Transactions Template


 

  

JOURNAL OF ENGINEERING RESEARCH AND TECHNOLOGY, VOLUME 7, ISSUE 1, APRIL, 2020 
  

  

10  

Health Risk Assessment of Groundwater Contamination 

Case Study: Gaza Strip 

Luay I. Qrenawi 
(*)

, Reem Abu Shomar 
(**)

 

(*)
 Corresponding Author, Civil Engineering Department, University College of Applied Sciences, Gaza, 

Palestine. P O Box: 1415, lqrenawi@ucas.edu.ps 

(**)
 Program Coordination Unit-PWA, Palestinian Water Authority, reemabushomar@gmail.com  

https://doi.org/10.33976/JERT.7.1/2020/2  

Abstract—Gaza Governorates are suffering from shortage problems and poor quality of groundwater that is 
being pumped from 281 municipal wells. According to the latest data available at the Palestinian Water 
Authority (PWA), the water consumption can be distributed on municipal consumption 96.428 MCM and 
agricultural sector consumption 95.3 MCM. The annual recharge is less than the pumping rate with more than 90 
MCM; resulting in declining water level, sea water intrusion and hence high chloride concentrations. Nitrate 
levels are increasing due to the improper systems of wastewater disposal, excess use of fertilizers and landfill 
leachate. The nitrate level exceeds the WHO limit in more than 90.6 % of Gaza Governorates municipal wells 
for the year 2018 (223 wells from a total of 245 wells. Due to the health impacts of nitrate, health risk 
assessment was conducted based upon the available quality data of 245 municipal wells. The risk assessment 
method adopted by the United States Environmental Protection Agency was utilized in this study. Three 
categories of receptors were assessed; infants, children and adults. The study revealed that the health risk values 
for adults is acceptable in 22 wells only while it is unacceptable in the other 223 wells. For children and small 
infants, the situation was riskier and the study outlined that none of the municipal wells in Gaza Governorates 
was suitable for drinking purposes for these two categories of people. The study recommended that actions 
should be taken to minimize the risk associated with drinking groundwater, looking for alternative water 
resources is to be seriously considered, community participation should be encouraged, people should know that 
their source of water is unsuitable and further studies that consider the impact of nitrate in groundwater on the 
public health in Gaza Strip should be performed. 

Index Terms— Gaza Governorates, nitrate, municipal wells, health risk assessment, groundwater, public health. 

I. INTRODUCTION

Gaza Strip is a narrow area located along the coastal 

southwestern zone of the occupied Palestine just near the 

Mediterranean Sea. It is divided into five governorates with 

a total are of about 365 km
2
 and a population of about 2 mil-

lion. High current and expected future population growth 

rates will undoubtly lead to greater impacts on natural re-

sources, especially the water. The over pumping of the Gaza 

groundwater aquifer (the only source of water) has resulted 

in continuous declining of the local groundwater levels and 

degrading its quality. Seawater intrusion and up-coning of 

deep brine water are considered as the major challenges im-

pacting the existing groundwater in Gaza Strip. As Gaza 

strip is located in an arid area with an unsustainable water 

resource, it faces serious problems of water in terms of 

quantity and quality. According to the water budget compo-

nents of Gaza Strip, it can be realized that the water re-

sources in Gaza are usually fluctuating around a stationary 

average, while the population is increasing continuously. 

The higher natural population growth rate of Gaza Strip (as 

indicated by many organizations as the highest rate in the 

world) has transformed water to a chronic and worsening 

imbalance in the population – water resources equation 

(Qrenawi, 2007, Eldadah et al., 2007, Qrenawi et al., 2002). 

