with their covers, together called as spermatic cord pass from abdomen to scrotum through inguinal canal. A protrusion of peritoneum called as hernia sac appears in this canal along with the cord and goes on increasing in size if this hernia sac is kept untreated. This canal and cord is normally protected by cover of two muscles behind and one muscle in front. The reason why hernia sac formation takes place is the weakness in those two muscles behind. This weakened spot in the posterior wall is called as weak spot or hernia hole. All traditionally done operations are designed to repair this hernia hole so that there is no recurrence of hernia after surgery.
There are two parts of hernia operations. First part is to separate the hernia sac and excise it. Second part is to repair this weak spot or hernia hole so as to prevent any recurrence in future.

Bassini Shouldice operation: In this operation patient is kept in the hospital for 2-4 days.
General or spinal anaesthesia is given. Hernia sac is excised. Then for repair of hernia hole, back two muscles are pulled down and sutured to the groin ligament. Surgeon takes several stitches so as to keep these pulled down muscles in place. There is tension on those stitches so patient has to take care for life time to avoid disruption of sutures. Unfortunately, this tension on muscles cause pain in groin area and prolonged rest needs to be taken to get relief and then only he can go to his routine work. There is more than 10% recurrence rate in this operation and increases with time because of contraction of the scar tissue adding more tension on the sutures. This results in more incidences of recurrences and groin pain. Repeat operation for recurrence or pain is difficult and bigger and the results are also far from satisfaction.
Some surgeons use another modification of this technique to reduce tension on the stitches. They suture back muscles and fascia in 4 layers. This reduces the tension on the muscles and sutures but for that many more complicated sutures are needed to be taken. Therefore, this operation can be done only by expert and specially trained hernia surgeons. This has brought down the recurrence rate but it has not totally disappeared. This operation is grouped under �tension repairs� because there is tension on the stitches and muscles.

Mesh repair: In this operation no muscles are pulled down to cover the hernia hole. Instead, mesh is sutured on the weak spot to cover the hernia hole. This mesh is a piece of synthetic cloth just like a mosquito net and it is in no way some thing special. There is no tension on the stitches so this operation grouped under �tension free repair�. This has reduced the recurrence rate to a great extent (7-8% in USA) but it did not disappear completely. Reduced recurrences and simplicity of operation made it popular immediately all over the world. The mesh per se does not give any protection because it is delicate. But because it is a foreign body stitched inside, foreign body reaction starts and a tissue curtain is formed just like a corn following the thorn prick. This takes 4-6 months to form the curtain. It takes another 2-3 years to gain strength in this curtain. So, practically patient remains without protection for 2-3 years after surgery and if patient gets an attack of cough or sneezing during this period then there are increased chances of recurrence.
Contraction of this scar tissue adds more to the chances of recurrence. Involvement of nerves, vas or other structures in this scar formation results in to groin pain in 28 to 42% of operated patients. Tearing of sutures, disintegration of mesh, infection, migration are all noted complications. The mesh used by many surgeons is of low quality to save on the cost. Such meshes contract more than 50-60% naturally causing more recurrences. All above complications following mesh repair requires repeat surgery and this surgery is quite difficult and commanding even in the hands of hernia expert surgeons and the results are also poor.

Laparoscopic repair: This operation is done by inserting endoscopes inside by making 4 holes on the abdomen. General anaesthesia is given. Co2 gas is pumped in side the abdomen to inflate it. A much larger size of mesh is required to be stitched to cover the hernia hole from inside the abdomen. It is claimed that there is less pain following this surgery and patient can go to his work earlier. This operation can be done by inserting endoscopes to hernia site through abdominal wall instead of entering the abdominal cavity. This operation can be done only by experts in doing such surgery. More recurrences are seen if done by a novice surgeon. There are more risks involved in this surgery like general anaesthesia, pumping Co2, or trauma to intestines etc. Costly equipments, bigger mesh and expertise required to do this risky operation increase the cost of surgery.

Dr. Desarda repair: This operation is done by taking a cut on the skin. It is simple and does not
require any foreign body like mesh or any complicated instruments like endoscopes. A strip of a nearby muscle is separated and stitched on the weak spot to cover the hernia hole. There is no foreign body like mesh or no endoscopes are required therefore, this operation is free from all complications and risks that are associated with the mesh or laparoscopic repair. There is no tension on the stitches or muscles as seen in Bassini-Shouldice operation. Therefore, there are no complications and risks that are associated with the Bassini- Shouldice operation. Hernia hole is covered by a strong muscle. Therefore, protection starts on the operation table itself. Patient is admitted in the morning and immediately taken for surgery after preparation. Operation is done under local or spinal anaesthesia. No general anaesthesia is required. Operation is completed in 30 minutes and patient is back on his feet as soon as anaesthesia effect is gone. Patient goes to bathroom on his own within couple of hours and moves freely in the wards afterwards and is ready to get discharged same day night or next day morning. Patients are allowed to drive car and go to office, bend, squat, climb up the staircase or carry luggage and travel. All foreign patients coming to Indian Hernia Institute go back to their country on third day carrying their luggage and a journey of 20-22 hours without any difficulty. The most important quality of this operation is that there is virtually no recurrence or pain. This operation is spreading quite rapidly all around the globe and today it is being followed in many countries.

Interested patients and doctors can contact Dr. Desarda on his mobile no. 0091 (0)9373322178 or log on to his website http://desarda.webs.com or http://herniasurgery.tripod.com

I received a comment - Quote from

"Mr. Vinod Kumar Singhal
on Wednesday, 21st-April-2010 at 6:03 PM

Basically I am Metallurgist/Scientist but for last 16 years I am associated with Acupressure Therapy and following Foot Reflexology and getting very good results in all types of diseases including psycho cases.Some of the Dr's and hospitals rfering the hopeless cases to us. Mr.Sunil Dutt, Actor and MP had been our One of successful and satisfied patient.
In our opinion Acupressure is much better than Acupuncture and have no side effects.
vinod singhal,Mumbai"

Acupressure is one of the several modalities of Acupuncture such as Moxibustion, Press Tags, Hot Needle, LASER and Electro Acupuncture. Acupressure is absolutely safe and follows the TCM paradigm of 5 Elements & 10 stems with palpation as a main diagnostic modality. It uses the meridian channels and points to tonify or disperse Qi and Blood. The basic pattern recognition and balancing Yin and Yang applies to acupressure. The beauty of Acupressure is that a TCM Acupuncturist Doctor can teach a few pressure points to the patient for home treatment especially in cases with Carpal Tunnel Syndrome, Tourettes and certain chronic pain cases.

The ancient Indian custom of Ear Piercing is an example of Auricular Acupressure on the Ear. It boosts the brain power and re-balances the Yin & Yang in a child. The idea stems from the discovery of Homunculus structure of the body in the Ear by Dr. Nogier of France considered to be the father of modern auricular acupuncture.

