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doi: 10.1098/rsta.2011.0602, 2216-2239370 2012 Phil. Trans. R. Soc. A
Elizabeth Whitcombe malariaIndo-Gangetic river systems, monsoon and
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Phil. Trans. R. Soc. A (2012) 370, 2216–2239doi:10.1098/rsta.2011.0602
Indo-Gangetic river systems, monsoonand malaria
BY ELIZABETH WHITCOMBE*,†
Earth System Science Interdisciplinary Center (ESSIC), University ofMaryland, College Park, MD 20740, USA
The history of the Indo-Gangetic river systems from the late nineteenth to the earlytwentieth centuries can be reconstructed from the meticulous official records of thesurvey, meteorological and medical departments of the British Government of India.In contrast with the grand sweep of the geological evidence, these records indicatea complex narrative of floods, droughts and channel shifts. Similarly, the cumulativegrowth of the Ganges–Brahmaputra and Indus deltas was overprinted by the effectsof the annual monsoon cycle on precipitation, temperature and winds. Malaria, theprincipal vector-borne disease of the Indian subcontinent, and the deadliest, displayedepidemiological types that ranged between the extremes of stable–endemic to unstable–epidemic as defined in the classic theory of equilibrium of George Macdonald. Variationsin its transmission, incidence and prevalence were closely tied to the different deltaicenvironments of the Bengal and Indus basins and to the short-sightedness of manyirrigation and related engineering schemes.
Keywords: Indo-Gangetic deltas; monsoon; malaria
1. Introduction
To H. F. Blanford, FGS, FRS (1834–1893), palaeontologist with the GeologicalSurvey of India from 1855 to 1862 and Meteorological Reporter to theGovernment of India from 1874 to 1888, the subcontinent offered ‘many peculiaradvantages’ for scientific enquiry. As a region defined, to the north, by theHimalaya and to the west and east by the Arabian Sea and Indian Ocean, itpresented ‘in its different parts extreme modifications of climate and geographicfeatures’ [1, pp. 563–564]. From the mid-1870s, systematic observations ongeological phenomena and meteorological events were published in the surveys’annual reports. Meanwhile, under the Registration Act of 1865, the districtmedical officers of the provincial Sanitary Commissioners’ departments collectedmonthly observations on births and deaths, with specific reference to climateand physiographic conditions. Deaths were registered inter alia by principalcause—chiefly fevers, of which upwards of one-third were ‘malarious’.
*[email protected]†Visiting Senior Research Scholar.
One contribution of 10 to a Theme Issue ‘River history’.
This journal is © 2012 The Royal Society2216
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Indian rivers, monsoon and malaria 2217
Nowhere in British India was the range of variation in physiography andclimate more striking, nor more closely observed, than in the north, in the greatriver basins of the Ganges–Brahmaputra system to the east and the Indo-Gangeticsystem to the west. Against a background of the geological past of these great riversystems, as established by advances in geoscience, it is possible to reconstruct arecent history, from the mid-nineteenth century, of fluvial processes, their climateand their environmental diseases from technical records of the British Governmentof India, unique in their calibre and consistency.
Malaria was British India’s most deadly and debilitating disease.Predominantly a disease afflicting the rural poor, malaria was ‘responsibledirectly’ for at least 1 000 000 deaths each ordinary year, increased, in epidemicyears, by another 25 000. At least 100 000 000 suffered from malaria each year.It probably accounted for an ‘additional indirect morbidity’ of 25–75 000 000. Ithad a marked adverse effect on the birth rate, and was ‘probably the greatestsingle cause in retarding the natural increase of the population’ and ‘the greatestfactor in lowering the health, vitality and physical development of the people’where it prevailed. Malaria accounted for annual financial losses ca £80 000 000to the individual and the family alone. While direct and indirect losses could notbe accurately evaluated, there was ‘little reason to doubt that they must run intounbelievable millions of pounds sterling each year’ [2, p. 158].
When systematic registration of mortality began in 1865, environmentalconditions—dampness, defective drainage, waterlogging and swamps—had longbeen regarded as the direct cause of ‘malarious fevers’, and were given prominenceaccordingly in the Sanitary Commissioners’ reports. Laveran’s identificationof the parasite Oscilleria (later renamed Plasmodium) malariae as causativeorganism in Algeria, in December 1880, established an intermediate stepbetween environment and human host. By the end of the decade, two furtherplasmodia had been discovered in the blood of malarious patients and theassociation of each species with periodicity of malarial fever—Plasmodium vivaxwith benign tertian, P. falciparum with malignant tertian and P. malariaewith quartan—determined. The passage of plasmodium to host, and the roleof environmental conditions, awaited elucidation. In China, in 1878, PatrickManson, parasitologist—the ‘father of tropical medicine’—had shown how theagent of filariasis, the parasitic worm, Filaria sanguinis hominis, was transmittedby Anopheles mosquito—the female, since ‘the anatomical arrangement of themale’s proboscis and appendages prevented it from penetrating the skin’. Themosquito ingested the filarial embryos, ‘nursed’ them to maturation, thenreinjected them into the animal host [3]. Might not the female Anopheles, favouredby the environmental conditions long associated with malarious fevers, be the‘nurse’ of the malarial parasite? In discussions from 1894 to 1897, Mansondiscussed his hypothesis with Surgeon-Major Ronald Ross, Indian MedicalService, physician, artist and mathematician. In Calcutta, in August 1897, Rossdemonstrated, by experiments of an elegance to match Manson’s hypothesis, thetransmission of the plasmodium associated with benign tertian malaria (P. vivax)by the female Anopheles mosquito to an avian host [4–6]. In 1900, Manson, inassociation with Italian colleagues, confirmed by experiment the transmission ofplasmodium by Anopheles to human host—his physician son, whose recordingof his symptoms of benign tertian malaria daily and in detail perfected thedemonstration [7].
Phil. Trans. R. Soc. A (2012)
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2218 E. Whitcombe
Subsequent investigations into the parasitology and transmission of malaria,the environmental conditions that favoured it and pioneering efforts at controland prevention are described by Bruce-Chwatt [8].
Distilling field and experimental observations on malaria as the prototype ofvector-borne disease into a probabilistic theory of transmissibility, generalized as‘pathometry’, Ross [9,10] laid the foundations of the mathematical epidemiologyof vector-borne disease.
Some 40 years later, George Macdonald, malariologist and mathematician,followed Ross’ probabilistic method in his classic paper on theory of equilibrium inmalaria [11]. His theory was derived from half a century’s field and experimentalobservations, given mathematical expression and translated back intoepidemiological terms.
