Biofuels – a new challenge for nutritional science?


Public Health Nutrition: 12(12), 2533 –2535 doi:10.1017/S1368980009991959

Invited commentary

Biofuels – a new challenge for nutritional science?

‘Food is basically a net product of an ecosystem, however

simplified. Food production starts with a natural material,

however modified later. Injections of energy (and even

brains) will carry us only so far. If the population cannot

adjust its wants to the world in which it lives, there is little

hope of solving the food problem for mankind. In that case

the food shortage will solve our population problem.’(1)

Food crisis, energy crisis or water crisis?

Today the dominating global interest seems to be devoted

to the energy situation, oil prices and their impact on the

global financial situation. This may be why there is now

so much interest in finding alternatives to oil as the main

energy source.

Debate on the world’s future is still dominated by people

from the industrialised world, but the real priority from a

global perspective still is food and water for survival and

optimal health for humankind. Energy comes much lower

on the priority list for human survival. Dependence on oil is

essentially a recent problem in affluent societies. Energy

from the petrochemical industry is a helper but is not the

most essential component for food production.

During the last decades there has been more interest in

global water resources and on the impact of human activ-

ities on the global water system(2). The impact of the cost of

water on food production and food availability is a fun-

damental challenge for nutritionists. The introduction of the

‘virtual water’ concept, and concern about the costs of

water in export agriculture, indicate that environmental and

socio-economic impacts of virtual water trade may well

dominate political discussion in future.

Optimal production of biofuels

The need to analyse energy efficiency in food production

became more acute as a result of the energy crisis in the

1970s(1). Now there is increased interest in the production

and use of biofuels. But we need a more holistic view,

balancing the use of primary resources in farming areas

for production of biofuels and with that for food and feed

production.

Efficiency in energy conversion should also be

addressed during all stages, from production of crops and

their conversion into various energy sources such as

ethanol, methanol and diesel, to distribution of biofuels to

the final consumer. For example, today most of the

ethanol used in Swedish cars comes from Brazil, because

the ethanol in Sweden derived from wheat is much less

cost-effective. But energy costs for transport from Brazil

to Sweden and for distribution of ethanol in Sweden

should also be taken into consideration.

We are still at the beginning of developing biofuel

technology. Priority is now given to finding alternatives

for power trains in vehicles, and to reduce the need for oil

importation in the transport sector. So far the production

of biofuels has been based on corn, wheat, soya, sugar

cane and sugar beet, and (for diesel) from oil seeds such

as rapeseed and palm oil. But these are all staple or

common foods or ingredients. Interestingly although

potato is one of the crops with highest energy yield, it is

not much discussed as an energy source in biofuel

production, and nor is cassava, another energy-rich crop.

From the nutritional point of view this is just as well, for

it reduces the risk of a conflict with their roles as staple

foods.

It is not only foods that can be sources of biofuels.

Waste products from rapeseed cakes and straw have great

potential, as does sewage treatment and the forestry

industry. These alternatives involve less conflict between

production of biofuels and production of food crops.

Hybrid and battery-powered electric vehicles and fuel cell

vehicles are alternatives to conventional internal com-

bustion engine vehicles using alternative biofuels such as

ethanol, methanol and biodiesel(3).

Starving people are paying for the economic crisis

‘The evidence now before us – of a world which can

produce automobiles, television setsy at a greater speed

than the increase in population, but is simultaneously

menaced by mass starvation – is disturbing.’(4)

The global economic turmoil during the last two years

demonstrates the incompetence of economists and policy

makers to handle the socio-economic situation. The stage

has been set for those who play vast pyramid or mono-

poly games. In many respects the economic crisis today is

artificial, started by unethical gamblers on the stock

market. It is not a result of a sudden and unforeseen crisis

in the availability of primary resources for feeding a

population. After all, it is food and water that represent

our basic needs. We do not drink oil, nor do we eat dollar

or euro notes. It is a luxury crisis. It means that we have to

reduce our overconsumption of cars and luxury products,

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and this leads to unemployment, malnutrition and public

health problems.