Interestingly there are points in the Ear that can be used to Jump Start the brain such as Jerome Point is for relaxation that boosts performance. This can be suitably used by students before taking a competitive exam without taking any designer drug. Even race horses respond well to Jerome Point and win races! Certain addictions can be treated with Ear acupressure to stop the craving. In many states in the US people convicted for Addiction are given two options - Option 1 - Acupuncture or Option 2 - Jail.

My congratulations to Mr. Singhal and his team for the good work and humane services that they extend to patients. My suggestion will be to include all modalities of Acupuncture to be a full service TCM clinic.

MedAku Contacts - You can reach me in my cell +91 81220 62636.

Bedsores - A comprehensive review.

Gurvinder Singh Sandhu*, Gourishankar Patnaik**

Introduction: One of the most nagging and frustrating problems in long term patient care is decubitus ulcer or commonly referred as Bed Sores. The problem becomes more compounded in cases of Diabetes Mellitus where there are problems ranging from delayed tissue healing to various biochemical changes that virtually frustrates every attempt to treat these patients. Proper Nursing Care is what is stressed up on.

According to www.medterms.com , Bed sore is defined as a painful often reddened area of degenerating, ulcerated skin caused by pressure and lack of movement, and worsened by exposure to urine or other irritating substances on the skin. Untreated bed sores can become seriously infected or gangrenous. Bed sores are a major problem for patients who are confined to bed or a wheelchair. They can be prevented by moving the patient frequently, changing bedding, and keeping the skin clean and dry. Synonyms include pressure sore, decubitus sore, or decubitus ulcer.



In a study conduced by the Healthcare Cost and Utilization Project (HCUP-USA) titled Hospitalizations Related to Pressure Ulcers among Adults 18 Years and Older in the year 2006 it was found that there were a total of 503,300 hospitalization with pressure ulcers noted as a diagnosis which is an increase in 78.9% since 1993 when there were about 281,300 hospitalization due to the same. Adult hospital stays bearing a diagnosis of pressure sores totaled up in 11.0 billion US Dollars in hospital bills in the year 2006 alone. (2)

Amongst others �highlighted� in the published report were: (2)

� Of the total admission, more than 90% of patient (among adults) with pressure ulcer related hospitalization were actually intended for other medical conditions like septicemia, pneumonia, and urinary tract infection to name a few.
� In comparison to hospital stays due to other medical conditions, pressure ulcers patients were more often discharged to a long-term care facility and are more likely to result in death in coming years.
� Almost every three out of four adult patients hospitalized with a secondary pressure ulcer diagnosis 72% were 65 years and older. On the contrary, adult patients with a principal diagnosis of pressures ulcers 56.5% of them are 65 or older.
� Moreover, the younger adults that are hospitalized primarily due to pressure ulcers often go hand in hand with paralysis and spinal cord injury.





Risk-factors

There are numerous risk factors listed below in development of pressure sores. (3)

� Prolong immobility :
Paraplegia
Arthritis
Operation and postoperative states
Plaster casts
Intensive care
� Decrease sensation :
Coma
Neurological disease or deficits
Diabetes Mellitus
Drug Induced Sleep
� Vascular Disease :
Atherosclerosis
Diabetes Mellitus
Scleroderma
Vasculitis
� Poor Nutrition :
Anaemia
Hypoalbuminemia
Vitamin C or Zinc deficiency




As the saying goes prevention is better than cure, after years of study on the topic per-say, several risk assessment tools have been devised for the immobile patient based on the known risk factor such as the �Norton scale�, and �Waterlow Pressure Sore Risk Assessment� are 2 validated systems which produce a numerical sore I while enabling staff to identify those at most risk. The table below depicts �Norton Scale�.


In recent days �Brandon Scale� for predicting risk for pressure ulcers is being used by many health care set-ups. Brandon�s scale is divided into six risk categories: sensory perception, moisture, activity, mobility, nutrition, friction and shear. The best possible interpretation is a score of 23 whilst the worst is a 6. If the total score is below 11, the patient is at risk for developing bedsores.
The patho-physiology & staging
Bedsores are predisposed by 5 main factors: pressure, injury, anaemia, malnutrition and moisture. (6) There are 3 main etiology for pressure ulcers to develop are namely:
1. Compression between bony prominences and contact surfaces, as when a patient remains in a single decubitus position for a prolonged period of time which will lead to decreased tissue perfusion, ischemia occurs and resulting in tissue necrosis
2. Friction  rubbing against bed linen or patient�s gown.
3. Shearing forces. It�s the force that is created when skin of a patient stays in one place as the deep fascia and skeletal muscle slide down with gravity leading to pinching off of blood vessels which eventually ends up with tissue necrosis.
Infuriating the situation may be other conditions such as excess moisture from incontinence, perspiration or exudates where in elapse of time this excess moisture may deteriorate the bonds between epithelial cells resulting in the maceration of the epidermis.
At present there are two major theories about the development of pressure ulcers. The first and most accepted is the deep tissue injury theory which claims that the ulcers begin at the deepest level, around the bone, and move outward until they reach the epidermis. The second, less popular theory is the top-to-bottom model that says that skin first begins to deteriorate at the surface and then proceeds inward.
The results of all this will eventually lead to erosion, tissue ischemia, and finally infarction over the site. The most common sites where bed sores most frequently build up is over the sacrum, ischial tuberosities, trochanters, malleoli, and last but non the least the heels. It is not necessarily for the ulcers to only develop at these areas but they can develop elsewhere, including behind the ears when nasal cannulae are used for prolonged periods. Poorly fitting prosthetic devices are also grounds for pressure ulcers to develop over bony prominences. Increased force and duration of pressure directly influence risk and severity.
Pressure sores can as little as 3 to 4 hours to develope in some settings (for example trauma patients who are immobilized on rigid spine-immobilization boards) and these ulcers worsen when skin is overly moist and macerated (e.g., from perspiration or incontinence).
In February 2007 the National Pressure Ulcer Advisory Panel (NPUAP) added unstageable pressure ulcers on to the list of the already existing original 4 stages which are further described below.
Stage I: Intact skin, non-blanchable redness of a localized area usually over a bony prominence. The area may be painful, firm, and soft, with local temperature change as compared to adjacent tissue. It may be difficult to detect this stage in individuals with darker skin tones.
Stage II: Partial thickness loss of dermis presenting as a shallow open ulcer with a red pink wound bed, without slough. Patient in this stage may also present as an intact or open/ruptured serum-filled blister. Presentation is of a shiny / dry shallow ulcer without slough or with bruising which may very well be deep tissue injury. Conditions like skin tears, tape burns, perineal dermatitis, maceration or excoriation should not be mistaken and described in this stage.
Stage III: In this stage pressure ulcer varies by anatomical location. There is full thickness tissue loss with visible subcutaneous fat but bone, tendon or muscles are not exposed or palpable. Slough may be present but does not obscure the depth of tissue loss with possibility of undermining and tunneling. Areas that do not have subcutaneous tissue namely the nose-bridge, ear, occiput and malleolus shows shallow ulcer. On the contrary areas with significant adipose tissue can develop extremely deep stage III pressure ulcers.
Stage IV: In this stage there is full thickness tissue loss with exposed bone (visible and palpable), tendon or muscle with presence of slough over the wound bed with significant undermining and tunneling. Osteomyelitis may transpire in tandem of this stage as ulcers can extend into muscle and/or supporting structures namely fascia, tendon or joint capsule.
Unstageable: Full thickness tissue loss in which the base of the ulcer is covered by slough and/or eschar in the wound bed if and until the debris are removed to expose the base of the wound, the true depth, and therefore stage, cannot be determined.