Macdonald [11] identified three factors as essential to the epidemiology ofmalaria: (i) the duration of the extrinsic cycle of the parasite (in the vector); (ii)the vector’s biting habit—specifically, the frequency with which it fed on man;and (iii) the vector’s normal longevity. Factors (ii) and (iii) could be related as theaverage number of feeds on man that an insect took in its lifetime. These factorsaffected ‘the probability of an insect becoming infected and thus the density ofinsects needed to maintain continuous transmission’: they determined the ‘criticaldensity of insects in relation to man, below which the disease tends to disappear’.If the critical density was exceeded, then Macdonald considered that these factorswould act to curb ‘progressive multiplication of human cases’.
Macdonald [11, p. 824] described the variability of transmission of malariabetween vector and host as a dynamic equilibrium, continually adjusted betweenstability and instability (see table 1):
according to the degree of the controlling factors, the epidemiology of the resultant malariacorresponds to some point on the scale between the extremes described as stable and unstablemalaria.
In stable–endemic areas, transmission of malaria was more or less constant,building up a firm immunity in the host population and thus preventingepidemics. In areas prone to epidemics, transmission was interrupted andimmunity fell. The resumption of transmission led to an epidemic, followed bya significant level of immunity for several years [11]. It was well recognized thatendemic malaria, despite its relatively low death rate, sapped the strength of thepopulation—and ‘may exercise in the long run a more harmful effect upon thepublic health than even the most severe epidemic’ [12, p. 418].
Recent exercises in the mathematical epidemiology of malaria have amendedand enlarged on Macdonald’s analysis with a variety of modelling techniques[13]. A simulation of the dynamics of transmission of malaria in association withvariation in weather, the Liverpool Malaria Model, designed by Hoshen & Morse[14], has lately been updated by Morse and co-workers [15].
From field studies throughout India on which Macdonald built his theoryof equilibrium of transmission, with the rate of enlarged spleens and laterparasitaemia in a given population taken as the index of malarial infection,variation between stable–endemic and unstable–epidemic types of malariawas localized to specific regions of the Indian subcontinent—a remarkableachievement of the Malaria Survey of India within 6 years of its establishment in1920 (figure 1).
Phil. Trans. R. Soc. A (2012)
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Indian rivers, monsoon and malaria 2219
Tab
le1.
Epi
dem
iolo
gica
lty
pes
ofm
alar
ia,ac
cord
ing
toM
acdo
nald
’sth
eory
ofeq
uilib
rium
[11]
.
Ano
phel
esde
nsity
requ
ired
tom
aint
ain
seas
onal
chan
ges:
effe
ctflu
ctua
tion
sin
imm
unity
ofty
pede
term
inin
gca
uses
tran
smis
sion
ende
mic
ity
ontr
ansm
issi
onin
cide
nce
popu
lati
on
Ist
able
tran
smis
sion
regu
lar,
byve
ctor
Ano
phel
esof
freq
uent
man
-bit
ing
habi
t,m
oder
ate
long
evity,
atte
mpe
ratu
re>
15◦ C
,fa
vour
ing
rapi
dco
mpl
etio
nof
extr
insi
cpl
asm
odia
lcy
cle,
allal
titu
des,
lati
tude
s
very
low
:≤0
.025
man
-bit
espe
rni
ght
very
high
:an
ophe
lism
wit
hout
mal
aria
also
foun
d
slig
ht:co
mpl
ete
term
inat
ion
oftr
ansm
issi
onun
likel
yde
spit
eco
ndit
ions
unfa
vour
able
tobr
eedi
ngor
prol
onge
dad
ult
surv
ival
(tem
pera
ture
<15
◦ C,
low
rain
fall,
low
hum
idity)
slig
ht,se
ason
al:m
ean
valu
eof
amou
ntof
tran
smis
sion
high
,w
ith
seas
onal
and
loca
lva
riat
ions
.V
irtu
alce
ssat
ion
oftr
ansm
issi
onra
re.E
pide
mic
sun
likel
y
regu
lari
tyof
tran
smis
sion
likel
yto
ensu
rest
able
imm
unity
wit
hlo
cal
vari
atio
ns.
Exp
erie
nce
ofm
alar
iaan
dre
sist
ance
thro
ugho
utpo
pula
tion
,ex
cept
youn
gest
child
ren
IIun
stab
letr
ansm
issi
onir
regu
lar,
wit
hgr
oss
vari
atio
ns,by
vect
orA
noph
eles
ofre
lati
vely
infr
eque
ntm
an-b
itin
gha
bit,
shor
t-liv
ed,at
low
alti
tude
son
ly
rela
tive
lyhi
gh:1
to≥1
0m
an-b
ites
per
nigh
t
vari
atio
n,lo
w-
mod
erat
e,m
aybe
high
very
mar
ked
resp
onse
tova
riat
ions
inte
mpe
ratu
re,lo
whu
mid
ity,
othe
run
favo
urab
leve
ctor
bree
ding
cond
itio
ns.
Vir
tual
cess
atio
nof
tran
smis
sion
inso
me
year
s.Se
ason
al,se
vere
epid
emic
s:ab
rupt
onse
tat
rela
tive
lyhi
ghte
mpe
ratu
res;
rapi
dce
ssat
ion
aste
mpe
ratu
res
fall
very
mar
ked:
mea
nva
lue
oftr
ansm
issi
onm
oder
ate-
low
,se
ason
alep
idem
ics
exag
gera
ted,
ende
mic
ity
exac
erba
ted
byin
crea
sein
favo
urab
lebr
eedi
ngco
ndit
ions
.M
ajor
regi
onal
epid
emic
s,in
vasi
onof
prev
ious
non-
mal
aria
lar
eas
whe
re/w
hen
clim
atic
fact
or(s
)fa
vour
vect
orlo
ngev
ity,
bree
ding
over
larg
ear
eas
very
vari
able
:si
gnifi
cant
prop
orti
onof
popu
lati
onno
tim
mun
e,no
resi
stan
ceto
upsw
ing
intr
ansm
issi
onin
unst
able
cond
itio
ns
Phil. Trans. R. Soc. A (2012)
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2220 E. Whitcombe
a
b c
Punjab: malaria epidemic–hyperepidemic
80° 90°70°
80° 90°70°
20°
30°
20°
30°
Sindh:focal epidemic malaria
Bengal:Maleria endemic-hyperendemic
Bengal:malaria endemic–hyperendemic
Figure 1. Epidemiological types of malaria prevalent in Punjab, Sindh and Bengal. FromChristophers & Sinton [16].
The association of these contrasting epidemiological types of malaria and thegreat river basins of northern India is apparent. In the northeast (NE), humidsubtropical region of the subcontinent of south Asia, the western part of theBengal foreland basin (the oldest, least active region of the inland delta of theGanges–Brahmaputra system) has a history of stable–endemic, stable malaria,with hyperendemic foci. The death rate was constant, but small, associated witha constantly high spleen rate and a relatively low birth rate [12]. Immunitylevels were consistently moderate to high. The semi-arid region of the Indusforeland basin to the northwest (NW), characterized by recent, dramatic rivershift particularly in its eastern part, has a history of unstable–epidemic malaria,with hyperepidemic foci. The death rate was high, but for short periods only,with a ‘remarkable freedom from mortality during inter-epidemic periods’ [12].