But the price is not paid by the affluent societies or the

rich. The chief executives who have led our companies

into ruin and bankruptcy are overpaid, and in some cases

even receive extra bonuses if they leave the job they did

not manage to handle. Those who have to pay for their

mismanagement are impoverished people in low-income

countries, who face increased prices of food. Increased

malnutrition is the result of economic mismanagement.

Starving people usually do not dream of having a car.

Why are the food and drink and associated industries

still considered as positive forces in policy making,

whereas the interests of consumers and of health are

regarded as burdens on society? When will human capital

in the form of a healthy population be more valued than

industrial production of luxury products, which may

solve short-term economic problems but often include

environmental problems? Why are ministers of industry,

agriculture and trade ranked higher than ministers of

social welfare? How can politicians discuss solutions to

correct maldistribution of primary resources, when they

do not know what the basic needs are?

Why have nutritionists failed to influence

food policy?

We nutritionists have failed to get our messages accepted

by politicians. One reason may be that those involved in

macroeconomic and international policy and trade are

seldom undernourished. Undernutrition of protein or

energy, or micronutrient deficiency, rarely afflicts politi-

cians or UN personnel. On the contrary, they might have

a problem of overnutrition, showing as obesity, CVD,

type 2 diabetes and cancer. Interestingly these diseases

are still not taken very seriously as major public health

problems by policy makers, although they dominate the

causes of death in the affluent societies and now

increasingly in lower-income countries.

Since the Second World War our focus on major nutri-

tional problems has changed from a focus on protein needs

to energy needs. Such a change has had and still has an

enormous impact on the direction of agricultural policy.

Better knowledge about the primary nutritional needs

in relation to the potentials of agricultural production

must be based on public health perspectives rather than

on strict agro-economic aspects or farmers’ income. Two

crops, potato and cassava, imported from Latin America

to Europe and Africa beginning in the 16th century,

illustrate the role of nutrition for socio-economic devel-

opment. They have probably saved more lives than any

macroeconomic policy actions. It was the introduction of

potato from the Alto Plana region in Latin America that

helped the farmers of Ireland to solve their subsistence

farming and also to some extent cash production. But

it was also monoculture of the highest-yielding potato

crops as cash crops to solve short-term economic problems

of the poor, in combination with crop failure, that resulted

in the great Irish famine. Cassava, on the other hand, was

blamed for its low protein content during the 1970s as

aggravating protein malnutrition, until its great potential

as a cheap and easily available energy source was

revealed and cassava became recognised as a life saver in

low-income countries and communities.

Nothing is new under the sun

Nutrition science is often said to be a new discipline.

Nothing could be more wrong. The burden of deficiency

diseases was the primary focus of medicine for many cen-

turies until the pharmacological era of the 20th century. The

development of biochemistry during the 19th and 20th

centuries focused on the metabolic processes in the body,

including the roles of nutrients, trace elements and vitamins,

and a number of scientists directly or indirectly engaged in

the vitamin and nutrition sector won Nobel prizes.

Who can solve nutrition problems?

In the 20th century nutritionists observed endemic and

epidemic malnutrition in the countries now described as

the low-income countries. Some realised that the cause

was maldistribution of resources. However, nutritional

problems are multifactorial and have to be approached in

a transdisciplinary and intersectoral way. Nutritionists

cannot solve global problems by themselves. Nor can

those skilled in anthropology, political or cultural issues

evaluate priorities in food production or public health,

without help from the nutritional and agricultural sciences.

When people identified as policy and socio-economic

experts entered the field, they started by discussing

macroeconomic solutions, and relegated medical people

and nutritionists to deal with marginal micro-problems.

Some administrators within the UN system still argue that

nutritionists have no role to play in solving the global

nutrition problems, and call for socio-economic mea-

sures(5). It has even been argued that knowledge of

human nutrition simply is of no importance. Thus: ‘Much

more important is knowledge and experience in for

example anthropological and cultural issues, political

analysis, communication and mobilization skills’. This is

an alarming and astonishingly short-sighted statement.