Prevention
One must bear in mind that bedsores are easier to thwart than to treat. A task is never easily achievable even if it�s the smallest of task need work, the same goes here although wounds can develop in spite of the most scrupulous care, it's possible to prevent them in many cases. First and foremost, the treating physician needs to devise a plan that is comprehendible and easy to follow by caregivers. The cornerstones of such a plan include position changes along with supportive devices, daily skin inspections and a maximally nutritious diet further explained below.
Position changes:  As mentioned before it takes a mere 2-3 hours for a sore to develop over immobilized area hence changing of posture has to be frequent (experts claims to shift position every 15 minutes) and consistent as it�s crucial to prevent bedsores. If one is wheelchair bounded he/she should reposition 2 hourly. When night falls a caregiver should be there to assist a bed ridden patient to change position. Some guidelines that are readily available by some physician on position change are as listed:
� Lie at a 30-degree angle so to avoid lying directly on hipbones..
� When in supine position a head size sleeping pillow should be kept from below knee onwards supporting calf and up to the heel.
� Try to avoid contact between knees and ankle using a foam pad or pillow..
� A higher incline head of the bed makes it more prone that one will slide down, where in there will be friction and shearing injuries.
� A pressure-reducing mattress / bed should be used as there are many options readily available in market stores including foam, air, gel or water mattresses.
� Pressure-release wheelchairs have recently been introduced in the market where in it functions to redistribute pressure hence making sitting for long periods easier and more comfortable. All wheelchairs need cushions in order to reduce pressure and provide maximum support and comfort.
Skin inspection  Skin should be inspected thoroughly at least once a day for pressure sores as its fundamental part of prevention. Inspect your skin thoroughly at least once a day, using a mirror if necessary. Special attention are to be paid to these areas hips, spine and lower back, shoulder blades, elbows and heels if a patient is bed ridden. When in a wheelchair, look especially for sores over the buttocks and tailbone, lower back, legs, heels and feet If an area of your skin is red or discolored but not broken, keep pressure off the sore, wash it gently with mild soap and water, dry thoroughly, and apply a protective wound dressing. If there is visible skin damage or any sign of infection such as drainage from a sore, a foul odor, and increased tenderness, redness and warmth in the surrounding skin, get medical help immediately.
Nutrition &#61664; Malnourished populaces are the ones highly predisposed to bed sores. It's crucial to get enough calories, protein, vitamins and minerals in preventing skin breakdown and in aiding wound healing. Markers of under nutrition include albumin < 3.5 mg/dL or weight < 80% of ideal. Protein intake of 1.25 to 1.5 g/kg/day is desirable for optimal healing. Zinc supplementation supports wound healing, and replacement at a dose of 50 mg thrice daily may be useful. Supplemental vitamin C 1 g/day may be provided. Providing a drink of water to patients at each repositioning may be useful to aid hydration.
Lifestyle changes including cessation of smoking as tobacco use damages skin and slows wound healing as on the other hand exercise improves circulation, helps builds up vital muscle tissue strengthen the body overall.

Treatment
The 1994 consensus guidelines provide a brilliant approach to the rational treatment of pressure ulcers. Listed below are the general summaries indicating steps necessary in management of this important issue.
Debridement of necrotic tissue can be done through a variety of potential techniques, which aids in healing of the wound. Several different debridement techniques are available.
� Sharp debridement is used in critical situations like cellulitis where in devitalized tissue are removed..
� Mechanical debridement where Hydrotherapy (whirlpool baths), ultrasound, medical maggots, wound irrigation, or dextranomers are to be used to remove thick exudates and loose necrotic tissue. Urgent debridement is indicated in advancing cellulitis or sepsis. Wounds with very loose exudates- debridement with wet-to-dry dressings can be done but only with utmost care as it is often painful and it may remove healthy tissue.
� Enzymatic debridement involves applying topical debriding agents to remove devitalized tissue using collagenase, papain, fibrinolysin, or streptokinase.
� Autolytic debridement requires the use of synthetic dressings that allow devitalized tissue to self-digest from enzymes present in wound fluids. DuoDERM or Contreet (which is impregnated with silver and thus offers antimicrobial effects) are commonly applied.
Wound cleansing using a 30 ml syringe and a 18 gauge angiocatheter will provide sufficient force to remove eschar, bacteria, and other debris from the wound site. Initially wound should be cleansed with normal saline and not using solutions that are cytotoxic in nature, such as povidone iodine, sodium hypochlorite solution and hydrogen peroxide, should be avoided to avoid further damage to tissue.
Treatment of Infected sites following the procurement of swabs from the area which are immediately sent for culture n sensitivity test. Conventionally first line therapy should cover gram-positive skin organisms, such as the use of a first-generation cephalosporin (e.g. Cephalexin 250-500 mg po qid). If the clinical picture is suggestive and/or swab results are confirmatory, consideration for antipseudomonal coverage should be made. Broader coverage should be emperically instituted in diabetic patients.
Dressing selection should be based on its ability to keep ulcer tissue moist and the surrounding intact skin, dry. Multiple types of dressings are available, and the choice should be based on clinical judgement. Objectives are to keep the ulcer bed moist to retain tissue growth factors while allowing some evaporation and inflow of oxygen, to keep surrounding skin dry, to facilitate autolytic debridement, and to establish a barrier to infection. Adjuvant therapy and /or operative repair are made on a case-by-case basis. Modes of operation include electrical stimulation, hyperbaric oxygen and laser irrigation. Electrical stimulation is only recommended for stage III and IV pressure ulcers. The table below tabulates the different options of dressing available for pressure ulcers.





Conclusion
Pressure ulcers are a preventable and treatable medical problem. Proper management of this problem can result in significantly improved quality of life and shorter hospital stays for elderly patients. When ulcers do develop, a multidisciplinary approach to treatment is recommended.