In the Indo-Gangetic river systems, a dynamic equilibrium between relativestability and instability is adjusted and readjusted by phases of progradationand aggradation, at rates of greater or lesser activity according to the balanceof forces—fluvial and, at the coastal deltas, tidal processes, on a seasonal,interannual and interdecadal scale, complicated by the anomalies of the Asiamonsoon cycle and constrained by tectonic movements. The systems arose in
Phil. Trans. R. Soc. A (2012)
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Indian rivers, monsoon and malaria 2221
SW phase
NE phase
2000 km
wet
thermalLowpressure
lowpressure
Highpressurehighpressure
transitional phase
transitional phase
dry
DecJan
April
Mar
Feb
MayJune
July
Aug
Sept
Oct
Nov
dry
Figure 2. The Asia monsoon cycle. From data in Pithawala [18] and Kump et al. [19].
the Himalaya–southern Tibet with the progressive collision of the Indian andEurasian plates during the Tertiary. The convergence of the plates, togetherwith gravitational spreading, unleashed forces that uplifted the Himalayan rangesand east Asian plateaux—movements that continue at the present day. In theHimalayan–south Tibetan drainage basin, the action of eroding forces towardsthe head of the rivers is counteracted by northward migration of rivers northof the rising Himalaya [17]. In their passage south, the forerunners of the Indo-Gangetic system have cut great gorges in the south Tibetan plateau and in thefoothills through which they debouch, abruptly into the plains of the northernsubcontinent, to form vast, braided fans of inland and coastal deltas. Deltabuilding continues, in phases of greater or lesser activity and forcefulness offluvial and tidal processes, subject below to tectonic movements and above tothe vagaries of the monsoon (figure 2; table 2).
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2222 E. Whitcombe
Table 2. History of the Asia monsoon system [20,21].
chronology (Ma) events
9–8 aridity in Asian interior increasesonset of Asian, East African monsoons
ca 5 intensification of Asian monsoon
3.6–2.6 intensification of East Asian NE and SW monsoons continuesdust transport to North Pacific Ocean increases
ca 2.6 increased variability in monsoons: continued strengthening of East AsianNE monsoon, weakening of Asian and East Asian SW monsoons
The modern Asia monsoon system is a complex, cyclical weather systemin dynamic equilibrium, varying with regular or irregular regularity abouta relatively stable norm to unstable anomaly in wind speed and direction,barometric pressure, precipitation, temperature and relative humidity, over years,decades, centuries and aeons [21–25]. But ‘the defining variability of a monsoonsystem is its seasonal character’ [26, p. 203]. The strongly defined seasonal cyclemarks out the Asian monsoon system from others with their weaker annual cycles[27]. The NE monsoon of the Asian cycle, in the NE and NW of the Indiansubcontinent, a relatively low-grade wind bringing gentle patchy precipitation,associated with mild temperatures, is in evidence at the turn of the calendar yearand dies away through March into a transitional phase, abruptly interrupted,during May–June, by the onset, commonly tumultuous, of the southwest (SW)monsoon winds, in an east to NW progression, the date of regular onset varyingaccording to location. The SW monsoon provides up to ca 80 per cent ofthe annual discharge of the Indo-Gangetic rivers, augmented by snow-melt.In September, the SW winds are exhausted and come gradually to cessation.A transitional phase follows, to the close of the year. Within the cycle, there ismuch intraseasonal variability—in onset and duration of monsoon wind, betweenweak and strong spells, in amount and distribution of precipitation, in coincidenttemperatures and in relative humidity [23,26].
2. Bengal: the Ganges–Brahmaputra river system
The dynamic equilibrium of the Bengal delta (figure 3; table 3) is most evidentwhere it is least stable, at its margins—south, in the tidal delta of the Bengalcoast; north, where the mountain torrents emerge from the gorges into the plains.In the tidal delta, as Hunter, Statistical Officer to the Government of Bengalobserved in the course of his field surveys of Bengal (and every district in BritishIndia) for the Imperial Gazetteer [32, p. 20]:
An eternal war goes on between the rivers and the sea, the former struggling to find avent for their columns of water and silt, the latter repelling them with its sand-ladencurrents.
From the Early Holocene, the shoreline has lost ground to the rivers andretreated south over some 80 kyr, with marked acceleration in pace between80 and 6 kyr, to its present position (figure 3). The sluggish end-streams of the
Phil. Trans. R. Soc. A (2012)
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Indian rivers, monsoon and malaria 2223
40 km
activedelta
moribund delta
mature delta
tidal delta
subaqueousdelta
Bay of Bengal
Padma
Ganges
Hug
li
Jamuna
Bhagirathi
Me
ghnaM
eghna
23°
22°
90°
24°
90° 91°89°88°
24°
23°
22°
present shoreline
palaeo-shoreline 6000 yr BP
palaeo-shoreline 80 000 yr BP
Figure 3. Bengal basin. Delta zones and palaeo-shorelines. From data in Lindsay et al. [28], Kuehlet al. [29] and Geological Survey of India [30].
Ganges now debouch into the NW reach of the Bay of Bengal. The deposition oftheir sediment load varies with their rate of discharge by an order of magnitudecorresponding to the seasonal variation in precipitation of NE and SW monsoons.Fluvial processes are here counteracted by the eroding forces of tides witha diurnal variation of 1.9 m range, compounded by a periodic variation at14–15 day intervals, stirred alternately by the clockwise and anti-clockwise gyreof the monsoon wind systems and funnelled 8 km or more into the estuaryand the network of tidal creeks, relicts of the old Ganges in its migrationeast–northeast [33].
Phil. Trans. R. Soc. A (2012)
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2224 E. Whitcombe
Tab
le3.
His
tory
ofth
eG
ange
s–B
rahm
aput
rari
ver
syst
em,B
enga
lde
lta.
Sour
ces:
Lin
dsay
etal
.[2
8],K
uehl
etal
.[2
9]an
dG
oodb
red
&K
uehl
[31]
.
stag
ein
delt
aag
ege
olog
ical
era
form
atio
nev
ents
>12
6M
aE
arly
Cre
tace
ous
init
ial
frag
men
tati
onof
Gon
dwan
alan
d:de
lta
form
atio
nbe
gins
from
slow
sedi
men
tati
onat
Indi
anpl
ate
mar
gin,
nort
hwar
ddr
iftof
Indi
anpl
ate,
colli
ding
wit
hE
uras
ian
plat
e:gr
eat
incr
ease
inra
teof
sedi
men
tati
on12
6–49
.5M
aC
reta
ceou
s–E
arly
Eoc
ene
prot
o-de
lta
depo
siti
onof
carb
onat
e–cl
asti
cas
soci
atio
ns:
earl
y,in
high
-lat
itud
e,re
stri
cted
mar
ine
envi
ronm
ent
late
r,in
low
-lat
itud
e,op
enm
arin
eeq
uato
rial
envi
ronm
ent
49.5
–10.