The present state of the water sector in Gaza is distressing 

and has been described by many organizations as a humani-

tarian crisis. The main source of domestic and agricultural 

water is the groundwater, which is almost totally polluted 

and at the present yields a flow of unacceptable quality for 

domestic usage. The amount of water available to the people 

of Gaza is also insufficient, while its deteriorated quality 

causes large adverse public health impacts. According to the 

latest data available at the Palestinian Water Authority 

(PWA) database, the water consumption can be distributed 

on the different sectors as follows: municipal consumption 

96.428 MCM (52%); of which 13 MCM is suitable for 

drinking purposes and agricultural sector consumption 95.3 

MCM (48%) (WRD-PWA, 2014, WRD-PWA, 2018). The 

annual net deficit in the groundwater aquifer in 2016 is 

about 90 MCM and predicted to reach 180 MCM by 2035; 

indicating that the only source of fresh water in Gaza Strip is 

mailto:lqrenawi@ucas.edu.ps
mailto:reemabushomar@gmail.com
https://doi.org/10.33976/JERT.7.1/2020/2


Luay I. Qrenawi, Reem Abu Shomar/ Health Risk Assessment of Groundwater Contamination  Case Study: Gaza Strip (2020) 

  

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being drastically over pumped and hence the aquifer is 

showing clear signs of irreversible failure or collapse, with 

quickly advancing the deterioration of the Gaza water re-

sources in terms of both quality and quantity (Aiash and 

Mogheir, 2017, Eldadah, 2013). 

The water municipal consumption varies slightly according 

to the time of the year; August is the month having the max-

imum consumption while February has the minimum con-

sumption. Figure 1 outlines the annual municipal water con-

sumption for Gaza Strip Governorates in 2018. According to 

the data available at PWA, this amount of water was extract-

ed from 281 municipal wells distributed all over the Gaza 

Strip; as shown in Figure 2 (Eldadah et al., 2007, WRD-

PWA, 2018). 

 

 
Figure 1 Municipal Water Consumption in Gaza Gover-

norates (WRD-PWA, 2018) 

 

Currently, groundwater extraction is far exceeding the rate 

of aquifer recharge. The level of groundwater is declining 

and the chloride concentrations are increasing, these results 

are expected; rendering the water unsuitable either for drink-

ing or irrigation purposes. The random disposal of raw 

wastewater and solid waste to the ground surface and the 

uncontrolled use of fertilizers have also contaminated 

groundwater and raise the nitrate levels in certain areas to 

unacceptable concentrations (Eldadah et al., 2007). 

Recently, and due to the continuous degradation of ground-

water quality in Gaza Strip, public attention has significantly 

grown and has concentrated on anthropogenic causing of the 

problem. The Gaza Strip Aquifer is the most important 

source of water to agricultural, domestic, and industrial de-

mands (Lubbad and Al-Yaqoubi, 2007). 

The nitrate concentration in groundwater has increased in 

the last years; this phenomenon has primarily taken place in 

the coastal area, where the water sources are close to popula-

tion clusters and to industrial and agricultural regions. The 

increased accumulation of nitrates in groundwater is respon-

sible for creating health dangers to the population who are 

using this contaminated water (Lubbad and Al-Yaqoubi, 

2007). In this paper, health risk assessment – a decision sup-

port tool – of groundwater contamination by nitrate will be 

presented; risk management will also be outlined. 

II. LITERATURE REVIEW 

SOURCES OF NITRATE: 

Nitrate is considered as a stable oxidized form of the 

combined nitrogen in the majority of environmental media. 

Different sources of the combined organic or ammonia ni-

trogen can be considered as the main source of nitrate, this is 

due to the fact that most of nitrogenous compounds in water 

tends to be transformed with a certain means to nitrate. Ni-

trates exists naturally in mineral stores including sodium or 

potassium nitrate, in soils, seawater, freshwater sources, the 

atmosphere, and in the animal and plant life. Main nitrate 

sources include, but not limited to, agricultural fertilizers, 

wastewater, landfill leachate, and livestock waste (Shelton 

and Lance, 1999). 

For the case of Gaza Governorates, nitrate is commonly in-

corporated into groundwater source through widespread or 

diffuse sources, normally known as non-point sources, 

which can’t be easily identified. Point source contaminants 

are also a major cause of contamination. By looking at the 

land use map of Gaza Strip, one can conclude that the agri-

cultural activities are mainly located in the eastern part 

which has a thick unsaturated zone with very low permeable 

layers, while the urban areas are located mainly in the west-

ern part which has a relatively thin unsaturated zone with 

high permeable sandy soil. 