*Final year Medical student
**Professor of Orthopedics ,Melaka Manipal Medical College, Melaka

N.B.This article is a product of a project given to one of the final year medical student as an exercise to make medical students and future doctors aware of their responsibility to treat preventable conditions like bed sores.
It comprehensively deals with the types, pathophysiology and necessary treatment regimens of this condition which is an indicator of nursing standards in a given setting.

References
1. Bedsores definition. http://www.medterms.com/script/main/art.asp?articlekey=11035
2. Russo C.A., Steiner C., Spector W. Statistical Brief # 64 Healthcare Cost and Utilization Project �Hospitalizations Related to Pressure Ulcers among Adults 18 Years and Older, 2006.� http://www.hcup-us.ahrq.gov/reports/statbriefs/sb64.jsp
3. Kumar P., Clark M. Kumar & Clark Clinical Medicine Textbook 6th edition. Elsevier Saunders 2005
4. Russel R.C.G., William N.S., Bulstrode C.J.K. Bailey & Love Short Practice of Surgery 24th Edition. Hodder Arnold 2004.
5. Wolff K., Goldsmith L. A., Katz S.I., Gilchrest B.A., Paller A.S., Leffell D.J., Fitzpatrick's Dermatology in General Medicine, 7th edition McGraw-Hill Professional 2008.
6. Niezgoda JA, Mendez-Eastman S (2006). "The effective management of pressure ulcers". Adv Skin Wound Care 19 Suppl 1: 3�15. doi:10.1097/00129334-200601001-00001. PMID 16565615. http://meta.wkhealth.com/pt/pt-core/template-journal/lwwgateway/media/landingpage.htm?an=00129334-200601001-00001
7. Support surfaces for pressure ulcer prevention by McInnes E, Cullum NA, Bell-Syer SEM, Dumville JC. http://www.cochrane.org/reviews/en/ab001735.html
8. Cervo FA, Cruz AC, Poscillico JA. Pressure ulcers: Analysis of guideline for treatment and management. Geriatrics. Mar 2000;55:55-60.
9. Pieper B. Mechanical Forces: Pressure, shear, and friction. In: Bryant RA. Acute and Chronic Wounds: Nursing Management, Second Edition. Mosby, Inc., 2000
10. Bergstrom N, Bennet MA, Carlson CE et al. Treatment of Pressure Ulcers. Clinical Practice Guideline, No 15. Rockville, MD. US Department of Health and Human Services. Public Health Service, Agency for Health Care Policy and Research. AHCPR Publication No. 95-0652. December, 1994.
11. Malone J.R., McInnes E. Pressure Ulcer Risk Assessment and Prevention. Royal College Of Nursing U.K. April 2001
12. Bedsores. Mayo Clinic. http://www.mayoclinic.com/health/bedsores/DS00570/DSECTION=symptoms
13. Encyclopedia for surgery. Bedsores. http://www.surgeryencyclopedia.com/A-Ce/Bedsores.html

Why Most Published Research Findings Are False

Published research findings are sometimes refuted by subsequent evidence, says Ioannidis, with ensuing confusion and disappointment.

John P. A. Ioannidis

Summary

There is increasing concern that most current published research findings are false. The probability that a research claim is true may depend on study power and bias, the number of other studies on the same question, and, importantly, the ratio of true to no relationships among the relationships probed in each scientific field. In this framework, a research finding is less likely to be true when the studies conducted in a field are smaller; when effect sizes are smaller; when there is a greater number and lesser preselection of tested relationships; where there is greater flexibility in designs, definitions, outcomes, and analytical modes; when there is greater financial and other interest and prejudice; and when more teams are involved in a scientific field in chase of statistical significance. Simulations show that for most study designs and settings, it is more likely for a research claim to be false than true. Moreover, for many current scientific fields, claimed research findings may often be simply accurate measures of the prevailing bias. In this essay, I discuss the implications of these problems for the conduct and interpretation of research.

John P. A. Ioannidis is in the Department of Hygiene and Epidemiology, University of Ioannina School of Medicine, Ioannina, Greece, and Institute for Clinical Research and Health Policy Studies, Department of Medicine, Tufts-New England Medical Center, Tufts University School of Medicine, Boston, Massachusetts, United States of America.

_______________________________________
Published research findings are sometimes refuted by subsequent evidence, with ensuing confusion and disappointment. Refutation and controversy is seen across the range of research designs, from clinical trials and traditional epidemiological studies [1�3] to the most modern molecular research [4,5]. There is increasing concern that in modern research, false findings may be the majority or even the vast majority of published research claims [6�8]. However, this should not be surprising. It can be proven that most claimed research findings are false. Here I will examine the key factors that influence this problem and some corollaries thereof.


Modeling the Framework for False Positive Findings Top

Several methodologists have pointed out [9�11] that the high rate of nonreplication (lack of confirmation) of research discoveries is a consequence of the convenient, yet ill-founded strategy of claiming conclusive research findings solely on the basis of a single study assessed by formal statistical significance, typically for a p-value less than 0.05. Research is not most appropriately represented and summarized by p-values, but, unfortunately, there is a widespread notion that medical research articles should be interpreted based only on p-values. Research findings are defined here as any relationship reaching formal statistical significance, e.g., effective interventions, informative predictors, risk factors, or associations. �Negative� research is also very useful. �Negative� is actually a misnomer, and the misinterpretation is widespread. However, here we will target relationships that investigators claim exist, rather than null findings.


It can be proven that most claimed research findings are false


As has been shown previously, the probability that a research finding is indeed true depends on the prior probability of it being true (before doing the study), the statistical power of the study, and the level of statistical significance [10,11]. Consider a 2 � 2 table in which research findings are compared against the gold standard of true relationships in a scientific field. In a research field both true and false hypotheses can be made about the presence of relationships. Let R be the ratio of the number of �true relationships� to �no relationships� among those tested in the field. R is characteristic of the field and can vary a lot depending on whether the field targets highly likely relationships or searches for only one or a few true relationships among thousands and millions of hypotheses that may be postulated. Let us also consider, for computational simplicity, circumscribed fields where either there is only one true relationship (among many that can be hypothesized) or the power is similar to find any of the several existing true relationships. The pre-study probability of a relationship being true is R/(R + 1). The probability of a study finding a true relationship reflects the power 1 - &#946; (one minus the Type II error rate). The probability of claiming a relationship when none truly exists reflects the Type I error rate, &#945;. Assuming that c relationships are being probed in the field, the expected values of the 2 � 2 table are given in Table 1. After a research finding has been claimed based on achieving formal statistical significance, the post-study probability that it is true is the positive predictive value, PPV. The PPV is also the complementary probability of what Wacholder et al. have called the false positive report probability [10]. According to the 2 � 2 table, one gets PPV = (1 - &#946;)R/(R - &#946;R + &#945;). A research finding is thus more likely true than false if (1 - &#946;)R > &#945;. Since usually the vast majority of investigators depend on a = 0.05, this means that a research finding is more likely true than false if (1 - &#946;)R > 0.05.
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Table 1. Research Findings and True Relationships
doi:10.1371/journal.pmed.0020124.t001