5M
aE
arly
Eoc
ene–
Mid
-Mio
cene
tran
siti
onal
delt
afo
rmat
ion
ofde
ep-s
eafa
nfr
omin
crea
sed
sedi
men
tlo
ad10
.5M
a–pr
esen
tM
id-M
ioce
ne–H
oloc
ene
mod
ern
delt
am
ajor
eust
atic
fall
inse
a-le
vel,
resu
ltin
gin
eros
ion
ofea
rlie
rde
posi
tion
s—m
oder
nde
lta
form
atio
nbe
gins
1.5
Ma
Ear
lyP
leis
toce
nese
a-le
velhi
gh;sm
allde
ltas
form
arou
ndin
ner
boun
dary
ofba
sin;
wit
hsu
cces
sive
falls
inse
a-le
vel,
deep
diss
ecti
onof
delt
ase
dim
ents
11–7
kaE
arly
Hol
ocen
eup
per
delt
apl
ain:
accr
etio
nof
maj
orflu
vial
and
flood
basi
nse
quen
ces
7ka
delt
ade
posi
tion
alse
quen
ces
larg
ely
aggr
adat
iona
l<
7ka
depo
siti
onal
sequ
ence
sm
ostl
ypr
ogra
dati
onal
;al
luvi
alsa
nds
wid
ely
dist
ribu
ted
acro
ssco
asta
lpl
ains
7.5–
6ka
Mid
-Hol
ocen
epr
ogra
dati
onm
ost
prom
inen
tin
wes
tern
delt
a,w
here
Gan
ges
syst
emdi
scha
rgin
gby
6–5
kaea
ster
nde
lta:
Bra
hmap
utra
shift
sea
stw
ard,
into
Sylh
etba
sin,
depo
siti
ngm
ost
load
inla
nd,no
tde
lta
fron
t<
5ka
Bra
hmap
utra
shift
sto
wes
twar
d,co
asta
lde
posi
tion
sre
vive
d<
3ka
InB
rahm
aput
ra,fu
rthe
rcy
cle
ofea
st–w
est
shift
,m
ain
Gan
ges
cour
sesh
ifts
east
war
d.Su
baer
ialde
posi
tion
sex
tend
tom
oder
nco
astl
ine
150
year
sea
stde
lta:
prog
rada
tion
ofco
astl
ine
begi
nsB
rahm
aput
rash
ifts
tom
oder
n,w
este
rn,co
urse
Phil. Trans. R. Soc. A (2012)
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Indian rivers, monsoon and malaria 2225
The NW shoreline of the Bay is distinguished by a series of tidal lakes where,as Hunter observed, ‘the strong monsoon and violent currents which sweep fromthe south during eight months of the year have thrown up ridges of sand’ [32].The largest of these, Chilka Lake, a pear-shaped ‘inland sea’ at the southernextremity of the Mahanadi delta of Orissa, measured over 70 km long in Hunter’stime, with a surface area varying from a minimum of 891 km2 during the eight drymonths to a maximum of 1165 km2 in the rains. The lake was joined to the seaby a narrow neck much silted up since 1780, when the opening in the bar—morethan 1.5 km wide—had had to be crossed in boats. Forty years later, the neck was‘choked up’ and an artificial mouth had had to be cut, which was now silting up[32, p. 23]. Hunter observed how the seasonal variation in the dominance of tidalas against fluvial forces was reflected in the composition of lake water [32, p. 20]:
The narrow tidal stream which rushes through [the neck, now a few hundred metres broad]is speedily lost in the wide interior expanse and produces a difference never more than 1.2 mbetween high and low tide and at times barely 0.45 m, while the tide outside rises and falls1.5 m. It suffices to keep the lake distinctly salt during the dry months, December to June.But once the rains have set in, the rivers come pouring down upon [the lake’s] northernextremity, the sea-water is gradually pushed out and the Chilka passes through variousstages of brackishness into a freshwater lake
The subtropical tidal deltas of the northern Bay of Bengal, as exemplified todayin the World Heritage Site of the Sunderbans, are swamp–creek–lake ecosystems.Their predominant vegetation, forests of mangrove, harbour a wide variety offauna, not least arthropods, and flora. Mangrove is adapted to the hydrodynamiccircumstances peculiar to estuaries. Its swamps are aquatic at high tide, terrestrialat low and subject to discontinuous flow given the wide diurnal and seasonalvariation in tidal and fluvial volumes. Trees and roots act as a brake on tidaland fluvial forces and by creating eddies, enforce non-laminar flow. Mangrove ishalophilic and adapted to seasonal variation in the saline concentration of creekand lake water [34, pp. 27–42].
The youngest, most active and unstable sector of the lower Bengal delta inlandfrom the coast lies to the east, at the apex of the Bay of Bengal, where theMeghna, carrying a combined sediment load of Ganges and Brahmaputra southfrom their confluence, enters the Indian Ocean. In the NE monsoon season, theMeghna’s sediment load at a discharge rate of ca 10 000 m3 s−1 is easily kept atbay by the tides. During the SW monsoon, when the Meghna increases 10-foldor more, a freshwater layer 50–100 m in thickness displaces the sea water in thenorth of the Bay [28,29,35].
At the northern margins of the Bengal basin, rivers rising from the easternHimalaya, still uplifting since the Asia–Eurasia collision of the Cretaceous, pourthrough steep gorges in the foothills to fan out at the sudden, drastic changein gradient on meeting the plains in great, unstable deltas, their courses shiftingdirection within the constraints of terraces thrown up by tectonic forces. One suchis the Kosi river, one of the great Ganges tributaries to the NW of the basin, inmodern Bihar. Draining a catchment of some 61 869 km2, the Kosi is braidedthroughout the 209 km of its course. Its fan, ca 154 × 147 km in maximum width,slopes from 0.89 m km−1 at the apex of the cone to 0.06 m km−1 at its base [36,p. 291]. Its discharge may vary by ±50 per cent, from 0.006 to 0.024 m3 s−1 fromNE to SW monsoons, with an average annual sediment load of 118 000 000 m3,
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ranging in content from boulders towards the apex of the fan to coarse pebble andshingle over the base, the more coarse sediment contributing to relatively rapidrates of aggradation [29]. The recent history of the Kosi fan is exceptionally welldocumented. A series of observations from Rennell’s survey of 1731 to the presentday shows a shift of 113 km 50◦ to the west in some 250 years [37,38].
