Post on 03-Jun-2020
SWITZERLAND
This research was funded by the Austrian, German, Norwegian, Korean, and Swiss Governments through the World Bank’s Multi-Donor Trust Fund for Labor Markets, Job Creation, and Economic Growth.
The findings, interpretations, and conclusions expressed in this paper are entirely those of the authors. They do not necessarily represent the views of the International Bank for Reconstruction and Development/World Bank and its affiliated organizations, those of the Executive Directors of the World Bank or the governments they represent, or the donors supporting the Trust Fund.
The brain drain of health professionals has become a source of concern for many developing
countries and international organizations. The World Health Organization estimates the current global
shortage of health workers at more than 4 million. From a global perspective, therefore, the medical
brain drain could be seen as a matching process through which workers are allocated to places
and jobs where they are most productive. This process is not recent but has accelerated recently:
it is estimated that expatriated doctors now constitute more than 20 percent of the stock of medical
doctors in the OECD (30% in countries such as Ireland or the UK, and more than 50% in the Gulf
States); there are currently more Ghanaian-born doctors living in London than in Ghana, and more
Filipino nurses in the US than in Manila.
In this note we focus on the emigration of physicians from developing countries. We first describe
the magnitude and intensity of the physician brain drain (PBD) and analyze its determinants. We then
survey the existing literature on the possible existence of a physician “brain gain” and characterize
some of the channels through which physicians’ emigration can damage health outcomes in sending
countries. Finally, we conclude by examining a number of policies that have been suggested recently
to curb the PBD in the light of our findings.
Physician Brain DrainSize, Determinants and Policy Issues
Frédéric Docquier Hillel Rapoport
1
Physician brain drain: size, determinants and policy issues1
Frédéric Docquiera and Hillel Rapoport
b
a FNRS and IRES, Université Catholique de Louvain
b CID, Harvard University, Bar-Ilan University and EQUIPPE
The brain drain of health professionals has become a source of concern for many
developing countries and international organizations. The World Health Organization
estimates the current global shortage of health workers at more than 4 million. From a
global perspective, therefore, the medical brain drain could be seen as a matching
process through which workers are allocated to places and jobs where they are most
productive. This process is not recent but has accelerated recently: it is estimated that
expatriated doctors now constitute more than 20 percent of the stock of medical
doctors in the OECD (30% in countries such as Ireland or the UK, and more than 50% in
the Gulf States); there are currently more Ghanaian-born doctors living in London than
in Ghana, and more Filipino nurses in the US than in Manila.
In the face of such figures, it is legitimate to ask two simple questions:
1. Could it be that, instead of narrowing the global shortage of healthcare workers,
the medical brain drain actually contributes to increase such shortages,
especially in developing countries? To a large extent, the answer to this first
question will depend on whether the emigration of health workers is caused by
push or by pull factors; in the spirit of the new brain drain economics (Stark,
2004, Docquier and Rapoport, 2011), it will also depend on whether migration
prospects generate more investment in medical education, i.e. drive more
people to invest (or people to invest more) in medical studies.
2. Is market-wage a good proxy for the social contribution of medical workers? As
we know, health has a dimension of public good, which implies that the
allocation of health workers through market wages may not be globally optimal.
Prospective doctors/migrants make their education and migration decisions on
the basis of private costs and benefits (including the weight they put of their
patients’ health and wellbeing); an efficient allocation, on the other hand, should
be based on the social marginal returns to health professionals’ education and
practice.
1 We thank Xushi Liu for excellent research assistance. This article is part of a research project on "Brain
drain, return migration and South-South migration: impact on labor markets and human capital"
supported by the Austrian, German, Korean, and Norwegian governments through the Multi-donor Trust
Fund on Labor Markets, Job Creation, and Economic Growth administered by the World Bank's Social
Protection and Labor unit.
2
In this note we address these two questions focusing on the emigration of physicians
from developing countries. We first describe the magnitude and intensity of the
physician brain drain (PBD) and analyze its determinants. We then survey the existing
literature on the possible existence of a physician “brain gain” and characterize some of
the channels through which physicians’ emigration can damage health outcomes in
sending countries. Finally, we conclude by examining a number of policies that have
been suggested recently to curb the PBD in the light of our findings.
How big is the physician brain drain?
The collection of comparative data on the physician brain drain is very recent; to the
best of our knowledge, it includes only three datasets: Clemens and Pettersson (2006),
OECD (2006), and Bhargava, Moullan and Bhargava (2010), an extension and
harmonization of Bhargava and Docquier (2008). The first data set focuses on African
countries and provides information on physicians and nurses’ emigration stocks and
rates by country of birth in 2000; to do so they aggregate data on foreign physicians and
nurses from nine important destination countries (UK, US, France, Australia, Canada,
Portugal, Belgium, Spain and South Africa). The second dataset also measures physicians
and nurses’ emigration stocks but does so for all the regions of the world, by country of
training, and for the year 2005. Finally, the third dataset is also about emigration stocks
by country of training for all countries but is for physicians only and adds a panel
dimension as stocks are measured on a yearly basis for the period 1991-2004. More
precisely, the Bhargava, Docquier and Moullan (henceforth BDM) (2010) dataset
contains data on foreign physicians collected from 17 host countries (16 OECD countries
and South Africa) and defines migrants according to their country of training. The data
are obtained from national medical associations and are available on an annual basis.2
On total, BDM come up with 14 yearly observations per country covering all the
countries of the world for the period 1991-2004. As shown on Figure 1, regional
comparisons reveal that PBD rates are highest in Sub-Saharan Africa (with average rates
above 20% against 13% in South-Asia and less than 10% in all the other regions), and in
smaller Pacific and Caribbean islands. The PBD rates are relatively stable over the
period, except in Pacific islands. In absolute terms the main “exporters” of medical
doctors are India and the Philippines, followed by two rich countries (Canada and the
UK), as shown on Table 1. Figure 2 lists countries exhibiting the highest physicians’
emigration rates. Clearly, small islands of the Caribbean (Dominica, Grenada, Saint Lucia,
2 Focusing on the year 2000, the comparison with Clemens and Pettersson (2006) reveals important
differences, with a correlation between the two of only .23. The “bilateral” correlations between
physician immigrants stocks in the eight common destination countries are much higher (from 55 percent
for South Africa to 97 percent for France and the United States). However, the stock based on country of
training is usually much lower than the stock based on country of birth (e.g., 10% in France -- licensure
requirements for foreign physicians are more stringent in France than in most other host countries --, 45%
in South Africa, 77% in the United Kingdom, and 82% in the United States).