 
Figure 2 Location Map of Municipal Wells in Gaza Strip 

(PWA, 2018) 
 



Luay I. Qrenawi, Reem Abu Shomar/ Health Risk Assessment of Groundwater Contamination  Case Study: Gaza Strip (2020) 

  

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The routine analysis results of nitrate for different wells lo-

cated in different agricultural and urban locations showed 

that the problem is particularly serious in public water sup-

ply wells as these are mainly located in un-sewered urban 

areas. These areas rely on cesspits for wastewater disposal 

which is basically not an efficient system of disposal. 

Wastewater infiltrates into the soil, which is mostly sandy of 

high permeability to the groundwater leading to the high 

levels of nitrate. Main causes of high nitrate in groundwater 

of Gaza are: 

 Infiltration of untreated wastewater in cesspits, sep-
tic and sewage discharges. 

 Leaching of chemical fertilizers. 

 Landfills' leachate (Lubbad and Al-Yaqoubi, 2007). 

HEALTH IMPACTS OF NITRATE: 

Nitrate is an inorganic dissolved substance that may gen-

erally found in groundwater samples. Nitrate is naturally an 

occurring chemical in the environment as a component of 

the nitrogen cycle. Relatively, the small amount of the ni-

trate found in natural waters is of mineral origin, most of it 

is coming from organic (solid waste and wastewater dis-

charges) and inorganic sources (artificial agricultural ferti-

lizers). However, oxidation by bacteria and nitrogen fixation 

by plants can both result in the formation of nitrate. High 

levels of nitrate and nitrite can cause dangerous illness due 

to acute exposure. High concentrations of nitrate in drinking 

water cause both environmental and health concerns due to 

its toxicity. Methaemoglobinaemia, or known as blue baby 

syndrome, is the major health concern attacking infants that 

are bottle fed with formula prepared with drinking water 

(CAWST, 2009, Shelton and Lance, 1999, EPA, 2001). 

Nitrate toxicity results since the human’s body reduces ni-

trate to nitrite. This reaction occurs in human saliva at all 

ages and in the infants’ gastrointestinal tract within the first 

three months of life. Nitrite toxicity is demonstrated by vas-

odilatory/cardiovascular impacts at high dose levels and 

methemoglobinemia at lower dose levels. Methemoglo-

binemia is an impact in which oxidation of hemoglobin to 

methemoglobin takes place; and hence asphyxia results. 

Infants up to the age of three months, the most sensitive 

population to nitrate. This can be figured out by the fact that; 

in the case of adult and child, approximately 10 % of the 

taken in nitrate is converted to nitrite, while 100 % of taken 

in nitrate by the infant can be converted to nitrite. The im-

pacts of methemoglobinemia are quickly reversible, and 

there are, therefore, no accumulation of these impacts. It 

results in the difficulty of breathing and turning skin to blue 

due to the absence of oxygen. It is a dangerous case that can 

sometimes cause death (CAWST, 2009, Shelton and Lance, 

1999). 

Due to the insufficient data of animal and humans, the EPA 

classifies both nitrate and nitrite as Group D contaminant. 

For the case of infants, nitrate compounds tend to demon-

strate adverse toxic impacts. Because of the widespread oc-

currence of this toxicity in water, nitrate has been regulated. 

Recent advances in research have proved that nitrate of high 

concentrations may cause cancer for adults. The World 

Health Organization (WHO) stated that the concentration of 

nitrate in drinking water should be < 50 mg/L. This regula-

tion is set to protect the bottle-fed infants, in the short-term 

exposure, from methaemoglobinaemia illness. (Shelton and 

Lance, 1999, Qrenawi, 2006, CAWST, 2009). 

III. SIGNIFICANCE OF THE RESEARCH 

While the guideline stated by the WHO for nitrate is 50 

mg/l, and it exceeds 300 mg/l in some areas of Gaza Strip. 

Since groundwater is the most important potable water 

source in Gaza strip; this encourages the researchers to be 

care of performing health risk assessment of groundwater 

contamination in Gaza Strip. Figures 3 to 7 outline the ni-

trate concentration in Gaza Governorates in the year 2018 

for 243 municipal wells. 