The Kosi’s stepwise migration to the west is less likely to reflect sudden,cataclysmic events, earthquakes and floods but rather ‘stochastic and autocyclic’shifts [38], irregular ‘oscillations’ by the sediment-laden river, which from timeto time is forced out of its course and migrates laterally, overwhelming smallerstreams in its path to leave a succession of dead and dying rivers in its wake.The history of delta building in the great plains of the western Bengal basinis written in the intricate networks of obsolete and obsolescent channels: ‘likefossils’, the geologist James Fergusson observed in his survey of the Bengal deltain the mid-nineteenth century. The shallow pools and streams of these remnantsof river shift have been transformed into wetlands, bogs and lakes and refreshedseasonally, but irregularly, by the monsoon [38,39].
The onset of NE monsoon sea-winds was first felt in February–March. Thiswinter–spring precipitation, ‘less regular and lighter’ than elsewhere in northernIndia, continued through April. The transitional phase, in May, was brief[1, p. 600]. From the first or second week of June, the SW monsooncurrent ‘pours into the funnel-shaped opening occupied by the delta, thenturns westward and passes up the Ganges Valley towards the Punjab. TheBengal basin is thus the recipient of most of the moisture it carries’. TheSW monsoon phase ended in late ‘autumn’ rains, in October, initiatinga turbulent transitional phase when winds over Lower Bengal—the delta—were ‘conflicting and variable and calms (alternating with storms) at theirmaximum frequency’. From the end of October and November, the NWwind current of Upper India combined with NE winds of north Bengal ina continuous stream over the Bengal basin, heralding the next NE monsoonphase. Temperatures were generally more equable in humid, subtropicalBengal than in the semi-arid NW. From a mean of 66◦F (19◦C) inJanuary, there was a gradual rise to a mean of 85–90◦F (29–32◦C) inApril, with a further, slight increase in May. Temperatures decreased throughthe SW monsoon phase from June. Regions where the rains were mostcopious, such as Bengal, were the coolest. By early October, as the rainsceased, mean temperature was a near-uniform mean at 81–82◦F (27–28◦C)[1, pp. 584–585]. Humidity, higher in every season in the tidal than in theinland delta, varied in relation to the prevailing winds. During the driest months,humidity increased, more so in the east than the west, and decreased fromthe onset of the SW monsoon in June, more so in the west than the east[1, p. 597].
The defective drainage of mature, and more especially moribund, regions ofthe western–central Bengal delta, the oldest, least active sectors, was highlightedannually, during and after the SW monsoon. These regions correspond, onthe malaria map (figure 1), to stable–endemic areas, where malaria of varyingintensity was ‘practically never absent . . . largely a reflex of a multiplicity ofnatural features of the country . . . rainwater collections, streams and rivers,swamps, ponds, lakes’ [16]. The spleen rate was rarely above 50 per cent,maximum, largely confined to young children, with a ‘relatively low rate in
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resident adults who have had considerable immunity to malaria and sufferlittle from its effects’, in contrast to the high incidence among—non-immune—immigrants to the region. The map shows extensive areas of high- and hyper-endemicity in the deltaic plains within the endemic tracts and ‘apparentlyassociated with secular changes affecting the physiographic conditions’ favouringtransmission of malaria: ‘decayed rivers’. Smaller such foci were found where old-established malaria was slowly enhanced in intensity over years. Hyperendemicfoci were also associated with forested hills to the north, jungle and terai, boulder-strewn marsh at 305–900 m in altitude at the debouchement of foothill streams[16]. In marked contrast to the western deltaic plains, malaria in the eastern,active delta was markedly lower in both incidence and prevalence, particularlyin the tidal delta, which had not lost its mangrove forests [40–42]. The strippingof mangrove from much southern reaches of the old delta from the eighteenthcentury [39] may well have contributed to a rise in endemic malaria. In thesestable–endemic areas, epidemics were rare [16].
The association of malarious fever and its seasonality with physiographicconditions peculiar to the old inland delta of the western Bengal basin—the lie ofthe land and the effect of the SW monsoon—was well recognized by the Sanitary(public health) Commissioners of Bengal through the later nineteenth century.Observations abound in their annual reports as to how the districts of the olddelta constituted ‘a vast alluvial plain intersected by six large rivers, numeroussmaller channels and by a labyrinth-like network of forsaken river-beds and oldrivers in every stage of decay and effacement. . . . The regularity of the slopeof the country is broken up by the tangle of rivers and river-beds that crossand recross one another and obstruct the natural lines of surface drainage. . ..The high mortality in October, November and December is undoubtedly due tomalarial fever caused [sic] by the marshy and waterlogged state of the countryafter the rains. . .worst in dense jungles and along drying-up river-beds, convertedin the monsoon to a series of still pools’ [43]. Jessore district, in the heartlandof endemic–hyperendemic malaria, was typical of the moribund delta—‘seamedwith the beds of extinct rivers, with a languid vitality during the rains and indry weather a chain of foetid swamps’ [44, appendix III].
Ross’ and Manson’s experimental confirmation of the mosquito–malariahypothesis in 1897–1900 was matched before long by field observations. After the(annual, June–August) Ganges floods, the Sanitary Commissioner commented inhis report for 1904 that there were ‘large collections of stagnant water [freshenedby the recent rains] . . . and as these became breeding places for anopheles, somalarious fever became rife during the latter months of the year’ [45].
Over the next four decades, officers of the Indian Medical Service and, from1920, of the Malaria Survey of India compiled a mass of field and experimentalobservations on the transmission of malaria, unique in the annals of epidemiology,identifying Anopheles, their habits and habitats, specific to the several regions ofthe subcontinent (table 4).
The work of control by the distribution of quinine from local dispensaries andpost offices, which had begun in the nineteenth century, was stepped up. Buttens of thousands of doses distributed per annum for a population of upwards ofsome 70 000 000 had little impact on annual mortality. Experiments in preventionby spraying kerosene on breeding pools were sporadic and confined to occasionalvillages. Throughout the 1930s, the death rate from malarious fevers continued to
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Table 4. Bengal basin. Distribution of Anopheles species identified by mid-twentieth century [46].
epidemiological breeding: site, adult feedingtype of malaria region vector seasonality habit
stable–endemic,hyperendemic wherevector populationdensity high
inland, mature,moribund delta
A. philippinensis river relicts—pools,streams, swamps, clearwater, in sunlight
chiefly domestic,anthropophilic
SE coastal deltas A. sundaicus lagoons formed by siltingof river mouths,especially wheremangrove cleared
anthropophilic >
zoophilic
SE coastal plains A. aconitus swamps, ponds, creeks,river-beds, where cattleabundant
zoophilic >
anthropophilic
A. annularis still water with floatingvegetation active at12◦C. Increasedlongevity in autumn
zoophilic,anthropophilic
north, NE hills A. minimus clear, slowly movingwater with grassyedges, death point40◦C
zoophilic,anthropophilic
dominate registered annual mortality: at an average for 1937–1940, for example,of 15‰. ‘The total loss . . . inflicted on this province annually by this devastatingscourge is colossal’ [47, p. 67].
