By Prof. Joseph O. Malo. KNAS and University of Nairobi

Abstract

The paper examines the role of traditional and indigenous knowledge and technology including the role of citizens in knowledge management of sustainable environment, health, water resources, education, habitat, disaster and emergency response, food security, clean energy etc.

The motivating factor is that most of the villages in developing countries are small and literally cut off from the rest of the world and hence under serviced. Social services particularly in health must therefore promote a combination of traditional and scientific approach. This calls for recognition of people who apply natural and traditional methods to sustain life.

One of the main bottle-neck in technology transfer is the current approach of the trickle-down effect rather than participatory bottom up approach where citizens are considered not just as partial beneficiaries but knowledgeable, active and centrally involved in both the upstream design and downstream delivery systems.

Background and Major Constraints

The key problem Africa is facing today is under-development that manifests itself in terms of abject poverty, diseases, ignorance and many other forms. It is regrettable to recognize and note that due to the severe but apparent lack of funds and other resources, many African counties have remained impoverished over the years. The weak fiscal status and the dim prospects for drastic economic improvement coupled with mismanagement, corruption in the continent also militate against any significant local support to alleviate the problems of under-development in the near future. From the experience of the industrialized countries it has become abundantly clear that for Africa to develop and survive this century, science, technology and innovation must take root in the continent to serve the people and improve productivity.

Global Environmental Change refers to a set of transformations of land, oceans and atmosphere driven by an interwoven system of socioeconomic and natural processes. Thus concurrent with the modern phenomena of globalization and to some extent as a consequence, human have begun to induce planetary-scale changes in earth’s life support systems.

Today human activities already match and sometimes exceed natural forces that regulate the earth systems. Current levels of carbon dioxide and methane are already well outside the range of natural variability over the years. Humans also now fix more nitrogen than nature dues. Furthermore particles emitted by human activities alter the energy balance of the planet as well as have adverse effects on human health.

It is however encouraging to note that the earth system is a very complex system with very many feedbacks to the extent that it can presumably still exhibit rapid global scale responses to changes in environmental conditions. However, a consequence of the interconnectedness of the coupled human environmental earth systems is that no region is independent of the rest of the world. For example the process at wok in the African region namely desertification and, biomass burning can have global consequences in the same way processes occurring in other regions can have influences in Africa such as particulate emissions from other continents affect rainfall patterns in Sub-Saharan Africa. Thus Global Environmental research in Africa requires not only Africa Scientists but also inputs from Scientists from outside the region. We are all interdependent.

It is therefore imperative that Global Warming and Climate Change that is real must be adequately addressed to bring sustainable development down to earth. To achieve this noble goal, traditional and indigeneous knowledge and technology including citizens engagement must be fully incorporated in the process of socio-economic development and more so in the developing world.

Science, Technology and Innovation Policy

It is today generally accepted that technology is “ the engine of economic growth” and technological innovation is indeed the principal currency of international competition. Thus technology plays a key role in attaining major goals in invigorating countries competitiveness in the global market place. For example the secondary applications of aerospace technology –spin-offs- span so broad a range of public needs and conveniences that is almost impossible to find an area of everyday life they have not improved and thus collectively represent a substantial dividend on the national investment in technology research.

A science and technology policy should therefore aim at improving the effectiveness of a national system of innovation, supporting public research and education, and sustaining the competitiveness of the business sector. So a major policy area should therefore focus on the promotion of innovation and investment, the diffusion of advanced technologies and creation of new firms. Thus a mechanism must be put in place for funding technological innovation by providing grants, low-interest loans and risk capital for supporting individual and cooperative research projects including downstream innovation that will mitigate the effects global warming and climate change.

Capacity Building

The highly interdisciplinary nature and mutuality of science in the development of new technology evolved mainly out of the capitalization on the solid foundation in science in the aspects of technology innovation, development and diffusion. Despite all the trailblazing advancements, our society is still experiencing an imbalance in improving literacy of citizens with the scientific technology development process, that has serious implications for public policy formulations, especially for developing countries.