3
Saint Kitts and Nevis, Antigua and Barbuda, etc.) and of the Pacific (Fiji) show the highest
PBD rates. There is a risk of overestimation for these countries as they usually host a
regional training center. On the other hand, some countries have no medical school and
exhibit zero PBD rates (e.g., Bostwana). This is clearly a drawback in using country of
training for defining migrants. This bias would be eliminated using data by country of
birth, as in Clemens and Pettersson. However, the latter include children migration
which most likely represents an important fraction of total immigration for certain
countries. Finally, we note that many sub-Saharan African countries are among the most
affected (such as Liberia, Zimbabwe, Ghana or Malawi), as well as some small European
countries (such as Ireland and Iceland).
Figure 3 shows the geographical distribution of the physician brain drain computed in
BDM (2010) in relative terms (Figure 3a) and in terms of change between 1991 and 2004
(Figure 3b). One can see that physician brain drain rates have increased dramatically in
many African countries; overall there is a lot of persistence in PBD rates (regressing
2004 rates on 1991 ones gives a R2 of .75), and no sign of either convergence or
divergence in PBD rates (regressing percent changes between 2004 and 1991 on the
initial rates gives a R2 of .06).
[Insert Figures 1 - 2 -3 and Table 1 about here]
What drives the physician brain drain?
As is the case for general migration, it is obvious that the emigration of physicians is not
an exogenous process. Individual-level surveys in six African countries indicate that
more than half of all physicians would like to emigrate to developed countries, in search
of better working conditions and more comfortable lifestyles (Awases et al., 2003). The
risks associated with caring for HIV/AIDS patients and the possibility of children of
healthcare staff contracting HIV as they enter adolescence may exacerbate the physician
brain drain (Awases et al., 2003; Bhargava, 2005). It is common in migration studies to
divide migration determinants into “push” and “pull” factors. For example, Mayda
(2008) analyzed the role of push and pull factors in international migration, showing
that the impact of push factors on aggregate emigration rates (without educational
breakdown) is relatively small compared to distance and to pull factors.
Docquier, Lohest and Marfouk (2007) and Docquier and Rapoport (2011), on the other
hand, analyzed the determinants of international migration at different education
levels. Focusing on the highest segment (tertiary education, or brain drain), they
decomposed the high-skill emigration rate between two multiplicative components, the
ratio of emigrants to natives (or “average emigration rate”) and the ratio of the
proportion of highly skilled among emigrants to their proportion among the native-born
(or “selection bias”). Focusing on developing countries, Docquier, Lohest and Marfouk
(2007) found the brain drain to increase with the degree of religious fractionalization at
origin (via the selection bias) and to decrease with the level of development at origin
4
(the effect on the selection bias dominates the effect on openness). The size of the
country also matters: small states appeared to be more open than large countries.
Comparing developing and developed countries, Docquier and Rapoport (2011) found
that the coefficients in the two samples have similar signs but different magnitudes.
Unsurprisingly, the brain drain from high income countries appeared to be less
responsive to distance and to other geographic characteristics, which is probably due to
the better ability of rich countries residents to pay for migration costs. The selection
bias, on the other hand, is less responsive to immigration policies at destination and to
the level of development. The latter result, however, may simply reflect a mechanical
effect of human capital on the selection bias. Indeed, when the proportion of tertiary
educated people increases, high-skill and total emigration rates tend to converge (from
the decomposition above, it is clear that the selection bias mechanically tends to one as
the proportion of highly skilled increases). Finally, the degree of openness in rich
countries did not appear to depend on the level of development (which is more
homogenous in the high-income sample).
To explore the determinants of the PBD we will first analyze these determinants in a
panel setting for the full sample of countries in the BDM (2010) data set. We will then
ask whether the physician brain drain is driven by the same forces as the general brain
drain or by different forces. For this we will restrict the analysis to a sample of African
countries as we need the data on the general brain drain (defined by country of birth
and available only for two years, 1990 and 2000) and from the physician brain drain
(taken also from Clemens and Perdersson (2006)) to coincide in both their cross-
sectional approach, their geographical coverage and their definitions of who is a migrant
(defined as foreign-born).
Panel estimation for developing countries. We first consider dynamic panel estimation of
the determinants of the PBD. For country i at time t, we use the stock of physicians
abroad, Mi,t, and at home, Hi,t, taken from Docquier and Bhargava (2006). We define 4
sub-periods of 3 to 4 years: 1991-94, 1995-97, 1998-2000, 2000-2004. Given that when
one push-pull factor changes, stocks are likely to adjust only slowly, a beta-convergence
model seems appropriate. We therefore estimate the following econometric model:
ln Mi,t – ln Mi,t-1 = ai + b.ln Mi,t-1 + c.Xi,t,
where Xi,t is a set of explanatory variables (population, medical wages, gdp per capita,
instability, health variables, etc.), ai is a country fixed effect, and 0<-b<1 captures the
speed of convergence toward the steady state.
Since Mi,t-1 is used to construct the dependent variable and is also on the right-hand
side, there is a risk of endogeneity (Nickel bias). In Table 2, we consider 4 specifications
and instrument Mi,t-1 with Mi,t-2: specification (1) uses the full sample and a limited set of
controls (155 countries out of 189 in Docquier and Bhargava (2006) and 309
observations) and a simple IV method (instrumenting physicians’ emigration by its one-
period lag). Specification (2) is identical to specification (1) except that it includes two
additional controls, the wage for physicians and HIV prevalence; due to missing values
for some countries, this reduces the sample to 89 countries (172 observations). Given
5
that the latter specification includes only a relatively small subset of countries (89 out of
189), in specification (3) we run a model with random effects. Finally, in specification
(4), we defined all time-variant explanatory variables as predetermined (instrumented
by their own lags) and run a 2-stage least square panel analysis with random effects,
using a GMM estimator. Table 2b has the same structure but focuses on developing
countries (124 countries and 248 observations in the largest sample).
[Insert Table 2a and 2b about here]
Both for the full sample (Table 2a) and the sub-sample of developing countries (Table
2b), the results show evidence of convergence as the coefficient on past emigration
level is negative, very significant and stable over specifications. The number of
physicians per thousand inhabitants at home is positive and also very significant,
suggesting a supply-push to the PBD, an interpretation supported by the fact that the
coefficient on public expenditure on higher education is also positive and significant. In
contrast to analyses of the brain drain in general, country size appears to stimulate the
PBD (however, this could be an artifact due to our consideration of countries of training
only). Finally, as expected, the prevalence of HIV-AIDS is also favoring a higher PBD, but
physicians’ wages do not seem to play any role. This result could be driven by the
collinearity between physicians’ wages and GDP per capita. Indeed, heterogeneity in
levels of total factor productivity is the main source variation in skill prices across
countries. We will now ask whether these results are weakened or strengthened when
we focus of our main region of interest, Africa.