3. Punjab: the upper Indus
From its debouchement at the Salt Range—the northwestern foothills of theHimalaya—the Indus river flows for some 1600 km through the semi-arid plains ofIndian and Pakistan Punjab and Pakistan Sindh to its exit into the Arabian Seasoutheast of Karachi. It drains a foreland basin of 970 000 km2—the world’s 12thlargest, and forms the seventh largest known coastal delta of some 30 000 km2. Itsannual sediment load, deposited in the sea over aeons, some 60 per cent of it by theSW monsoon flood, has formed the gigantic Indus Deep-sea Fan, in its volume ofca 5 000 000 km3 second only to the Bengal (Ganges–Brahmaputra) Fan [48,49](see table 5). An integral part of an Indo-Gangetic river system following thecollision of the Indian and Eurasian plates before 126 Ma, the Indus is thought tohave separated from the Ganges, which subsequently expanded eastward. TheIndus, and its main tributaries, migrated west. The impetus may have beena strengthening in the SW monsoon from ca 5 Ma, increasing erosion in theHimalaya, bringing down a greater load of coarse sediments from increased erosionin the western Himalaya [48,52]. As the sediment-laden rivers of the westernIndo-Gangetic system burst from the steep gorges in the Himalayan foothillsinto the low-gradient foreland basin, they overwhelmed old courses of the inlanddelta to form new streams successively to the west [50,51,53]—events similarto sequential river shift in the Bengal basin, as described above, to fetch up intheir present course, further gross westward movement being forestalled by themountain ranges rising northward from the SW.
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Table 5. History of the Indus river system. Sources: Inam et al. [48], Clift & Blusztajn [50] andSchroder [51].
age geological era events
>126 Ma Early Cretaceous fragmentation of Gondwanaland: northward drift ofIndian plate, colliding with Eurasian plate
75 Ma Late Cenozoic palaeo-Indus north, west of present location57–37.5 Ma Eocene parallel, west-flowing streams south and north
(palaeo-Indus) of Himalayacontinued uplift of Himalaya, Suleiman
Range—corresponding flexion of Indian plate,formation of Indus foreland basin
24.5–5 Ma Miocene–Pliocene ca 18 Ma: diversion of upper Indus south, throughHimalaya close to Nanga Parbat massif, intoforeland basin and east, into Ganges
<5 Ma separation of Indus, Ganges<20 ka Pleistocene last glacial maximum
expansion of Ganges basincontraction of Indus basinwestward migration of major Indus tributariesmain depositional lobe of Indus (coastal) delta
formed: westward shift in main channelin westward shift, obsolete–obsolescent channels
abandoned by main streams, forming riverainsshift of upper and lower Indus to west constrained
by uplifting western ranges running north fromKarachi
The westward migration of the Indus (figure 4) has been the object of closeattention from the early nineteenth century, when British Indian surveyorsand administrators, learned in Sanskrit and with a bent for history, began toexplore the abandoned riverains (jhils in the vernacular: obsolescent–obsoleteriver channels in Punjab, turned to ponds during monsoon) of the Indusbasin for evidence of the ‘lost river Saraswati’ of Vedic times, the Ghaagar–Hakra–Nara Nadi river systems and the Indus (Harappan) civilization itselfand subsequent settlements, successively abandoned and now identified fromarchaeological remains [54,56–58].
With a resurgence of interest in the Indus civilization since the late twentiethcentury, professional exploration of the obsolete–obsolescent foreland basin hasintensified, equipped with remote-sensing imagery and the latest geophysical andgeochemical techniques [51,53,59–61]. As yet, there is no consensus on the exactcourses taken by former Indus channels.
The annual monsoon cycle in Punjab was distinguished by its volatility. TheNE monsoon, from December to March–April, was more regular and ‘copious’—ata mean monthly precipitation of ca 0.5–1.3 inches (13–33 mm)—than in the southand east Gangetic valley. A transitional phase followed, through April–May andinto early June, marked by ‘scanty and uncertain rainfall from occasional thunder-storms’. Rainfall in the SW monsoon, from mid–late June to September, was in
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100 km
(a)
(b)
100 km
Figure 4. The Indus foreland basin. Westward river shift, plotted from historical documents andarchaeological remains. (a) 2000 BC; (b) AD 1940 (based on Wilhelmy [54]). For a critique ofWilhelmy’s reconstructions in the light of LANDSAT imagery, see Ghose et al. [55]. Dashed linesin panel (b) represent abandoned channels.
inverse proportion to distance from the coast—‘much lighter than elsewhere inIndia except in Sind . . . ’ [1, pp. 568, 600–602]. Even submontane Rawalpindiregistered a total precipitation for the season of 17.2 inches (437 mm), while thetotal average fall at Multan, on the south-central plains, was 5 inches (127 mm)from June to October.
The south west wind is not . . . here a rain-bearing current. It probably comes as much fromthe desert as the sea, and passing in its course over the heated arid plains that surroundthe lower course of the Indus, the increase of its temperature counteracts any tendency toprecipitation which may be induced by the upward diffusion of its vapour . . . [It] appearsthat during the SW monsoon the winds perform a kind of cyclonic circulation in the Punjab,converging from the plains to the south and east
There was a similarly marked annual variation in mean temperature, from55◦F (13◦C) in January, when Punjab was ‘the seat of greatest cold’, to a sharprise in March–April to 95◦F (35◦C) and upwards. In the SW monsoon, Punjabbecame ‘the seat of the highest temperature’, at means of over 90◦F (32◦C)[1, pp. 586–588]. Humidity in the Punjab plains was at a minimum in May–Juneand at a maximum in December.
Dry winds were characteristic of Punjab’s weather, and drought frequent. Inan examination of anomalies in annual precipitation in Punjab from 1845 to 1878Blanford showed a complementarity between NE and SW monsoons. In 12 years
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of the series, the NE rains were excessive and SW deficient; in 13 years, theconverse was recorded; in 3 years, both NE and SW monsoons were excessive;in 6 years, both were deficient. Further, in years of dry land winds and deficientrainfall during the SW monsoon, an unusually heavy snowfall was recorded inthe NW Himalaya. From this, Blanford suggested that ‘the varying extent andthickness of the Himalayan snows exercise a great and prolonged influence on theclimatic conditions and weather of the plains of North-Western India’ [62, p. 3]. Arecent assessment by Fasullo [63] of Blanford’s hypothesis with satellite imagerysuggests that the association of Eurasian snow cover and the intensity of themonsoon is complicated by the El Nino Southern Oscillation (ENSO). NorthernIndia showed the closest association between rainfall and snow cover, vindicatingBlanford.
