Tribute to Dr Luis Fernando Bicudo Pereira Costa Rosa (GG)

We have been asked to pay our respects on behalf of the Department of Cell and Developmental Biology to our dear colleague Luis Fernando Bicudo Pereira Costa Rosa, who tragically passed away on May 19, 2005, at the age of 40, after he met with an accident while cycling. We have to confess we have had a hard time coming up with the words. We hope we have achieved the right blend of respect and admiration to adequately memorialize him in these short few lines of ink. 
 
Luis Fernando (known to his friends as GG) was born in Sao Paulo, Brazil, on December 31, 1964, as the oldest child of Antonio Fernando and Maria Cecilia. He graduated from the University of Sao Paulo (USP), where he majored in Biology. He received his master's degree and PhD under the supervision of Professor Rui Curi in 1992 and in 1995, respectively, at the USP. He started his academic career in the Department of Physiology and Biophysics, Institute of Biomedical Sciences, at the USP before moving to the Department of Cell and Developmental Biology in 1995, where he remained until he died. On December 21, 1990, he married Marilia Seelaender, also our colleague at the Department of Cell and Developmental Biology. As he liked often to say, his children, Isabel and Felipe, were his most important accomplishments. Among the things that made Luis Fernando unique, and which all of those who knew him will miss, were his energy, his unquiet spirit and his sincere talking. 
 
He was an exceptional athlete and had been rowing champion at the state level many times and the Brazilian university champion a couple of times, as well as competing in many athletic running events. He won numerous medals in cycling, running and triathlon competitions. All this energy was also reflected in his academic career. The force with which he fought for his ideals (scientific and political) and his indefatigable persuasion of others to consolidate research in the area of exercise physiology were, without a doubt, meritorious. As part of a group of specialists he coordinated an annual specialization course, one of only a few in this area of expertise in Brazil. Luis Fernando was widely known for his research and professional contributions on exercise metabolism and immune function. He authored or coauthored 65 scientific papers on these subjects. As everyone who knew Luis Fernando will recognize, his scientific talk was not a purely cerebral affair but was always rich in emotion, excitement and nervous tension—something peculiar to those who share his love for his subject. As an advisor, his actions always were and still are a guide to the large group of graduate and undergraduate students and colleagues who had associations with him. His spirit also could be justly defined as that of a sportsman, for his fascination for sporting activities transcended his scientific activities. He was an inspiration to his students, and his influence, I am sure, will be felt by us for several decades. So it is with great sadness that I bid farewell to Luis Fernando on behalf of our colleagues. His family, colleagues and friends loved him dearly. He will be deeply missed by all of us. 
 
As a faculty member of the Laboratory of Metabolism, Department of Histology and Embryology, Institute of Biomedical Sciences, USP, Brazil, Luis F. B. P. Costa Rosa was the author of one of our most accessed articles (“Exercise as a Time-conditioning Effector in Chronic Disease: A Complementary Treatment Strategy”), published in the first issue of eCAM. 
 
The Editor-in-Chief was a personal friend of his, and on behalf of all the editorial staff and the board of eCAM, we extend our profound sympathy to his family and friends.

The article by Skene [1] has touched on an important topic in as far as global health research is concerned. Skene's barometer is certainly a critical contribution to the discourse in research ethics that could be used in both extra-territorial and intra-territorial research. There are, however, several areas where I feel a different opinion would enrich the discussion.
My fi rst concern is that the author presents this barometer with the slices of the pie having sharp demarcations. To the reader, this may suggest that there are clear-cut transitions from one area of the barometer to the other. In reality, however, issues in ethics are less well demarcated. For instance, a research area in itself may fi t more in one color zone, but the participants chosen may move it towards the next color zone. Another researcher studying the same research area but different participant groups may be in a different color zone. In general, however, gradations with one color merging into the other, rather than clearcut demarcations, would be more likely to be observed in practice. The fact that a different scheme could present reality more clearly is exemplifi ed by the author's use of the "green zone", where research on competent adults, research on vulnerable populations, and research on children have all been grouped under one "roof". Skene's barometer may also be modifi ed if one considers that vulnerability can be determined on a categorical basis (all persons in that category are vulnerable) versus on a situational basis [2]. For example, why should all persons under sentence of capital punishment be considered vulnerable? Do we assume that these people cannot make informed decisions which are so central in research ethics? Are we worried about coercion or constraining factors?
It is of interest that Skene's barometer has research on stored human tissue and observing people in a public place as neither associated with any laws and no requiring ethics oversight. Did the author mean that a researcher intending to video tape (which is by the way observational) in a restaurant not require ethics oversight? I would argue that stored human specimens should also be associated with ethical oversight. Mfutso-Bengo and I have made a case for continued ethical oversight on stored specimens in international collaborative research [3]. This view has been supported by Ndebele, who has advocated for materials transfer agreements [4]. Although we have made arguments based on actual specimens, we have not argued in support of agreements on use of data that emanates from international research.
The author also writes, "research that imposes severe suffering on animals, especially for a cosmetic rather than scientifi c purpose, would be widely condemned as well as unlawful in Australia". I do understand that the author writes from an Australian standard point, but the statement implicitly suggests that research conducted for cosmetic improvements cannot be for "scientifi c purposes". What is the author's defi nition of science? It would certainly make a difference if what the author actually meant was research for cosmetic purposes or gains versus research for treatment of diseases (although cosmetics can also be a treatment for disfi guring human diseases).
It is interesting that the author also suggests that research on cloning "would be unlawful in Australia and almost universally regarded as ethically unacceptable". This certainly brings into question the thesis that research ethics are universal. I guess in the next decades, the world will grapple with the ethical conduct of research in space. Who has jurisdiction when research occurs in outer space? These questions and others will certainly confront humanity, if not in this century, perhaps in the next.
Finally, because of the use of specifi c examples and situations, Skene's barometer may be applicable to Australia but not so much to the wider world. I guess the tool will undergo transformations where general algorithms and principles will be considered such that the barometer will be used beyond Australia. Competing Interests: The author has declared that no competing interests exist.