Thus for Africa to enjoy the full benefit of Science and Technology they must be deemed critical to our effort to achieve economic well-being and indeed, social justice integrated into societal decision making structure and systematically supported by actions that nurture the nation’s capacities and indigenous talent/knowledge.

Since many of the urgent problems facing humanity today have potential solution derived from science and technology, it is vital that science and technology become part of the mainstream of education system. Thus courses that provide the basis of science and technology literacy and reasonable literacy and familiarity with scientific and technological culture, should be required at all levels and for all students including the many who do not intend to specialize in science and technology. This will create a science culture for a knowledge based society of the future.

Regarding Science Education we need to urgently introduce Inquiry-based Science Education (IBSE) at least from Pre- primary to primary school level. The conduct of science is also increasingly affected and indeed, driven by economic and other societal concerns .It is therefore necessary for the scientific community to be conscious of the concerns of the societies. Research agenda priorities derive not just from the wishes of scientists or their interest in certain problems, but from factors such as national needs, the availability of funding, access to tools of research and commercial prospects for deploying the resulting technologies such that almost always what get studied is decided by non-scientists.

Since the indigenous professionals generally understand their nation’s culture, they can easily communicate with it’s people. That is, they are uniquely placed to be disseminators of advanced knowledge and know-how to other critical local actors. This will greatly increase the likelihood that the new technologies will be well adapted to that society’s needs and cultures. The public can become sensitized on the important role of Science and Technology in society and their potential to help to solve urgent problems. A society that has become increasingly more dependent upon Science and Technology requires more professional scientists, more technically trained professionals and more citizens literate in science and technology who can make intelligent decisions on the increasing number questions of public policy with a technical component.

A nation that is involved in development, production or use of new technologies such as those deriving from biotechnology and bioengineering, should have the means to access and manage their benefits and risks. It is obvious that independent scientific advice improves decision making for public policies in terms of formulation, implementation, monitoring and evaluation. The effective government programmes can be greatly improved if inputs and independent review are provided by scientific, engineering and health experts. These are honest brokers who bridge the gap between what is technically possible and politically achievable. We know that many international deliberations from intellectual property rights to environmental and health regulations require governments to fully understand the science and technology premises that underlie the decisions they are negotiating. It is therefore vital that we create suitable mechanisms for providing important scientific and technological advice to government policy makers. That will also mitigate the effect of global warming and climate change.

Our governments must therefore ensure that indigeneous science and technology capacities are in place not only for adoption of new technology but also for helping in implementing public health, human safety and environmental guidelines or regulations that address potential side effects of new technologies. The possibilities of long term effects must be kept in mind when setting up such systems which must remain fully adaptable to rapid advances in scientific and engineering knowledge. It is therefore highly desirable that there be coordination of such efforts among nations to permit the sharing of the experiences and standardization of some of the risk assessments.

Traditional and Indigeneous Knowledge and Technology

There is no doubt that traditional and indigeneous knowledge and technology, particularly in the developing world, can enhance and indeed play decisive role in the management of sustainable environment, health, water resources, education, habitat, disaster and emergency response, food security, clean energy etc. In this paper, I will however focus only on health.

Plenty of our villages are small and literally cut off from the world and under-serviced. Most are subsistence farmers and indeed live below poverty line. The children are under and malnourished and at risk of preventable diseases.
We must expand social services for these people who are particularly disadvantaged in remote villages. The few government institutions that exist are far away and most are under equipped, including lack of staff. In any case they are often beyond the reach of those without money. Needless to point out that young doctors prefer working in towns. In addition to this, language barriers and cultural differences make communication even more difficult.

Social services particular in health, we must promote a combination of traditional and scientific methods during training of all cadres of medical personnel. The so called healers should first impart basic knowledge of scientific, natural and dental care including sexual and reproductive health.

We must urgently start supporting people who manufacture and use natural healing methods and recognize the potential of traditional medicine. As a first step, we should compile a handbook that will indicate disease patterns, diagnosis and cure including details of identification and the correct way to use medicinal plants.