The distinctive topographical features of the eastern Indus basin were wellrecognized in official records of the Government of Punjab. These vast, semi-arid plains, low in gradient and apparently featureless, were distinguished, oncloser inspection, by ‘great riverains’ lying slightly below the surrounding country,which had been deserted by rivers migrating to the west. Soils were composedmostly of fine silt sediments, laced with salts—especially CaCO3, deposited inconcretions known locally as kankar in the desiccation of summer, which formedan indurated layer a few feet below the surface. The riverains were peculiarlyliable to flood from mid-June to early September, during the SW monsoon. Onits cessation, surface pools formed by rainfall gradually dried out, ‘as much byevaporation as by absorption’, where kankar layers prevented downward drainage[64]. The SW monsoon gradually weakened in its progression northwestwards,with the heaviest precipitation at the eastern extremity of the Indus basin and inthe submontane tracts to the north, and the least, even in a strong monsoon, inthe west.
In the malaria map (figure 1), the epidemic tracts in the NW region are roughlyco-extensive with the foreland basin of the Indus (Punjab), the upper Gangesbasin (Northwestern Provinces, from 1901 United Provinces of Agra and Oudh)and the arid desert of Rajputana to the west. Christophers & Sinton [16] describethe prevalence of malaria in this area as ‘markedly seasonal’, being enhancedsomewhat in early summer (March–April), followed by a lull on account ofwidespread desiccation, with a marked increase in early autumn (late September),following the cessation of the SW monsoon.
Within these tracts of unstable–epidemic malaria, the map shows a dense beltstretching from the centre and east of the Indus basin on to the upper Gangeticplain, roughly co-extensive with the obsolete–obsolescent Indus riverains. Thisbelt represents ‘fulminant malaria . . . vast cyclical disturbances peculiar to thisregion’ manifested in a great, pandemic exaggeration of the normal autumnalrise in prevalence, at ca 8 year intervals and mostly in years when the SWmonsoon was unusually heavy. An area of at least 25 000 km2 was affected, withdeath rates of 40‰ or more [2,64,65]. Spleen rates among the population of this‘hyperepidemic’ belt were characteristically low, ca 10 per cent before epidemics,rising to 80–90% in their aftermath, to fall gradually back to the usual low levelover the following 5 or so years. Endemicity, and hence immunity, was low [16].The vast areas of the eastern and central riverains afflicted with epidemic malaria,particularly in its fulminant form after an exceptionally heavy SW monsoon, madePunjab ‘the unhealthiest province in India’ [66].
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Table 6. Indus basin delta, Punjab–Sindh. Distribution of Anopheles species identified in thetwentieth century [46].
epidemiological adult feedingtype of malaria region vector breeding: site, seasonality habit
unstable–epidemic,with ‘fulminant’,autumnal,hyperepidemicfoci
NW India: Indusforeland basin
A. culicifacies chief malaria vector of NWIndia, largely rural, breedsin winter in sluggishstreams, river-bed pools,freshwater sheets, irrigationchannels, particularlyassociated with extensiveflooding, hibernates in larvalstage, adults common fromMay 1 to end December
indifferent:zoophilic–anthropophilic
unstable–epidemic NW India: Indusforeland basin
A. stephensi sunlit pools, stream beds,marshes, hardy, long-lived
anthropophilic >
zoophilicepidemic central-
submontaneA. fuliginosus breeds December–January,
found throughout year
The seasonality of malarious fevers in Punjab and their association withriverains and heavy SW monsoons had long been recognized by the SanitaryCommissioner’s department. A review of fever mortality from 1869 to 1876showed a sudden, steep increase in the monthly death rate from fever—mostlyof the kind called ‘malarious’—through October to December, chiefly in areasof poor natural drainage with additional ‘accidental obstruction’ [67, pp. 33–34].Rainfall was ‘invariably excessive every third year’ and associated with maximumprevalence and fatality from epidemic fever ‘in low-lying tracts where drainage isobstructed’ [67, pp. 33–34]. In east Punjab, ‘vast jhils’ formed in the abandonedchannels of the Indus in the wake of a heavy SW monsoon in 1887 and the feverdeath rate rose: in 1887, to over 25‰ [68, p. 33].
From early in the twentieth century, the chief Anopheles species associatedwith epidemic malaria in the Punjab were readily identified—A. culicifacies chiefamong them, infesting the central and eastern riverain tract (table 6).
The highest mortality from malarious fevers was recorded in years of excessiveSW monsoon preceded by deficient precipitation in the NE phase. With theexpansion of breeding grounds in the waterlogged riverains under the heavysummer rains, the Anopheles population exploded, with consequent increase intransmission of plasmodium. Drought in the preceding winter and spring alsocontributed, indirectly, to increased transmission by changing the biting habitof the female Anopheles. A. culicifacies, the predominant species in Punjab,was zoophilic and would only turn to man ‘as an alternative to starvation’[11, pp. 820–821; 69, p. 882]. In rural Punjab, such zoophilic Anopheles wouldfeed preferentially on cattle. The death of cattle in vast numbers from droughtobliged Anopheles to feed off humans [70].
The melancholy record continued in the twentieth century. Localized epidemicsof malaria were recorded in districts marked by riverains and visited byheavy rainfall and floods. A. culicifacies was regularly identified as the agent[65, pp. 12–14; 71, p. 11; 72, p. 19; 73, p. 1].
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Within the regions of the Indus basin characterized by epidemic malaria, therewere exceptions to the general rule of low endemicity, pockets where spleen rateswere persistently high, and immunity in adults relatively rare. These pocketswere ‘more associated with old defective [irrigation] systems, where leakage andwaterlogging are a feature’—perennial seepage and pooling in terrain and climategeared to episodic, seasonal waterlogging [64]. Whether the large-scale canalsystems for perennial irrigation introduced by the British Government of Indiawere responsible for an aggravation of malaria, if so, how much, and how torectify it, were questions repeatedly debated by Government throughout thenineteenth and early twentieth century [74]. The western Jumna Canal, the firstlarge-scale system in British India, was a strict realignment-cum-reconstructionby British Indian military engineers in the early nineteenth century of an oldMoghul irrigation channel meandering through low-gradient plains just to thewest of Delhi. Defective drainage along the lower reaches of the canal and the‘liability of the inhabitants to miasmatic fever’ were the subject of an extensiveenquiry in 1847: the three-man committee travelled 1400 miles in a few months,visited more than 300 villages and clinically examined more than 12 000 villagersof all ages. From the findings, Surgeon-Major Dempster devised the spleen rate(which served as index of malarial infection until replaced by blood sampling forparasitaemia early in the twentieth century). The committee concluded that intracts of stiff, retentive soils, swamps bordered on the canal, from seepage and/orthe canal embankments’ obstruction to natural drainage. The district of Karnalwas especially remarkable for insalubrity [75].