What is less well appreciated is that bias and the extent of repeated independent testing by different teams of investigators around the globe may further distort this picture and may lead to even smaller probabilities of the research findings being indeed true. We will try to model these two factors in the context of similar 2 � 2 tables.
Bias Top

First, let us define bias as the combination of various design, data, analysis, and presentation factors that tend to produce research findings when they should not be produced. Let u be the proportion of probed analyses that would not have been �research findings,� but nevertheless end up presented and reported as such, because of bias. Bias should not be confused with chance variability that causes some findings to be false by chance even though the study design, data, analysis, and presentation are perfect. Bias can entail manipulation in the analysis or reporting of findings. Selective or distorted reporting is a typical form of such bias. We may assume that u does not depend on whether a true relationship exists or not. This is not an unreasonable assumption, since typically it is impossible to know which relationships are indeed true. In the presence of bias (Table 2), one gets PPV = ([1 - &#946;]R + u&#946;R)/(R + &#945; &#8722; &#946;R + u &#8722; u&#945; + u&#946;R), and PPV decreases with increasing u, unless 1 &#8722; &#946; &#8804; &#945;, i.e., 1 &#8722; &#946; &#8804; 0.05 for most situations. Thus, with increasing bias, the chances that a research finding is true diminish considerably. This is shown for different levels of power and for different pre-study odds in Figure 1. Conversely, true research findings may occasionally be annulled because of reverse bias. For example, with large measurement errors relationships are lost in noise [12], or investigators use data inefficiently or fail to notice statistically significant relationships, or there may be conflicts of interest that tend to �bury� significant findings [13]. There is no good large-scale empirical evidence on how frequently such reverse bias may occur across diverse research fields. However, it is probably fair to say that reverse bias is not as common. Moreover measurement errors and inefficient use of data are probably becoming less frequent problems, since measurement error has decreased with technological advances in the molecular era and investigators are becoming increasingly sophisticated about their data. Regardless, reverse bias may be modeled in the same way as bias above. Also reverse bias should not be confused with chance variability that may lead to missing a true relationship because of chance.
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Figure 1. PPV (Probability That a Research Finding Is True) as a Function of the Pre-Study Odds for Various Levels of Bias, u

Panels correspond to power of 0.20, 0.50, and 0.80.
doi:10.1371/journal.pmed.0020124.g001
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Table 2. Research Findings and True Relationships in the Presence of Bias
doi:10.1371/journal.pmed.0020124.t002
Testing by Several Independent Teams Top

Several independent teams may be addressing the same sets of research questions. As research efforts are globalized, it is practically the rule that several research teams, often dozens of them, may probe the same or similar questions. Unfortunately, in some areas, the prevailing mentality until now has been to focus on isolated discoveries by single teams and interpret research experiments in isolation. An increasing number of questions have at least one study claiming a research finding, and this receives unilateral attention. The probability that at least one study, among several done on the same question, claims a statistically significant research finding is easy to estimate. For n independent studies of equal power, the 2 � 2 table is shown in Table 3: PPV = R(1 &#8722; &#946;n)/(R + 1 &#8722; [1 &#8722; &#945;]n &#8722; R&#946;n) (not considering bias). With increasing number of independent studies, PPV tends to decrease, unless 1 - &#946; < a, i.e., typically 1 &#8722; &#946; < 0.05. This is shown for different levels of power and for different pre-study odds in Figure 2. For n studies of different power, the term &#946;n is replaced by the product of the terms &#946;i for i = 1 to n, but inferences are similar.
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Figure 2. PPV (Probability That a Research Finding Is True) as a Function of the Pre-Study Odds for Various Numbers of Conducted Studies, n

Panels correspond to power of 0.20, 0.50, and 0.80.
doi:10.1371/journal.pmed.0020124.g002
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Table 3. Research Findings and True Relationships in the Presence of Multiple Studies
doi:10.1371/journal.pmed.0020124.t003
Corollaries Top

A practical example is shown in Box 1. Based on the above considerations, one may deduce several interesting corollaries about the probability that a research finding is indeed true.
Box 1. An Example: Science at Low Pre-Study Odds

Let us assume that a team of investigators performs a whole genome association study to test whether any of 100,000 gene polymorphisms are associated with susceptibility to schizophrenia. Based on what we know about the extent of heritability of the disease, it is reasonable to expect that probably around ten gene polymorphisms among those tested would be truly associated with schizophrenia, with relatively similar odds ratios around 1.3 for the ten or so polymorphisms and with a fairly similar power to identify any of them. Then R = 10/100,000 = 10&#8722;4, and the pre-study probability for any polymorphism to be associated with schizophrenia is also R/(R + 1) = 10&#8722;4. 1Let us also suppose that the study has 60% power to find an association with an odds ratio of 1.3 at &#945; = 0.05. Then it can be estimated that if a statistically significant association is found with the p-value barely crossing the 0.05 threshold, the post-study probability that this is true increases about 12-fold compared with the pre-study probability, but it is still only 12 � 10&#8722;4.

Now let us suppose that the investigators manipulate their design, analyses, and reporting so as to make more relationships cross the p = 0.05 threshold even though this would not have been crossed with a perfectly adhered to design and analysis and with perfect comprehensive reporting of the results, strictly according to the original study plan. Such manipulation could be done, for example, with serendipitous inclusion or exclusion of certain patients or controls, post hoc subgroup analyses, investigation of genetic contrasts that were not originally specified, changes in the disease or control definitions, and various combinations of selective or distorted reporting of the results. Commercially available �data mining� packages actually are proud of their ability to yield statistically significant results through data dredging. In the presence of bias with u = 0.10, the post-study probability that a research finding is true is only 4.4 � 10&#8722;4. Furthermore, even in the absence of any bias, when ten independent research teams perform similar experiments around the world, if one of them finds a formally statistically significant association, the probability that the research finding is true is only 1.5 � 10&#8722;4, hardly any higher than the probability we had before any of this extensive research was undertaken!

Corollary 1: The smaller the studies conducted in a scientific field, the less likely the research findings are to be true. Small sample size means smaller power and, for all functions above, the PPV for a true research finding decreases as power decreases towards 1 &#8722; &#946; = 0.05. Thus, other factors being equal, research findings are more likely true in scientific fields that undertake large studies, such as randomized controlled trials in cardiology (several thousand subjects randomized) [14] than in scientific fields with small studies, such as most research of molecular predictors (sample sizes 100-fold smaller) [15].