Undertaking Research in Other Countries: Author's Reply
Adamson Muula [1] rightly observes that demarcation between the "zones" of Skene's barometer is unclear. Certain activities may fall in one zone or another, depending on the circumstances. A research project does not fall within a particular zone solely because of its type. One must consider the project in operation. Muula mentions the treatment of participants in trials, particularly whether they are properly informed before the trial starts. One could add other factors such as the way participants are recruited, personal information held, or adverse incidents reported. Thus "research involving competent adults", which I have in the green zone (permitted with ethical oversight), would move to the yellow or orange zones (permitted under national laws with ethical oversight; or prohibited by national laws) if participants were coerced or duped into entering a trial; or if their personal details were revealed without their consent or other lawful authority; or if researchers did not inform the appropriate authority during the trial that other participants had suffered serious and unexpected injury. Similarly, "medical research involving children" would fall within the green zone only if there is minimal harm to the child and full parental consent.
I suggested in my original article that the sensitivity of research could be "measured" on the barometer by its nature and by how it is legally regulated. I then gave examples, such as medical research involving competent adults and research on genetically modifi ed crops. That is, of course, only the fi rst step. I intended to designate research of that kind that is "properly conducted". The zones are less clear when one considers a variation of the initial research activity. This is illustrated by Muula's examples. In Australia, there is no general legal restriction on observing people in a public place, or even photographing or videotaping them for research. I therefore placed those activities in the white zone on the Australian barometer (no specifi c laws or oversight). Australian law does not recognize a general legal right to "privacy". However, those activities could appear in another zone in certain circumstances. It is an offence to "stalk" people, or to photograph them so as to suggest they are acting unlawfully or to defame them.
Similarly, in Australia, it is not unlawful to collect human bodily material that has been "discarded" by other people, even if they have not consented and do not know about it. A scientist who picks up a tissue with a person's blood on it, in a public place, and does research on the blood would commit no offence even if he or she knew the identity of the person concerned. No ethics committee approval is needed. The scientist would breach the law only if personal information derived from the research was revealed without lawful authority. The same argument applies to research on bodily materials that are discarded by hospitals or pathology laboratories as garbage. The position of the research on the barometer moves according to the circumstances. If the bodily material is specifi cally sought from a hospital or laboratory, ethics approval would be needed, and possibly also consent from the people concerned, though that can be waived in certain circumstances.
The barometer is always based on local laws, which are a measure of the sensitivity of the community regarding particular conduct. The barometer reading may indicate that community opinion is divided or not so opposed to particular activities that they could not be accepted in another country, especially where they are undertaken with appropriate ethical surveillance. If other countries choose to use the barometer, they must substitute their own local laws and they may, of course, reach a different conclusion. Research ethics are not universal, but there may be more agreement than is commonly thought.
Loane Skene (l.skene@unimelb.edu.au) University of Melbourne Melbrourne, Australia of natural ventilation rates in health-care settings, and the novel conclusions of our article are that extremely high rates of dilutional ventilation can be achieved through natural ventilation at very little cost by simply opening windows and doors. Indeed, this natural ventilation was far in excess of even the best maintained mechanical ventilation systems used in health-care settings. Importantly, this natural ventilation greatly reduced the calculated risk of airborne infection.
Measuring TB transmission itself is diffi cult, as rates in staff are confounded by exposures outside the workplace, and mechanical air sampling techniques have had limited success. We have established a guinea pig air sampling facility to directly measure TB transmission in a hospital ward in Lima, Peru [2] and have used this model to evaluate the effects of upper room ultraviolet light and negative air ionization on TB transmission. We plan to use this facility to further study natural ventilation, and its effect on actual TB transmission.
The results of the current study cannot be generalized to regions too cold to tolerate enhanced natural ventilation and not every room may be as amenable to natural ventilation as the Peruvian rooms that we studied. However, the key conclusions are clear: high rates of natural ventilation were achieved even on days with little wind and even rooms without high ceilings and large windows were well ventilated, such that natural ventilation signifi cantly exceeded mechanical ventilation.
It is therefore clear that natural ventilation has an important role to play in the fi ght against institutional TB transmission in resource-limited settings. Mechanical ventilation is expensive to install, requires costly ongoing maintenance, may be dangerous if poorly maintained (for example, delivering positive instead of negative pressure), and is clearly inappropriate for the great majority of resourcelimited settings where the burden of TB is highest. TB infection control is an urgent priority, underscored by the emergence of extreme drug-resistant TB strains and the increasing congregation in potentially high-risk overcrowded settings of persons living with HIV through the roll-out of enhanced HIV care. When infectious TB patients share rooms with others, opening windows and doors to enhance natural ventilation is a simple, inexpensive, and effective strategy in the fi ght against nosocomial TB transmission.