African PBD: cross-sectional results. For this second exercise we restrict our sample to
African countries. In addition to analyzing the determinants of the African Physician
Brain Drain (henceforth APBD), which we perform in the first two columns of Tables 3a
and 3b, we also want to analyze whether the APBD is more or less impacted by certain
push and pull factors than the general brain drain out of Africa, and why.
To do this we apply the method used by Docquier, Lohest and Marfouk (2007) for the
general brain drain and decompose the African physician brain drain into two
multiplicative components:
+
+
×
+
≡
+
≡coll
ti
coll
ti
phys
ti
phys
ti
coll
ti
phys
ti
coll
ti
coll
ti
coll
ti
phys
ti
phys
ti
phys
tiphys
tiMH
MH
M
M
MH
M
MH
Mm
,,
,,
,
,
,,
,
,,
,
,/
where the first multiplicative component is the ratio of emigrants to natives among
skilled workers (coll stands for college graduates, and phys stands for physician doctors),
that is, the average high-skilled emigration rate (or “degree of openness to skilled
emigration”) and the second multiplicative component is the ratio of the proportion of
doctors among highly skilled emigrants to their proportion among the native college
graduates (or “selection bias”).
We consider a cross-section framework because our sources of data for the general
brain drain are Docquier and Marfouk (2006) and its extension to correct for age of
entry in Beine, Docquier and Rapoport (2007). Docquier and Marfouk (2006)
6
constructed a global bilateral database of South-North and North-North migration (from
195 origin countries to 30 OECD countries) for three levels of education, and for 1990
and 2000. Beine, Docquier and Rapoport (2007) extended this data set for the highest
(tertiary) education level; the latter collected data on the age of entry structure of
immigration, and used age of entry as a proxy for whether education was acquired in
the home or in the host country. Since such data was not available from all OECD
receiving countries, their data set combines observations (for 75 percent of the sample
size) and estimations of the age of entry structure of the remaining 25 percent using a
gravity model.
For the African PBD we will use both BDM (2010), as above, and also Clemens and
Pettersson (2006), who collected data on foreign physicians from nine important
destination countries (UK, US, France, Australia, Canada, Portugal, Belgium, Spain and
South Africa) and computed the stock of African-born physicians living abroad by
country of birth in 2000. They then evaluate the physician brain drain in relative terms,
dividing the number of physicians abroad by the total number of physicians born in each
origin country. It is important to consider PBD data by country of birth for two reasons:
for robustness and for interpretation of any differences with the results obtained using
PBD data by county of training.
For the empirical analysis we will match the different data sets as follows. In Table 3a,
we match Beine, Docquier and Rapoport (2007) with BDM (2010), that is, the PBD data
by country of training coupled with estimates of brain drain rates at age 22 or more (i.e.,
obtained after excluding those who were younger than 22 at the time of immigration).
In Table 3b, we use Docquier and Marfouk (2006) and Clemens and Pedersson (2006), as
both define migrants by country of birth. The odd columns in Table 3a and 3b give the
results for the full model while the even columns give the results for the parsimonious
specifications.3
[Insert Table 3a and 3b about here]
Focusing on the results of the parsimonious specifications for the APBD by country of
training (and using the regressions by country of birth for comparison and robustness), a
number of interesting results appear:
First, GDP per capita has the expected negative sign for both the general and physician
brain drain; note that the latter is more impacted by differences in country income
levels, as shown by the negative sign for the coefficient on the selection bias (which is
not negative enough though to make the coefficient on GDP per capita negative and
significant in the PBD regressions by country of birth). Wage differences, on the other
hand, are insignificant is all specifications. The latter result can be driven by collinearity
between wages and GDP per capita, as stated above.
Second, the geographical variables are also generally significant and have the expected
signs: negative for landlock status for both the physician and general brain drain (with
the former being less negatively impacted in the regressions by country of birth) and
3 Parsimonious specifications are obtained after sequential elimination of insignificant variables.
7
surface area, positive for small island status (but less positive due to a negative
coefficient on self-selection) but only in the country of birth regression.
Third, the selection bias of physicians vis-à-vis all tertiary educated is significantly
affected by the population size: negatively in the regressions by country of birth and
positively in the regressions by country of training: this is consistent with a “supply-
push” interpretation, as already suggested for the panel results on developing country.
Recall that demographically larger countries are more likely to host medical schools and
train physicians from smaller countries.
Third, additional push factors seem to play an important role: the prevalence of HIV-
AIDS in the regressions by country of training, and the degree of ethnic fractionalization
in the regressions by country of birth.
The case for a physician “brain gain”
In the spirit of the recent literature on endogenous human capital in a context of
migration (e.g., Beine, Docquier and Rapoport (2008)), we may ask whether there is a
chance for a net medical brain gain. Regressing the log of domestic physicians per capita
on the log of physician emigrants per capita in a sample of African countries, Clemens
(2007) found a positive correlation of about 70 percent. Clearly, this correlation can be
driven by the simultaneous effects of observed variables (GDP per capita, school
enrolment, ethnic conflicts, etc.) or unobserved variables. However, after controlling for
observables and instrumenting the number of emigrants, the causal effect of emigration
becomes insignificant. This analysis fails to detect any negative effect of health
professionals’ emigration on the supply of healthcare staff in Africa in a cross-section
analysis based on 53 observations. The author attributes this result to the positive effect
of emigration prospects on enrolment in medical schools.
The absence of negative effect of emigration on domestic physicians’ stocks could also
be due to omitted variables such as the size (and quality) of the medical training system.
Physician emigration is instrumented with country size and linguistic links. However,
data reveal a strong correlation between country size and both the number of medical
schools (82 percent) and the annual number of domestically-trained medical graduates
(60 percent). In addition, the number of schools and graduates are significantly higher in
English-speaking countries and/or UK former colonies. Hence, it is very likely that
country size and linguistic linkages exert a direct impact on the domestic supply of
health workers. This relationship obviously needs to be explored in more detail in future
research.
Three other studies examine the interactions between medical education and migration
decisions in developing countries; they deliver interesting results for developing
countries in general, and for low-income countries in particular.