Corollary 2: The smaller the effect sizes in a scientific field, the less likely the research findings are to be true. Power is also related to the effect size. Thus research findings are more likely true in scientific fields with large effects, such as the impact of smoking on cancer or cardiovascular disease (relative risks 3�20), than in scientific fields where postulated effects are small, such as genetic risk factors for multigenetic diseases (relative risks 1.1�1.5) [7]. Modern epidemiology is increasingly obliged to target smaller effect sizes [16]. Consequently, the proportion of true research findings is expected to decrease. In the same line of thinking, if the true effect sizes are very small in a scientific field, this field is likely to be plagued by almost ubiquitous false positive claims. For example, if the majority of true genetic or nutritional determinants of complex diseases confer relative risks less than 1.05, genetic or nutritional epidemiology would be largely utopian endeavors.

Corollary 3: The greater the number and the lesser the selection of tested relationships in a scientific field, the less likely the research findings are to be true. As shown above, the post-study probability that a finding is true (PPV) depends a lot on the pre-study odds (R). Thus, research findings are more likely true in confirmatory designs, such as large phase III randomized controlled trials, or meta-analyses thereof, than in hypothesis-generating experiments. Fields considered highly informative and creative given the wealth of the assembled and tested information, such as microarrays and other high-throughput discovery-oriented research [4,8,17], should have extremely low PPV.

Corollary 4: The greater the flexibility in designs, definitions, outcomes, and analytical modes in a scientific field, the less likely the research findings are to be true. Flexibility increases the potential for transforming what would be �negative� results into �positive� results, i.e., bias, u. For several research designs, e.g., randomized controlled trials [18�20] or meta-analyses [21,22], there have been efforts to standardize their conduct and reporting. Adherence to common standards is likely to increase the proportion of true findings. The same applies to outcomes. True findings may be more common when outcomes are unequivocal and universally agreed (e.g., death) rather than when multifarious outcomes are devised (e.g., scales for schizophrenia outcomes) [23]. Similarly, fields that use commonly agreed, stereotyped analytical methods (e.g., Kaplan-Meier plots and the log-rank test) [24] may yield a larger proportion of true findings than fields where analytical methods are still under experimentation (e.g., artificial intelligence methods) and only �best� results are reported. Regardless, even in the most stringent research designs, bias seems to be a major problem. For example, there is strong evidence that selective outcome reporting, with manipulation of the outcomes and analyses reported, is a common problem even for randomized trails [25]. Simply abolishing selective publication would not make this problem go away.

Corollary 5: The greater the financial and other interests and prejudices in a scientific field, the less likely the research findings are to be true. Conflicts of interest and prejudice may increase bias, u. Conflicts of interest are very common in biomedical research [26], and typically they are inadequately and sparsely reported [26,27]. Prejudice may not necessarily have financial roots. Scientists in a given field may be prejudiced purely because of their belief in a scientific theory or commitment to their own findings. Many otherwise seemingly independent, university-based studies may be conducted for no other reason than to give physicians and researchers qualifications for promotion or tenure. Such nonfinancial conflicts may also lead to distorted reported results and interpretations. Prestigious investigators may suppress via the peer review process the appearance and dissemination of findings that refute their findings, thus condemning their field to perpetuate false dogma. Empirical evidence on expert opinion shows that it is extremely unreliable [28].

Corollary 6: The hotter a scientific field (with more scientific teams involved), the less likely the research findings are to be true. This seemingly paradoxical corollary follows because, as stated above, the PPV of isolated findings decreases when many teams of investigators are involved in the same field. This may explain why we occasionally see major excitement followed rapidly by severe disappointments in fields that draw wide attention. With many teams working on the same field and with massive experimental data being produced, timing is of the essence in beating competition. Thus, each team may prioritize on pursuing and disseminating its most impressive �positive� results. �Negative� results may become attractive for dissemination only if some other team has found a �positive� association on the same question. In that case, it may be attractive to refute a claim made in some prestigious journal. The term Proteus phenomenon has been coined to describe this phenomenon of rapidly alternating extreme research claims and extremely opposite refutations [29]. Empirical evidence suggests that this sequence of extreme opposites is very common in molecular genetics [29].

These corollaries consider each factor separately, but these factors often influence each other. For example, investigators working in fields where true effect sizes are perceived to be small may be more likely to perform large studies than investigators working in fields where true effect sizes are perceived to be large. Or prejudice may prevail in a hot scientific field, further undermining the predictive value of its research findings. Highly prejudiced stakeholders may even create a barrier that aborts efforts at obtaining and disseminating opposing results. Conversely, the fact that a field is hot or has strong invested interests may sometimes promote larger studies and improved standards of research, enhancing the predictive value of its research findings. Or massive discovery-oriented testing may result in such a large yield of significant relationships that investigators have enough to report and search further and thus refrain from data dredging and manipulation.
Most Research Findings Are False for Most Research Designs and for Most Fields Top

In the described framework, a PPV exceeding 50% is quite difficult to get. Table 4 provides the results of simulations using the formulas developed for the influence of power, ratio of true to non-true relationships, and bias, for various types of situations that may be characteristic of specific study designs and settings. A finding from a well-conducted, adequately powered randomized controlled trial starting with a 50% pre-study chance that the intervention is effective is eventually true about 85% of the time. A fairly similar performance is expected of a confirmatory meta-analysis of good-quality randomized trials: potential bias probably increases, but power and pre-test chances are higher compared to a single randomized trial. Conversely, a meta-analytic finding from inconclusive studies where pooling is used to �correct� the low power of single studies, is probably false if R &#8804; 1:3. Research findings from underpowered, early-phase clinical trials would be true about one in four times, or even less frequently if bias is present. Epidemiological studies of an exploratory nature perform even worse, especially when underpowered, but even well-powered epidemiological studies may have only a one in five chance being true, if R = 1:10. Finally, in discovery-oriented research with massive testing, where tested relationships exceed true ones 1,000-fold (e.g., 30,000 genes tested, of which 30 may be the true culprits) [30,31], PPV for each claimed relationship is extremely low, even with considerable standardization of laboratory and statistical methods, outcomes, and reporting thereof to minimize bias.
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Table 4. PPV of Research Findings for Various Combinations of Power (1 - �), Ratio of True to Not-True Relationships (R), and Bias (u)
doi:10.1371/journal.pmed.0020124.t004
Claimed Research Findings May Often Be Simply Accurate Measures of the Prevailing Bias Top

As shown, the majority of modern biomedical research is operating in areas with very low pre- and post-study probability for true findings. Let us suppose that in a research field there are no true findings at all to be discovered. History of science teaches us that scientific endeavor has often in the past wasted effort in fields with absolutely no yield of true scientific information, at least based on our current understanding. In such a �null field,� one would ideally expect all observed effect sizes to vary by chance around the null in the absence of bias. The extent that observed findings deviate from what is expected by chance alone would be simply a pure measure of the prevailing bias.