We should then use media such as Radio and TV that feature interviews including public lectures that are informed and knowledge based. This programme could give information on symptoms and report on how to prevent and cure illnesses. Last but not least train two or more people in each village.

Citizen Engagement

It has become imperative that high- tech promotion should be of particular interest for developing countries because research in this areas has the general advantage that leads and require technological advancement in the frontier fields that will produce important spin-offs on the development of a country in which it is performed. Thus only knowledge based on local realities and environment can resolve the appropriateness of an imported technology to the community and turn them into new products and services that address national and local needs.

Citizen engagement is vital to ensure Science, Technology and Innovation respond to the challenges of international development agenda that includes Global Warming, Climate Change, Bioengineering and Biotechnology. There are many pathways to poverty reduction including social, cultural and institutional dimension that are key. This is so because Science, Technology and Innovation should be perceived as a part of a bottom-up participating process of development where citizen themselves are centre stage. Instead of citizen being viewed as passive beneficiaries of trickle-down development of technology transfer, they be considered as knowledgeable, active and centrally involved in both upstream choice and design of technologies and indeed their downstream delivery and regulation.

How about the following issues (1) What role can technologies play in future of people in developing world (2) How can poor people become more involved in shaping their own technological future (3) What makes Science and Technology to work for the poor (4) Which forces will be involved in shaping this (5) How can those who work in science and development assist and (6) How and where should Research and Development funds be directed

One of the main bottleneck of acceptance of new technologies currently is how risk and uncertainties arising from technological applications are regulated. In this connection the marginalized people should be involved in decision about innovation and technology. Thus it is time to adopt a new vision of citizenship that goes beyond public engagement with science encompassing, how science and technology agendas are framed, and the social purpose they serve and, who stands to gain or lose from them.

Conclusion

Thus advances in Science, Technology and Innovation (STI) should not neglect the poor people’s own priorities in trickle - down model since this approach will ignore poor people’s own perspective and concerns. For these technologies to provide well being for the citizens, innovation must be rooted in the local realities. Thus more participatory approach is needed where innovation are seen as part of broader system of governance and markets that extends from local to national , regional and international levels . No doubt this will increase access and indeed ownership for sustainability.

I have tried above to present historical perspective of the development of science and then not only to underscore but also to underpin policy issues and capacity building together with citizen engagement for sustainability in order to guarantee achieving both goals and the desired result. My conclusion is that it is vital to ensure well being of the society than so called wealth creation by providing the necessary infrastructure and an enabling environment. I have no doubt that Science, Technology and Innovation will make lasting contribution in these efforts to by engaging citizens and incorporating of traditional and indigeneous knowledge and technology.

BIBLIOGRAPHY

1. Malo J. O., Physics and Industrial Development, 3rd Regional ANSTI Seminar in Physics, 5 – 7 August, Gaborone, Botswana

2. Malo J. O., Capacity building in Science and Technology :The African perspective, International Conference on Physics and Industrial Development- Bridging the Gap, 17- 19 January ,1994, New Delhi , India
3. Malo J. O., Physics in Africa World Congress of Physical Societies, 17- 22 September 2000
4. Malo J. O., Major constraints in Application of Science and Technology in National Development- The African Perspective, COPID 200, Durban, South Africa, 4-7 September 2000
5. Malo J. O., Physics in Contemporary World: The African Perspective: Third World Congress of Physical Societies, Berlin, Germany 15- 16 December 2000
6. ICSU, Report on New Genetics, Food and Agriculture: Scientific Discoveries – Societal Dilemmas, 2003
7. Inter Academy Council (IAC), Inventing a Better Future: A Strategy for Building Worldwide Capabilities in Science and Technology, January 2004
8. Prof. E. O. Odada, A Strategy for Global Environmental Change Research in Africa : Science Plan and Implementation Strategy, 2000 PASS Secretariat, Nairobi, Kenya.
9. Malo J. O., Technology Development and Citizen Engagement; Career Development in Bioengineering and Biotechnology, 2008, USNAS