8
The first study, by Kangasniemi et al. (2007), documents the incentive mechanism in the
medical sector using a survey of overseas doctors working in the United Kingdom. The
authors show that 28 percent of the Indian doctors surveyed (the largest group in their
sample) acknowledge that the prospect of emigration affected their education
decisions. This proportion increases to 29 percent for physicians originating from
middle-income countries and to 37 for those originating from low-income countries. In
addition, the physicians surveyed estimate that among medical students currently
studying in the home country, the proportion of students for which emigration
prospects affected their decisions as to whether and what to study is very high
(estimated proportions are 36 percent for India, 46 percent for low-income countries
and 41 percent for middle-income countries). Given these figures, we cannot exclude
the possibility that incentive effects are large enough to increase the net supply of
physicians in origin countries. A necessary condition for a “brain gain” is that the
additional human capital formed thanks to the prospect of emigration exceeds the
human capital lost through actual emigration. The survey responses in Kangansniemi et
al. (2007) suggest that such a possibility is not unrealistic for a large number of low-
income countries, including many African ones. This is notwithstanding other potential
benefits to home countries through remittances and return migration: the survey also
shows that a large fraction of expatriate physicians send substantial remittances, and
many intend to return after completing their training or gaining work experience in the
UK.
In the second study, Defoort (2010) regresses the change in the number of native
physicians on past medical emigration rates in logs. She took advantage of the panel
structure of the Bhargava-Docquier’s data set and worked with 5 observations per
country (one observation every 3 years). Using different methods (fixed effects v.
random effects, GLS, IV, GMM), she found evidence of a positive incentive effect,
especially in Sub-Saharan African countries. Using counterfactual simulations as those
used by Beine et al. (2008) for the general brain drain, she found an optimal physician
brain drain rate of about 10 percent and concludes that only 20 African countries
actually suffer from the physician brain drain while about 30 countries would actually
gain (in terms of physicians per capita) from an increase in medical emigration rates.
The above result is driven by the log specification of the incentive mechanism. At low
levels of PBD, the elasticity of medical training to PBD is very large. Using PBD data by
country of training, many developing countries exhibit very low emigration rates. In a
third study, Bhargava, Moullan and Docquier (2010) use a slightly different specification
with log(1+PBD) at the right-hand side. This avoids unrealistic marginal incentive effects
for countries with MBD around or below 1 percent. Again, there appears to be a positive
incentive effect of migration prospects on medical training. However, the effect was too
small to generate a net brain gain so that MBD mainly reduces the number of physicians
in developing countries.
Another argument militating against physician brain gain is that migration prospects not
only affect the number of physicians but also their fields of study. From this perspective,
a clearly negative effect of the brain drain, recognized long ago (e.g., in the pages on the
9
“brain drain” in Todaro’s “Economic Development” textbook’s early editions) is that it
can drive prospective doctors toward medical fields which have low social value at
home but are highly valued in rich countries. As Lucas (2004) puts it (while observing the
case of the Philippines), “It is difficult to believe that these high, privately financed
enrolment rates are not induced by the possibility of emigration. There are signs that
the choice of major field of study ... responds to shifts in international demands. Higher
education is almost certainly induced to a significant extent by the potential for
emigration.” For example, medical students contemplating emigration may specialize in
geriatrics or in cardio-vascular diseases rather than in pediatrics or tropical diseases,
thereby contributing more to “brain waste” than to “brain gain”.
In summary, the existing literature is not conclusive as to whether the emigration of
physicians lowers or increases the net supply of physicians at home: the results from
empirical studies depend on data sources or empirical specifications; once incentive
effects are taken into account, there is no strong evidence of either a physician brain
drain or brain gain.
PBD and health outcomes
In developing countries, the size and quality of the medical sector is a key determinant
of human development and economic performances (see Bhargava et al., 2001,
Hagopian et al., 2004, Cooper, 2004, Bhargava and Docquier, 2008). While the number
of physicians per 1,000 people is greater than 3 in most industrialized countries, it is
lower than 0.25 in a large number of developing countries. Many observers and analysts
have pointed to the physician brain drain as one of the major factors leading to the
under-provision of healthcare staff in developing countries (see Bundred and Levitt,
2000, Beeckam, 2002, Johnson, 2005, Eyal and Hurst, 2008) and, ultimately, to low
health status and shorter life expectancy – hence Michael Clemens’s (2007) provocative
question: do visas kill?
Since 1990, the world’s countries and leading development institutions have agreed on
a set of “Millennium Development Goals” (MDG). The Millennium Declaration, signed in
2000, established 2015 as the deadline for achieving the MDG. The eight goals include
specific health targets: (i) reducing by two thirds the mortality rate among children
under five, (ii) reducing by three quarters the maternal mortality ratio and achieving
universal access to reproductive health, (iii) combat HIV/AIDS, malaria and other
diseases. Much progress has been made in reducing maternal deaths in developing
regions, but not in the countries where giving birth is most risky, and many countries are
still falling short of meeting the goals.
Is the physician brain drain partly responsible for these bad records? Using the
methodology described above, Clemens (2007) found no significant causal impact of the
numbers of physicians and nurses abroad on child mortality, infant mortality under age
one, vaccination rates or prevalence of acute respiratory infections in children under
10
age five. Chauvet et al. (2008) investigated the determinants of child mortality using a
sample of 98 developing countries from 1987 to 2004. In their benchmark full-sample
regressions, remittances strongly improve health indicators while health aid per capita
and the number of physicians per 1,000 people have no significant impact. However,
when interacted with the level of development, health aid commitments become
significant and help reducing child mortality in poorer countries, while the number of
physicians per 1,000 people has no significant impact. Interestingly, the supply of
healthcare staff does not significantly reduce infant and child mortality rates. However,
the physician brain drain is shown to significantly deteriorate child health indicators.
This suggests that emigrants could positively self-select out of the physicians’
population, with only the most talented obtaining a qualification abroad and leaving.
The only study we are aware of directly tackling the issue of physicians self-selection in
Africa is a recent paper by De Laat and Jack (2009) who use Ethiopia as a case-study.
They take advantage of a feature of the recruitment process of physicians in the public
sector of Ethiopia to estimate the extent of adverse selection in that sector. More
precisely, physicians’ first placements occur through a lottery, leading to self-selection
into the lottery while non-lottery participants apply mainly to private institutions. The
authors argue that such random placement does not allow for efficient signaling of
individual ability and therefore leads to adverse selection into the lottery, which is
indeed what they find using career and wage records of physicians who remain in the
public sector. They also find that within the group of lottery participants, the most able
tend to leave and are likely to account for a substantial part (one third) of the physician
brain drain out of Ethiopia.
Two other studies examine the effect of medical staffing and brain drain on human
development. Bhargava and Docquier (2008) assess the effect of PBD on the dynamics
of HIV prevalence rates and adult deaths from AIDS. They find no effect of PBD on the
long-run level of HIV prevalence, but a significant effect on deaths rates: a doubling of
the physician brain drain rate is associated with a 20 percent increase in adult deaths
from AIDS. Bhargava, Moullan and Docquier (2010) evaluate the impact of PBD on child
mortality and vaccination rates, allowing for quantity and quality effects (i.e., decrease
in the numbers and average abilities of the remaining physicians as in Chauvet et al.).