For example, let us suppose that no nutrients or dietary patterns are actually important determinants for the risk of developing a specific tumor. Let us also suppose that the scientific literature has examined 60 nutrients and claims all of them to be related to the risk of developing this tumor with relative risks in the range of 1.2 to 1.4 for the comparison of the upper to lower intake tertiles. Then the claimed effect sizes are simply measuring nothing else but the net bias that has been involved in the generation of this scientific literature. Claimed effect sizes are in fact the most accurate estimates of the net bias. It even follows that between �null fields,� the fields that claim stronger effects (often with accompanying claims of medical or public health importance) are simply those that have sustained the worst biases.

For fields with very low PPV, the few true relationships would not distort this overall picture much. Even if a few relationships are true, the shape of the distribution of the observed effects would still yield a clear measure of the biases involved in the field. This concept totally reverses the way we view scientific results. Traditionally, investigators have viewed large and highly significant effects with excitement, as signs of important discoveries. Too large and too highly significant effects may actually be more likely to be signs of large bias in most fields of modern research. They should lead investigators to careful critical thinking about what might have gone wrong with their data, analyses, and results.

Of course, investigators working in any field are likely to resist accepting that the whole field in which they have spent their careers is a �null field.� However, other lines of evidence, or advances in technology and experimentation, may lead eventually to the dismantling of a scientific field. Obtaining measures of the net bias in one field may also be useful for obtaining insight into what might be the range of bias operating in other fields where similar analytical methods, technologies, and conflicts may be operating.
How Can We Improve the Situation? Top

Is it unavoidable that most research findings are false, or can we improve the situation? A major problem is that it is impossible to know with 100% certainty what the truth is in any research question. In this regard, the pure �gold� standard is unattainable. However, there are several approaches to improve the post-study probability.

Better powered evidence, e.g., large studies or low-bias meta-analyses, may help, as it comes closer to the unknown �gold� standard. However, large studies may still have biases and these should be acknowledged and avoided. Moreover, large-scale evidence is impossible to obtain for all of the millions and trillions of research questions posed in current research. Large-scale evidence should be targeted for research questions where the pre-study probability is already considerably high, so that a significant research finding will lead to a post-test probability that would be considered quite definitive. Large-scale evidence is also particularly indicated when it can test major concepts rather than narrow, specific questions. A negative finding can then refute not only a specific proposed claim, but a whole field or considerable portion thereof. Selecting the performance of large-scale studies based on narrow-minded criteria, such as the marketing promotion of a specific drug, is largely wasted research. Moreover, one should be cautious that extremely large studies may be more likely to find a formally statistical significant difference for a trivial effect that is not really meaningfully different from the null [32�34].

Second, most research questions are addressed by many teams, and it is misleading to emphasize the statistically significant findings of any single team. What matters is the totality of the evidence. Diminishing bias through enhanced research standards and curtailing of prejudices may also help. However, this may require a change in scientific mentality that might be difficult to achieve. In some research designs, efforts may also be more successful with upfront registration of studies, e.g., randomized trials [35]. Registration would pose a challenge for hypothesis-generating research. Some kind of registration or networking of data collections or investigators within fields may be more feasible than registration of each and every hypothesis-generating experiment. Regardless, even if we do not see a great deal of progress with registration of studies in other fields, the principles of developing and adhering to a protocol could be more widely borrowed from randomized controlled trials.

Finally, instead of chasing statistical significance, we should improve our understanding of the range of R values�the pre-study odds�where research efforts operate [10]. Before running an experiment, investigators should consider what they believe the chances are that they are testing a true rather than a non-true relationship. Speculated high R values may sometimes then be ascertained. As described above, whenever ethically acceptable, large studies with minimal bias should be performed on research findings that are considered relatively established, to see how often they are indeed confirmed. I suspect several established �classics� will fail the test [36].

Nevertheless, most new discoveries will continue to stem from hypothesis-generating research with low or very low pre-study odds. We should then acknowledge that statistical significance testing in the report of a single study gives only a partial picture, without knowing how much testing has been done outside the report and in the relevant field at large. Despite a large statistical literature for multiple testing corrections [37], usually it is impossible to decipher how much data dredging by the reporting authors or other research teams has preceded a reported research finding. Even if determining this were feasible, this would not inform us about the pre-study odds. Thus, it is unavoidable that one should make approximate assumptions on how many relationships are expected to be true among those probed across the relevant research fields and research designs. The wider field may yield some guidance for estimating this probability for the isolated research project. Experiences from biases detected in other neighboring fields would also be useful to draw upon. Even though these assumptions would be considerably subjective, they would still be very useful in interpreting research claims and putting them in context.
References Top

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Citation: Ioannidis JPA (2005) Why Most Published Research Findings Are False. PLoS Med 2(8): e124. doi:10.1371/journal.pmed.0020124

Published: August 30, 2005

Copyright: � 2005 John P. A. Ioannidis. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Competing interests: The author has declared that no competing interests exist.

Abbreviation: PPV, positive predictive value

Chikungunya
Classification & external resources
ICD-10 A92.0
ICD-9 065.4, 066.3
DiseasesDB 32213
MeSH D018354
Chikungunya virus
Virus classification
Group: Group IV ((+)ssRNA)
Family: Togaviridae
Genus: Alphavirus
Species: Chikungunya virus
Chikungunya is a relatively rare form of viral fever caused by an alphavirus that is spread by mosquitobites from Aedes aegypti mosquitoes, though recent research by the Pasteur Institute in Paris claims the virus has suffered a mutation that enables it to be transmitted by Aedes albopictus (Tiger mosquito). This was the cause of the plague in the Indian Ocean and a threat to the Mediterranean coast at present, requiring urgent meetings of health officials in the region.
Contents
1 Etymology
1.1 Linguistic confusion
2 Impact
3 Symptoms
4 Treatment
5 Epidemiology
6 Preventive measures
7 See also
8 Notes
9 External links
9.1 General information
9.2 News reports
Etymology
name is derived from the Makonde word meaning "that which bends up" in reference to the stooped posture developed as a result of the arthritic symptoms of the disease. The disease was first described by Marion Robinson[1] and W.H.R. Lumsden[2] in 1955, following an outbreak on the Makonde Plateau, along the border between Tanganyika and Mozambique, in 1952. Chikungunya is closely related to O'nyong'nyong virus[3].

Linguistic confusion
According to Lumsden's initial 1955 report about the epidemiology of the disease, the term chikungunya is derived from the Makonde root verb kungunyala, meaning to dry up or become contorted. In concurrent research, Robinson glossed the Makonde term more specifically as "that which bends up." Subsequent authors apparently overlooked the references to the Makonde language and assumed that the term derived from Swahili, the lingua franca of the region. The erroneous attribution of the term as a Swahili word has been repeated in numerous print sources; Google lists over 15,000 results in a search for "chikungunya swahili". Many other erroneous spellings and forms of the term are in common use including "Chicken guinea", "Chicken gunaya," and "Chickengunya".