It was the nutritionists and physicians who called for a

holistic view on prevention of malnutrition, and for help

from anthropologists and socio-economic experts. Eco-

nomic progress does not necessarily lead to improved

nutritional status. Malnutrition persists even in apparently

food-secure households. Physicians have shown the evil

circle between malnutrition and infection, and also the

long-term effect of malnutrition on mental and physical

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development. The macroeconomists and the socio-

anthropologists did not do this.

High infant mortality caused by introduction of breast

milk substitutes in low-income countries as a result of

marketing efforts from big multinational companies, was

identified by doctors and nutritionists. It was they who

led the battle against the marketing actions from multi-

national food companies, not the policy makers nor the

socio-economic administrators.

Time for nutritionists to engage in the debate

on biofuels

The new interest in production of biofuels is a challenge

to us all. In the enthusiasm to test new approaches to

solve global energy problems, we must analyse long-term

perspectives and indirect effects on other markets.

Just as we earlier got misled in evaluation of the role of

cassava for human nutrition, there is now a great risk that

the interest for production of biofuels may conflict with

interest for optimal food production. Increased production

of biofuels may be deleterious for food production if the

wrong crops are chosen. But it could also increase eco-

nomic power in agricultural production and thereby help to

increase food security. Optimal use of production area thus

calls for optimal selection of crops under prevailing cir-

cumstances, which can increase efficiency in food pro-

duction, transport, food industry and food handling.

We need sustainable energy systems. But we also need

increased cooperation between nutritionists and agri-

cultural scientists, and those involved in the development

of sustainable biofuel technology. Increase in energy

resources must be combined with reduction of malnutri-

tion and poverty. A systems approach is needed, whereby

nutritionists, agronomists and those engaged in technical

change and innovation within the bioenergy sphere, all

work together.

Sustainable food production calls for sustainable

energy resources. We must support increased cooperation

between disciplines from all fields involved in optimal

socio-economic development and also public health

protection. Bridges need to be built by broad-minded

scientists who are well established within their respective

disciplines, and open-minded policy makers. This will

stimulate interdisciplinary approaches to solve the future

problems of humankind regarding energy availability and

access to food for everybody.

So what is to be done?

> Defend the value of human capital for development of

society against the dominant over-evaluation of indus-

trial production by politicians and macroeconomists.
> Identify the dominant nutrition and public health

problems in various societies, to support policies that

help vulnerable groups and lead to optimal health for all.
> Find the best balance between dietary recommenda-

tions and the potential resources for food production,

especially in respect of small and family farmers.
> Stimulate sustainable agricultural production by balancing

production costs with costs for transport, distribution and

storage, in small- as well as large-scale production.
> Engage with energy environmental scholars, to find the

best balance between food crops, feed crops and

energy crops for sustainable agricultural production.

With this ambition, and an innovative scientific

approach to develop sustainable energy and food pro-

duction, we can together solve the problems for feeding

the world population with food and energy for tomorrow!

Leif Hambræus

Unit for Public Health Nutrition

Department of Bioscience and Nutrition

Novum, Karolinska Institutet

SE-141 57 Huddinge, Sweden

Email: leif.hambraeus@ki.se

References

1. Steinhart CS & Steinhart CE (1974) Energy use in the U.S.
Food System. Science 184, 307–316.

2. Hoekstra AY & Hung PO (2004) Globalisation of water
resources: international virtual water flows in relation to
crop trade. Global Environmental Change 15, 45–56.

3. Åhman M (2001) Primary energy efficiency of alternative
powertrains in vehicles. Energy 26, 973–989.

4. Georgescu-Roegen N (1971) The Entropy Law and the
Economic Process. Cambridge, MA: Harvard University Press.

5. FSN Forum discussion (2009) Putting people first: nutrition,
a key to integrated programming for poverty reduction?
1st December 2008 to 10th February 2009. http://km.fao.org/
fileadmin/user_upload/fsn/docs/PROCEEDINGS_Nutrition_
Integrated_programming.doc

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