They show that infant and child mortality rates decrease with the numbers of physicians
per capita when adult literacy rates exceeded 60 percent, which is the case for the
majority of countries. The results for DPT and measles vaccinations again underscore
the importance of literacy rates and physicians per capita for higher vaccination uptake.
However reducing physician brain drain generates only small improvements in human
development indicators compared to the stated Millennium Development Goals.
In summary and as for the previous section, the existing empirical literature fails to
provide strong evidence of the effects of the APBD on health outcomes in Africa. Better
health indicators could probably be achieved by exploiting synergies between the
numbers of physicians and other factors such as availability of medicines, number of
nurses (for which the data are missing for many developing countries and years), and
medical equipment (such as hype syringe, latex gloves) and general infrastructure
11
(access to drinkable water, use of mosquito net, etc.). Increasing the supply of
physicians might be inefficient for some developing countries if the effective demand is
low due to poor infrastructure and/or political instability.
Policy implications and conclusion
The main insights from the above analysis may be summarized as follows:
i) A country’s stock of medical human capital is endogenous to the prospect and
realization of migration; this induces a theoretical possibility of beneficial
physician brain drain. Such a possibility is unlikely to materialize in the case of
the African physician brain drain for a least three reasons: first, there is
anecdotal evidence of brain waste when prospective doctors invest in fields
which may be disconnected from the needs of the local population; second there
is suggestive evidence of positive selection into migration among physicians; and
third, the empirical evidence on the sign of the net effect (i.e., whether the brain
gain effect compensates for the brain drain) is mixed and varies with the choice
of econometric specification.
ii) Physicians are just one in many arguments of the production function of
“healthcare” and are strategic complements of other factors such as medical
infrastructure, nurses and other health care personnel, medical equipment, etc.
Increasing the supply of physicians without increasing that of complementary
inputs is unlikely to significantly affect health outcomes.
iii) Retaining more home-trained physicians implies taking into account the pull and
push factors that determine physicians’ emigration decisions. The evidence here
is a mix of good and bad news. On the good side, there does not seem to be
evidence of “chain migration” by which past physician emigration would fuel
future waves of expatriation. Also, physicians’ wages do not seem to be an
important drive; this may just reflect the lack of heterogeneity in physicians’
wages across Africa, however the fact that wage distance to the US is never
significant in the panel regression for the sample of developing countries as a
whole makes this latter interpretation improbable. On the bad side, the main
source of concern is probably the strong push effect of HIV-prevalence that
comes out for both the panel regressions for developing countries and the cross-
sectional results for African countries. Since HIV-prevalence is unlikely to
decrease substantially in the short run, this cast doubts on the potential for
active policies to effectively retain local physicians or convince expatriated
physicians to return.
Finally, one should recall that the results summarized in i), ii) and iii) likely affect
different countries differently, and so there is no “one size fits all” optimal policy
response to the physician brain drain. Existing policy responses, however, have adopted
12
uniform solutions and either focused on the prevention of physicians’ emigration or on
favoring the return of those who emigrated. We discuss these two policies separately.
Should MDs from poor countries be “blacklisted”? Preventing someone from emigrating
is extremely difficult and most likely entails adopting very repressive steps such as
sanctions on the remaining family, confiscation of any assets left, deprivation of
citizenship or right of return, etc. Still, many have recommended the creation of
blacklists of source countries from which it should be forbidden to recruit physicians,
nurses, health workers and, more generally, highly-educated individuals. On a general
note one should keep in mind that the countries generally cited as candidates for being
blacklisted are precisely those where emigration is quite often provoked by political and
racial conflicts and/or oppressive and corrupted governments. Constituting such
blacklists would deprive many developing countries professionals from their basic right
to escape oppression and extortion, and could even lead to higher political and
economic repression.4 Finally, such blacklisting of countries and professions may be
based on erroneous appreciations of the role of migration in explaining professional
shortages in developing countries. For example, a proposal to ban recruitment of health
professionals from Sub-Saharan Africa has gained wide support in many healthcare and
media circles;5 however, as we have seen, it is not clear that the physician brain drain is
decreasing the net supply of physicians in Africa, that decreasing physicians emigration
is feasible without seriously changing their environment, or that increasing the supply of
physician ceteris paribus has a positive health impact in Africa.
Is “brain circulation” a panacea? Another popular, even almost consensual policy
proposal is to encourage the “brain circulation” of MDs from poor countries, that is,
their return to the home country after some time, once they have acquired knowledge
and professional skills abroad that can eventually serve their home country. This would
seem the ideal solution. Most policy reports also emphasize, in line with our findings,
that brain circulation should be promoted through incentives to return and be
accompanied by an increase in the supply of complementary inputs (such as nurses,
infrastructures, medical equipment, etc.) and by policy action to affect the pull and push
factors that affected the PBD in the first place.6 Health organizations now emphasize the
need to move from brain drain to brain circulation, to let physicians from poor countries
emigrate freely while at the same time designing incentive packages for their return.
This is a big improvement over the previous proposal. However, the effectiveness of
such policies can be questioned on a number of grounds.
4 Docquier and Rapoport (2003) show that migration as an exit strategy can serve to tame oppressive,
rent-seeking governments. 5 See for example the editorial of a recent issue of the British Medical Journal, where the editor, James
Johnson, states that “the rich countries of the North must stop looting doctors and nurses from
developing countries” (Johnson, 2005). 6 See for example Physicians for Human Rights (2004).
13
First, wage gaps are so huge that it is unlikely they can be raised in the home country in
a way that significantly affects return decisions.7 Second, physicians who contemplated
wage increases when they made their emigration decision will face wage decreases
when contemplating return migration; given that preferences evolve over time and
people tend to have loss-aversion, any domestic wage increase for local physicians in
poor countries would probably affect the decision to migrate more than the decision to
return. The same rationale applies for other policy actions aimed at affecting pull and
push factors such as improved infrastructures, better governance of the public health
system or reduced risks associated with the high-prevalence of HIV-AIDS.
Another way of looking at brain gain and brain circulation, however, is possible and may
leave more room for optimism; it starts from the realization that ideas can move
without people physically moving. From this perspective, physicians do not differ
fundamentally from other highly educated professionals in terms of attachment to the
home country, willingness to keep return options open, and potential for taking part in
medical, scientific, business networks that serve as bridges between their home and
host country. A sensible policy recommendation, therefore, is to recognize that
preventing physicians’ emigration is not feasible (nor is it moral) and that hoping for
return migration is not a viable strategy unless the conditions at home evolve
drastically. As for the brain drain in general, it is preferable instead to favor brain
circulation by making emigration and remigration easier (e.g., through dual-citizenship
agreements)8 and, ultimately, by creating domestic networks that allow for quality
interactions with the expatriated networks. While this is easier said than done, there
seems to be a strong commitment at the bilateral and multilateral level to favor such
institutions building aimed at “harnessing the diaspora”, including the one formed as a
result of the physician brain drain.9
References
Awases, M., A. Gbary, J. Nyoni, and R. Chatora (2003): Migration of health professionals in six
countries: A synthesis report, World Health Organization, Regional Office for Africa.