From the 1850s to 1885, various drainage schemes were implemented,culminating in realignment in 1885, with little change in the annual mortalityfrom fever in the low-lying districts [76, pp. 250–252]. In dry years, the deathrate from malarious fever in Punjab fell, except in Karnal district. With anabnormally heavy SW monsoon, it was the worst in the Province—endemicitycomplicated by fulminant epidemic [65,77,78]. Intensive epidemiological studiesof the Karnal district in the 1930s by the Malaria Survey of India showed why: theswamps were favoured breeding places of the chief malaria vectors of the Punjab,A. culicifacies, A. stephensi and A. fuliginosus [77,78].
The great canal systems pioneered in the late nineteenth and early twentiethcenturies to reclaim and colonize the uplands of the western Indus basin had abetter record, largely because the natural drainage was by no means defective[12]. But where perennial canals, their distributaries and the embankments ofroads and railways cut across obsolete and obsolescent riverains of the centraland eastern basin, perennial swamps arose and, with them, malarious fever settledinto endemicity [76, pp. 254–255].
4. Sindh: the lower Indus
South of the foreland basin, the Indus narrowed in a relatively steep-sided channelto emerge near Sukker, to spread over alluvial plains with a fall of a mere 55 min 402 km into a huge delta. Most of its old channels east of the main streamwere abandoned by the main stream of the Indus in its shifts to the west: ‘thewhole surface is furrowed and cross-furrowed by the beds of ancient river channelswhich have left their meanders’, shrinking to a string of dhands or salt lakes. On
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the eastern boundary, one old channel, the eastern Nara, meandered southwards[79]. The climate was, and remains, harsh—the epitome of monsoon instability.In field surveys of the 1920s and 1930s, rainfall was described as ‘scanty andprecarious’, average annual precipitation ranging from 73 mm at Sukker, at theapex of the southern, inland Indus delta, to 179 mm towards its base, with wildinterannual variation; summer temperatures of at least 45◦C and a seasonal meanhumidity of 41 per cent. Sindh was the driest and hottest of British India’sprovinces [18,48,79,80].
Throughout most of its moribund delta, the bed of the main Indus streamis higher than the surrounding country. The subsoil water rises at the time ofevery inundation, assisted, in the traditional, rich, rice-growing tracts of the deltaclosest to the main stream, by flooding from seasonal, inundation canals.
Sindh was visited periodically by unstable epidemics, as in 1897, 1906, 1916–1917 and 1929, with a high death rate generally through the population,most likely from a coincidence of unusual rainfall and flooding [81–83]. Stable,hyperendemic pockets were recognized, chiefly in the rice-growing tract ofLarkana on the west bank of the lower Indus, distinguished by a moderatedeath rate and high immunity. Elsewhere, ‘the amount of endemic malariaaccording as local conditions were favourable or unfavourable for the breedingof malaria-carrying mosquitoes . . . Thus villages situated on the banks of “dead”rivers (e.g. the Sind Dhoro, a former bed of the Indus) were invariably highlymalarious’ [80,81].
In 1932, the Lloyd Barrage at Sukker with its canal system, the penultimategreat irrigation enterprise of the British Indian Government, began operation.In 1927, before the Barrage’s construction, Government had launched the SindMalaria Inquiry. In an exemplary series of field surveys, from May 1928 toMay 1935, Gordon Covell and Subedar J. D. Baily surveyed selected areasin all talukas (district subdivisions) that came under the command of thescheme, before and after its coming into operation, together with certain tractsoutside, for comparison. Establishing the incidence and prevalence of malariaas above, prior to the scheme’s operation, they revisited each area after itopened in 1932, to assess its effects. They concluded that, in many places,the incidence of malaria had increased: in the areas most affected by theepidemic of 1929, the spleen rate had fallen below its level immediately afterthe epidemic—the usual finding, as earlier, in Punjab—but was still much higherthan in the 10 year period between epidemics observed before the barragewas opened.
The higher incidence, and prevalence, of endemic malaria was to be attributedto ‘conditions favouring malaria transmission produced by the operation of theBarrage Scheme’—familiar from long experience in northern India: a rise insubsoil water level; actual or threatened waterlogging; seepage from some newcanals; the ‘cutting-off of sections of old canals, thus forming prolific Anophelesbreeding grounds; a 40 mile lake had formed above the Barrage, and the subsoilwater level had risen along it; rice cultivation had expanded in the areas outsidethe scheme, under irrigation with water from the lake and remodelled canals—awretched catalogue of the adverse effects of irrigation and especially over-irrigation by inundation in the presence of defective drainage, largely determinedby geomorphology, and a highly unstable climate, so familiar from the NE Indusbasin [80,84].
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Recommendations for rectifying a root cause of intensified malaria transmissionby the provision of efficient drainage would not be implemented—or could not,given the simple impediment of low gradient. The options for treatment, stronglyrecommended by Covell [84], were wretchedly inadequate.
It was fitting that, in 1952, the year Macdonald published his theoryof equilibrium, an India-wide programme for the eradication of malaria byeliminating vector populations with dichlorodiphenyltrichloroethane (DDT) wasunder way, with considerable initial success. The interruption of the programmein the late 1950s has led to a revival of malaria, albeit not with its formerferocity. Our understanding of transmission and transmissibility, while vastlymore sophisticated in recent years, with the introduction of complex probabilisticanalysis and stochastic modelling, is still far from complete.
5. Conclusions
The use of historical records in reconstructing the recent past of the Earth, itsgeomorphological processes and the variations of its climates is often frustratedby the limitations of elderly data. For the Indian subcontinent, it is a differentmatter. Through the later nineteenth century, to the mid-twentieth century,officers of the British Government of India—engineers, surveyors, geologists,meteorologists, zoologists, botanists, physicians—explored the subcontinent’slandscape, its mountains, rivers, flora, fauna, its populations, the history of theirhabitations, their occupations and their diseases, with inexhaustible curiosity,great skill in observation and methods of surface recording and a remarkablecommand of the language of analysis, verbal and mathematical.
The great Indo-Gangetic river systems of northern India, the site of continuoushabitation over many millennia, were a constant focus of scientific enquiry bythe Imperial Government. From its records, unsurpassed in their consistencyand accuracy over the better part of a century, an extraordinary river historycan be reconstructed—extraordinary in its events, given the dynamic nature offluvial processes forming these great deltas and the variability of the monsoonweather system to which they were subject, and in the conditions of theirenvironment, which favoured vector-borne disease, principally malaria. With sucha history to hand, present-day problems of rivers and their environment may bebetter understood.
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