Impact
Chikungunya is generally not fatal. However, in 2005-2006, 200 deaths were associated with chikungunya on R�union island and a widespread outbreak in India, primarily in Tamil Nadu,Karnataka, Kerala, and Andhra Pradesh. After flood and heavy rains in Rajasthan, India in August 2006, thousands of cases were detected in Rajsamand, Bhilwara, Udaipur, and Chittorgarh districts and also in adjoining regions of Gujarat and Madhya Pradesh, and in the neighbouring country of Sri Lanka. In the southern Indian state of Kerala, 125 deaths were attributed to Chikungunya with the majority of the casualties reported in the district of Alapuzha, primarily in Cherthala. In December 2006, an outbreak of 3,500 confirmed cases occurred in Maldives, and over 60,000 cases in Sri Lanka, with over 80 deaths. [1]. In October 2006 more than a dozen cases of Chikungunya were reported in Pakistan. A recent outbreak of the disease during June 2007 in Pathanamthitta, Kottayamand Alappuzha districts of South Kerala, India claimed more than 50 lives. It is confirmed officially that there are 7000 confirmed Chikungunya patients in these areas. Unofficial reports suggest that more than one hundred thousand are suffering from symptoms of chikungunya.[citation needed] Roamers are there telling that radio active waste from Tamil Nadu was deposited at the outskirts of this region which made the mosquitos to mutate and spread the disease like any thing..till now all the infected people are suffering from sever body pain and swelling The European Network for Diagnostics of "Imported" Viral Diseases [2] claims new phylogenetic variants of virus which are fatal have been identified on R�union. [3]

Symptoms

The Aedes aegypti mosquito
The symptoms of Chikungunya include fever which can reach 39�C, (102.2�F) a petechial or maculopapular rashusually involving the limbs and trunk, and arthralgia or arthritis affecting multiple joints which can be debilitating. The symptoms could also include headache, conjunctival injection, and slight photophobia. In the present epidemic in the states of Andhra Pradesh and Tamil Nadu, India, high fever and crippling joint pain are the prevalent complaint. The fever typically lasts for two days and abruptly comes down. However, other symptoms, namely joint pain, intense headache, insomnia and an extreme degree of prostration last for a variable period, usually for about 5 to 7 days. But, patients have complained joint pains for much longer time periods depending on age of the patient. With younger patients recovering within 5 to 15 days and middle aged recovering in 1 to 2.5 months and more for old people. It has been observed that the severity of the disease as well as its duration is less in younger patients and pregnant women. No untoward effects of pregnancy is noticed following the infection.

Dermatological manifestations observed in a recent outbreak of Chikungunya fever in Southern India (Dr. Arun Inamadar, Dr. Aparna Palit, Dr.V.V. Sampagavi, Dr. Raghunath S, Dr. N.S. Deshmukh), Western India (Surat) (Western India reported by Dr. Buddhadev) and Eastern India (Puri) (Dr. Milon Mitra et al) includes the following:
Maculopapular rash
Nasal blotchy erythema
Freckle-like pigmentation over centro-facial area
Flagellate pigmentation on face and extremities
Lichenoid eruption and hyperpigmentation in photodistributed areas
Multiple aphthous-like ulcers over scrotum, crural areas and axilla.
Lympoedema in acral distribution (bilateral/unilateral)
Multiple ecchymotic spots (Children)
Vesiculobullous lesions (infants)
Subungual hemorrhage
Photo Urticaria
Acral Urticaria
Cephalgia
Lumbago
Vomiting
Epistaxis and haemetemesis
Histopathologically, pigmentary changes, maculopapular rash, lichenoid rash, aphthous-like ulcers show lymphocytic infiltration around dermal blood vessels (Inamadar et al). Pedal oedema (swelling of legs) is observed in many patients, the cause of which remains obscure as it is not related to any cardiovascular, renal or hepatic abnormalities.

Treatment
There is no specific treatment for Chikungunya. Vaccine trials were carried out in 2000, but funding for the project was discontinued and there is no vaccine currently available. A serological test for Chikungunya is available from the University of Malaya in Kuala Lumpur, Malaysia.

Chloroquine is gaining ground as a possible treatment for the symptoms associated with Chikungunya and as an antiviral agent to combat the Chikungunya virus. According to the University of Malaya, "In unresolved arthritis refractory to aspirin and nonsteroidal anti-inflammatory drugs,chloroquine phosphate (250 mg/day) has given promising results." [4] Research by Italian scientist, Andrea Savarino, and his colleagues in addition a French government press release in March 2006 [5] have added more credence to the claim that chloroquine may be effective in treating Chikungunya. The CDC fact sheet on Chikungunya advises against using Aspirin. Ibuprofen, Naproxen and other non-steroidal anti-inflammatory drugs are recommended for arthritic pain and fever.

Infected persons should limit further exposure to mosquito bites, stay indoors and under a mosquito net. Further, "supportive care with rest is indicated during the acute joint symptoms. Movement and mild exercise tend to improve stiffness and morning arthralgia, but heavy exercise may exacerbaterheumatic symptoms." [6] Arthralgia remains troublesome even after 8 months.

Homoeopathy claims to have successful treatment for chikungunya. As they treat on symptomatology and not the diagnosis, they claim to have many medicines successful for prevention and cure of chikungunya.

Epidemiology
Chikungunya was first described in Tanzania, Africa in 1952. The first outbreak in India was in 1963 inCalcutta.[4] An outbreak of chikungunya was also discovered in Port Klang in Malaysia in 1999affecting 27 people [7] [8].

Preventive measures
The most effective means of prevention are those that protect against any contact with the disease-carrying mosquitos. These include using insect repellent containing NNDB, DEET or permethrin, wearing long sleeves and trousers (pants), and securing screens on windows and doors. It's also important to empty stagnant water where mosquitoes breed. [9].

See also
September 2007 peer-reviewed review article on Chikungunya virus. Free on JGV Direct
Dengue fever
Notes
^ Robinson Marion (1955). "An Epidemic of Virus Disease in Southern Province, Tanganyika Territory, in 1952-53; I. Clinical Features". Trans Royal Society Trop Med Hyg 49 (1): 28-32.
^ Lumsden WHR (1955). "An Epidemic of Virus Disease in Southern Province, Tanganyika Territory, in 1952-53; II. General Description and Epidemiology". Trans Royal Society Trop Med Hyg 49 (1): 33-57.
^ Vanlandingham DL, Hong C, Klingler K, Tsetsarkin K, McElroy KL, Powers AM, Lehane MJ, Higgs S (2005). "Differential infectivities of o'nyong-nyong and chikungunya virus isolates in Anopheles gambiae and Aedes aegypti mosquitoes". Am J Trop Med Hyg 72 (5): 616-21. PubMed.
^ Chikungunya-History. Retrieved on 2007-05-20