Beecham, L. (2002): UK government should stop recruiting doctors from abroad, British Medical
Journal, 325.
Beine, M., F. Docquier and H. Rapoport (2007): Measuring international skilled migration: new
estimates controlling for age of entry, World Bank Economic Review, 21: 249-254.
Beine, M., F. Docquier and H. Rapoport (2008): Brain drain and human capital formation in
developing countries: winners and losers, Economic Journal, 118: 631-652.
7 Kangasniemi et al. (2007) set the wage gap for Indian physicians in the UK at about eight at current
exchange rates and about 4 in PPP. They are about twice those figures for African doctors. 8 See, e.g., Leblang (2009), who shows such dual citizenship agreements are associated with more
remittances, capital flows, aid flows, and return intentions. 9 See for example the Global Forum on Migration and Development (http://www.gfmd2009.org/) for a list
of policy initiatives in this direction.
14
Bhargava, A. (2005): AIDS epidemic and health care infrastructure inadequacies in Africa: A
socioeconomic perspective, Journal of AIDS, 40: 241-242.
Bhargava, A. and F. Docquier (2008): HIV Pandemic, Medical Brain Drain, and Economic
Development in Sub-Saharan Africa, World Bank Economic Review, 22: 345-66.
Bhargava, A., F. Docquier and Y. Moullan (2010): Modeling the effect of physician brain drain on
human development, Economics and Human Biology, forthcoming.
Bhargava, A., Jamison, D., Lau, L., Murray, C. (2001): Modeling the effects of health on economic
growth, Journal of Health Economics, 20: 423-440.
Bundred, P. and C. Levitt (2000): Medical migration: who are the real losers?, The Lancet 356,
9225: 245-46.
Chauvet, L., F. Gubert, S. Mesplé-Somps (2008): Are remittances more effective than aid to
improve child health? An empirical assessment using inter and intra-country data, paper
presented at the Annual Bank Conference on Development Economics, Cape Town, South Africa.
Clemens, M. (2007): Do Visas Kill? Health Effects of African Health Professional Emigration,
Working Paper 114, Center for Global Development.
Clemens, M.A. and G. Pettersson (2006): A New Database of Health Professional Emigration
from Africa, Working Paper, 95, Center for Global Development.
Cooper R.A. (2004): Weighing the evidence for expanding physician supply, Annals of Internal
Medicine, 141: 705-14.
De Laat, J. and W. Jack (2009) : Adverse selection and the brain drain, Mimeo., Georgetown
University.
Defoort, C. (2010): To educate or not to educate: the impact of migration perspectives in the
medical sector, Working Paper, EQUIPPE, University of Lille.
Docquier, F. and A. Marfouk (2006): International migration by educational attainment (1990-
2000), in C. Ozden and M. Schiff (eds). International Migration, Remittances and Development,
Palgrave Macmillan: New York.
Docquier, F. and H. Rapoport (2003): Ethnic discrimination and the migration of skilled labor,
Journal of Development Economics, 70, 159-72.
Docquier, F. and H. Rapoport (2009): Documenting the brain drain of “la crème de la crème”:
three case studies on international migration at the upper tail of the education distribution,
Jahrbucher fur Nationalokonomie und Statistik, 229, 6: 679-705.
Docquier, F. and H. Rapoport (2011): Globalization, brain drain and development, Journal of
Economic Literature, forthcoming.
Docquier, F., O. Lohest and A. Marfouk (2007): Brain drain in developing countries, World Bank
Economic Review, 21, 2: 193-218.
Eyal, N. and S.A. Hurst (2008): Physician Brain Drain: Can Nothing Be Done?, Public Health Ethics,
1, 2: 180-192.
Hagopian A, M.J. Thompson, M. Fordyce, K.E. Johnson, G.L. Hart (2004): The migration of
physicians from sub-Saharan Africa to the United States of America: measures of the African
brain drain, Human Resources for Health, 2-17.
15
Johnson, J. (2005). Editorial: Stopping Africa's medical brain drain, British Medical Journal, 331:2
Kangasniemi, M., L.A. Winters and S. Commander (2007): Is the medical brain drain beneficial?
Evidence from overseas doctors in the UK, Social Science and Medicine, 65, 5: 915-923.
Leblang, D. (2009): Harnessing the diaspora: the political economy of dual citizenship, Working
Paper, University of Virginia.
Lucas, R.E.B. (2004): International migration regimes and economic development, Report for the
Expert Group on Development Issues (EGDI), Swedish Ministry of Foreign Affairs.
Mayda, A.M. (2010): International migration: A panel data analysis of the determinants of
bilateral flows, Journal of Population Economics, 23, 4: 1249-74.
OECD (2006): The medical brain drain, Paris: OECD.
Physicians for Human Rights (2004): An action plan to prevent brain drain: building equitable
health systems in Africa, Boston, MA: June.
Stark, O. (2004): Rethinking the brain drain, World Development, 32, 1: 15-22.
16
Table 1. The main exporters of physicians in 2004
Country Emigration1991 Emigration2004 % change
India 45375 71290 57.11%
Philippines 17158 20000 16.56%
Canada 13128 18635 41.95%
United Kingdom 15478 17759 14.73%
South Africa 10027 16433 63.89%
Pakistan 7300 16423 124.97%
Germany 8778 13571 54.61%
Mexico 10877 13057 20.04%
Ireland 11904 11388 -4.33%
Egypt 5311 8515 60.32%
Italy 7037 8402 19.40%
Australia 11212 7958 -29.02%
Spain 6581 7779 18.21%
Dominican Republic 4905 7257 47.96%
Iran 4985 6620 32.78%
Poland 3633 5765 58.67%
Nigeria 1519 5499 261.97%
China 1655 5417 227.29%
Russia 1331 5039 278.51%
Grenada 1625 5000 207.69%
Top 20 Total 189821 271808 43.19%
World Total 288249 411379 42.72%
Top20/World 65.85% 66.07% —
17
Table 2a. Determinants of the growth rate of the PBD - Full sample
(dependent variable = log emphys(i,t) -minus log emphys(i,t-1))
Spec 1 Spec 2 Spec 3 Spec 4
Method IV IV GLS GMM
Random effect No No Yes Yes
Incl. wagerat and hivprev No Yes Yes Yes
log(emphys(i,t-1))a -0.083
(-8.08)***
-0.087
(-4.48)***
-0.087
(-4.48)***
-0.082
(-3.73)***
log(phys1000(i,t-1)) 0.081
(3.39)***
0.165
(3.73)***
0.165
(3.73)***
0.169
(3.26)***
log(poptot(i,t-1)) 0.054
(3.65)***
0.056
(1.96)**
0.056
(1.96)**
0.048
(1.44)
log(scht(i,t-1)) 0.004
(0.14)
0.017
(0.42)
0.017
(0.42)
0.027
(0.58)
log(gdppc(I,t-1)) -0.006
(-0.31)
-0.039
(-1.03)
-0.039
(-1.03)
-0.054
(-1.18)
log(wagerat(I,t-1)) - 0.002
(0.09)
0.002
(0.09)
0.021
(0.68)
log(hivprev(I,t-1)) - 0.064
(3.09)***
0.064
(3.08)***
0.082
(3.44)***
log(pubext(i)) 0.054
(2.23)***
0.129
(2.92)***
0.129
(2.92)***
0.137
(2.79)***
log(distocde(i)) -0.011
(-0.65)
-0.028
(-0.93)
-0.028
(-0.93)
-0.030
(-0.90)
log(ethnfr(i)) 0.004
(0.20)
-0.017
(-0.38)
-0.017
(-0.38)
-0.015
(-0.29)
linocde(i) 0.044
(1.22)
0.071
(1.09)
0.071
(1.09)
0.066
(0.89)
colocde(i) 0.049
(1.08)
0.040
(0.46)
0.040
(0.46)
0.029
(0.30)
oilexp(i) 0.120
(2.06)**
0.027
(0.25)
0.027
(0.25)
-0.007
(-0.06)
smisl(i) 0.251
(4.15)***
0.341
(3.44)***
0.341
(3.44)***
0.354
(3.25)***
landlock(i) -0.002
(-0.03)
-0.069
(-0.97)
-0.069
(-0.97)
-0.104
(-1.29)
Constant -0.405
(-1.22)
-0.334
(-0.51)
-0.335
(-0.51)
-0.111
(-0.14)
Chi2(15) - - 87.78 77.89
Prob > chi2 - - 0.0000 0.0000
Rsquare (Adj.) 0.3037 0.2989 0.3604 0.3449
# of countries 155 89 89 83
# of observations 309 172 172 156
Note. a log(emphys(i,t-1)) instrumented by log(emphys(i,t-2)).
18
Table 2b. Determinants of the growth rate of the PBD - Developing countries
(Dependent variable = log emphys(i,t) -minus log emphys(i,t-1))
Spec 1 Spec 2 Spec 3 Spec 4 Spec 5
Method IV IV GLS GMM GMM
Random effect No No Yes Yes Yes
Incl. wagerat and hivprev No Yes Yes Yes Yes
log(emphys(i,t-1))a -0.095
(-7.25)***
-0.086
(-3.86)***
-0.086
(-3.86)***
-0.081
(-3.21)***
-0.078
(-4.31)***
log(phys1000(i,t-1)) 0.082
(2.94)***
0.154
(3.11)***
0.154
(3.11)***
0.145
(2.42)**
0.152
(4.9)***
log(poptot(i,t-1)) 0.078
(3.73)***
0.064
(1.86)*
0.064
(1.86)*
0.055
(1.35)
0.052
(1.85)*
log(scht(i,t-1)) 0.033
(1.01)
0.022
(0.49)
0.022
(0.49)
0.027
(0.53)
log(gdppc(I,t-1)) 0.020
(0.72)
0.005
(0.10)
0.005
(0.10)
0.002
(0.03)
log(hivprev(I,t-1)) 0.062
(2.61)***
0.062
(2.61)***
0.086
(3.14)***
0.056
(2.93)***
log(wagerat(I,t-1)) 0.007
(0.24)
0.007
(0.24)
0.023
(0.68)
log(pubext(i)) 0.088
(2.80)***
0.143
(2.94)***
0.143
(2.94)***
0.151
(2.79)***
0.117
(3.27)***
log(distocde(i)) -0.005
(-0.22)
-0.036
(-0.93)
-0.036
(-0.93)
-0.063
(-1.36)
log(ethnfr(i)) -0.003
(-0.09)
-0.007
(-0.12)
-0.007
(-0.12)
-0.033
(-0.44)
smisl(i) 0.305
(4.22)***
0.355
(3.30)***
0.355
(3.30)***
0.349
(2.95)***
0.256
(3.2)***
oilexp(i) 0.075
(1.09)
-0.017
(-0.14)
-0.017
(-0.14)
-0.034
(-0.25)
linocde(i) 0.052
(1.15)
0.053
(0.69)
0.053
(0.69)
0.042
(0.47)
colocde(i) 0.080
(1.5)
0.066
(0.69)
0.066
(0.69)
0.034
(0.32)
landlock(i) 0.011
(0.2)
-0.046
(-0.60)
-0.046
(-0.60)
-0.092
(-1.07)
Constant -1.200
(-2.58)**
-0.775
(-1.01)
-0.775
(-1.01)
-0.423
(-0.46)
-0.639
(-1.52)
Chi2(15)
72.09 64.46 62.39
Prob > chi2
0.0000 0.0000 0.0000
Rsquare (Adj.) 0.2809 0.2811 0.3550 0.3434 0.2716
# of countries 124 76 76 71 90
# of observations 248 147 147 133 168
Note. a log(emphys(i,t-1)) instrumented by log(emphys(i,t-2)).
19
Table 3a. Determinant of aggregate PBD rates in 2000 for African Countries
Analysis by country of training
Log(PBD_Train) Log(BD22+) Log(PBD_Train/BD22+)
Full Parsim Full Parsim Full Parsim
Log(gdppc) -1.176 -0.700 -0.671 -0.338 -0.257
(-1.57) (-2.56)** (-3.08)*** (-2.95)*** (-0.43)
Log(scht) 0.754 0.077 0.505
(1.39) (0.40) (1.18)
Log(poptot) 0.629 0.283 0.439 0.546
(1.47) (1.96)* (1.29) (3.51)***
Log(georeg) -2.023 -5.527 1.342 -4.444
(-0.28) (-2.16)** (0.70) (-0.78)
landlock -1.469 -1.581 -0.968 -0.853 -0.004
(-1.95)* (-2.75)*** (-2.89)*** (-3.15)*** (-0.01)
smisl 2.241 2.822 1.073 -2.977
(0.83) (3.43)*** (2.87)*** (-1.39)
linocde 0.356 1.487 0.801 -0.426
(0.45) (3.86)*** (2.60)** (-0.67)
opec 0.816 0.247 0.236
(2.04)* (1.68)* (0.74)
oilexp -0.835 -0.145 -0.338
(-0.97) (-0.54) (-0.49)
Log(hivprev) -0.096 0.670 -0.578 0.764 0.274506
(-0.11) (3.66)*** (-2.48)** (1.13) (2.23)**
Log(ethnfr) -2.424 -2.545 -0.192
(-1.07) (-2.63)** (-0.11)
Log(relfr) 1.255 1.189 -0.378
(1.00) (2.10)** (-0.38)
Log(phys1000) 0.050 0.237
(0.07) (0.42)
Log(wagerat) -0.359 -0.158
(-0.73) (-0.41)
Cons -5.181 11.023 -7.008 -0.674 1.990
(-0.27) (2.04)** (-1.37) (-0.89) (0.13)
observations 33 36 43 51 33 35
R-square 0.53 0.36 0.59 0.41 0.62 0.40
Adj. R-square 0.16 0.27 0.43 0.36 0.33 0.36
Notes: OLS regressions, robust t-statistics in parentheses. *, **, *** significant at 10, 5 and 1%.
Data sources: BD22+ from Beine et al. (2007), PBD by country of training from BDM (2010).
Variables definitions: Gdppc=gdp per capita. Linocde=Linguistic proximity with OECD. Landlock=land
locked country. Smisl=small islands developing country. Georeg= geographic area. Wagerat= Average
wage rate of physicians (US=1). Relfr=religious fractionalization. Ethnfr=ethnicity fractionalization.
20
Table 3b. Determinant of aggregate PBD in 2000 for African Countries
Analysis by country of birth
Log(PBD_Birth) Log(BD0+) Log(PBD_Birth/BD0+)
Full Parsim Full Parsim Full Parsim
Log(gdppc) -0.237 - -0.574 -0.492 -0.028 -
(-1.11) (-2.79)*** (-4.09)*** (-0.10)
Log(scht) 0.107 - 0.091 - -0.102 -
(0.66) (0.50) (-0.48)
Log(poptot) 0.117 - 0.257 - -0.152 -0.179
1.03 (1.89)* (-1.03) (-1.95)*
Log(georeg) -3.229 -2.806 0.638 - -3.276 -
(-2.06)** (-3.04)*** (0.35) (-1.59)
landlock -0.431 -0.313 -0.814 -0.737 0.562 0.445
(-1.70)* (-1.72)* (-2.57)** (-2.9)*** (1.69)* (1.8)*
smisl 1.543 0.804 2.588 1.570 -1.658 -0.961
(2.22)** (2.47)** (3.33)*** (3.41)*** (-1.82)* (-2.01)*
linocde 0.426 - 1.340 0.984 -0.770 -0.680
(1.49) (3.68)*** (3.3)*** (-2.05)** (-2.49)**
opec 0.129 - -2.523 -1.462 0.964 1.007
(1.15) (-2.76)*** (-2.04)** (0.99) (2.1)**
oilexp -0.307 - 1.155 0.888 -0.586 -
(-1.50) (2.16)** (1.85)* (-1.07)
Log(hivprev) 0.106 - 0.179 - -0.032 -
(0.61) (1.29) (-0.22)
Log(ethnfr) -1.028 - -0.017 - -0.249 -0.461
(-1.39) (-0.07) (-0.93) (-2.49)**
Log(relfr) 0.597 1.289 -0.500 -0.188 0.598 0.346
(1.43) (3.58)*** (-2.27)** (-1.71)* (2.63)** (2.97)***
Log(phys1000) -0.247 -0.301 - - 0.317 -
(-1.07) (-3.27)*** (1.04)
Log(wagerat) -0.131 - - - -0.063 -
(-0.95) (-0.35)
Cons 2.635 2.473 -5.426 0.095 10.980 4.180
(0.66) (1.72)* (-1.12) (0.13) (2.09)** (2.64)**
observations 42 45 43 47 42 48
R-square 0.52 0.36 0.59 0.53 0.52 0.45
Adj. R-square 0.27 0.28 0.43 0.45 0.27 0.35
Notes: OLS regressions, robust t-statistics in parentheses. *, **, *** significant at 10, 5 and 1%.
Data sources: BD-Docquier and Marfouk (2006), PBD by country of birth-Clemens and Pedersson (2006).
Variables definitions: Gdppc=gdp per capita. Linocde=Linguistic proximity with OECD. Landlock=land
locked country. Smisl=small islands developing country. Georeg= geographic area. Wagerat= Average
wage rate of physicians (US=1). Relfr=religious fractionalization. Ethnfr=ethnicity fractionalization.
21
Figure 1. Evolution of PBD by region (1991-2004)
Note. PBD = physician emigration rate in percent. Pacific islands exclude Australia and New Zealand. Latin
America = Central America + South America (excluding Caribbean islands). Asia =East, South-East and
South Asia. MENA =Middle East and Northen Africa.
22
Figure 2. Largest PBD rates in 2004
23
Figure 3. Geographical distribution of PBD
3a. PBD in 2004
3b. Change PBD2004-PBD1991
SWITZERLAND
This research was funded by the Austrian, German, Norwegian, Korean, and Swiss Governments through the World Bank’s Multi-Donor Trust Fund for Labor Markets, Job Creation, and Economic Growth.
The findings, interpretations, and conclusions expressed in this paper are entirely those of the authors. They do not necessarily represent the views of the International Bank for Reconstruction and Development/World Bank and its affiliated organizations, those of the Executive Directors of the World Bank or the governments they represent, or the donors supporting the Trust Fund.
The brain drain of health professionals has become a source of concern for many developing
countries and international organizations. The World Health Organization estimates the current global
shortage of health workers at more than 4 million. From a global perspective, therefore, the medical
brain drain could be seen as a matching process through which workers are allocated to places
and jobs where they are most productive. This process is not recent but has accelerated recently:
it is estimated that expatriated doctors now constitute more than 20 percent of the stock of medical
doctors in the OECD (30% in countries such as Ireland or the UK, and more than 50% in the Gulf
States); there are currently more Ghanaian-born doctors living in London than in Ghana, and more
Filipino nurses in the US than in Manila.
In this note we focus on the emigration of physicians from developing countries. We first describe
the magnitude and intensity of the physician brain drain (PBD) and analyze its determinants. We then
survey the existing literature on the possible existence of a physician “brain gain” and characterize
some of the channels through which physicians’ emigration can damage health outcomes in sending
countries. Finally, we conclude by examining a number of policies that have been suggested recently
to curb the PBD in the light of our findings.
Physician Brain DrainSize, Determinants and Policy Issues
Frédéric Docquier Hillel Rapoport