Figure 3 Nitrate Concentration in Northern Governorate 



Luay I. Qrenawi, Reem Abu Shomar/ Health Risk Assessment of Groundwater Contamination  Case Study: Gaza Strip (2020) 

  

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Municipal Wells (PWA, 2018) 

Figure 4 Nitrate Concentration in Gaza Governorate Mu-

nicipal Wells (PWA, 2018) 

Figure 5 Nitrate Concentration in the Middle Governorate 

Municipal Wells (PWA, 2018) 

Figure 6 Nitrate Concentration in Khan-Younis Governorate 

Municipal Wells (PWA, 2018) 

Figure 7 Nitrate Concentration in Rafah Governorate 

Municipal Wells (PWA, 2018) 

 

Due to the unstable political issue in the Palestinian territo-

ries and its negative impacts on the security and socio-

economics, the water situation in Gaza Strip became worse 

in terms of water quality deterioration, water depletion and 

water supply system efficiency. By referring to the previous 

figures, one can conclude that nitrate level exceeds the 

WHO limit in more than 90.6 % of Gaza Governorates mu-

nicipal wells for the year 2018 (222 wells from a total of 245 

wells); indicating that the problem of water is not only a 

quantity problem but also a quality one. 

A WHO study found a high concentration of nitrates in the 

water supply from wells in different localities within the 

Gaza Strip, and this nitrate contamination was found to be 

the cause of the incidence of ―blue-baby syndrome‖ among 

infants in the Gaza Strip (IBRD, 2009). Whilst this disease 

primarily affects young children, nitrate contamination can 

also affect pregnant women and might increase the risk of 

certain types of cancer (Abu Naser et al., 2007). 

(Shomar et al., 2008) stated that recent observations re-

vealed a high positive correlation between the concentra-

tions of nitrate in groundwater of the Gaza Strip and the 

occurrence of methemoglobinemia in babies younger than 6 

months. Among 640 babies tested in Gaza, 50% showed 

signs of methemoglobinemia in their blood samples.  

A study into the relationship between the concentration of 

nitrates in drinking water and the disease of Methemoglo-

binemia in children under 6 months old was conducted in 

2001. Twelve primary health care centers were involved in 

the study and results showed a strong positive relationship 

between levels of nitrates and contraction of the disease. The 

highest incidence of the disease was found in Khan Younis 

coinciding with the highest levels of water nitrates. Moreo-

ver, the proportion of Methemoglobinemia incidence was 

highest in children between 1 – 3 months old due to their 

dependence on milk and hence their higher intake of ni-

trates, while it decreased in those between 3 – 6 months old 

(Ramahi, 2013). 

IV. RISK ASSESSMENT 

Using risk assessment as decision making process tool 

has given more importance in the last two decades, because 

it has become evident that different statuses cannot be easily 

referred to as either safe or unsafe (Langley et al., 2002). 

Risk does not have a specific and clear definition; everyday 

language uses the term risk to indicate a chance of danger or 

catastrophe. When used in the risk assessment theme, it has 

a concise definition; the combination of the probability or 

frequency of occurrence of a defined hazard and the magni-

tude of the consequences of the occurrence. Or it is the sys-

tematic steps that determine the potential effects of a chemi-

cal, physical, microbiological or psychosocial hazard on a 

certain human population or ecological system under a cer-

tain set of conditions and for a specified period of time. It is 

a set of logical, systemic and well defined activities that give 

comprehensive information to risk managers, specifically 

those who put policies and regulations and decision makers 

with a good identification, measurement, estimation and 

evaluation of the risk linked to specific natural incidents or 

man-made activities, so that the best possible decisions are 

made (Blumberga, 2001, Langley et al., 2002). 

The risk assessment process can give a systematic concept 

for characterizing the nature and extent of the risks related 

with specific hazards. The main goal of risk assessment is to 

give the best available scientific, social and practical infor-

mation concerning the risks, so that these information can be 

extensively studied and therefore the best alternatives can be 

formulated and hence the best decisions can be taken (Petts 

and Eduljee, 1994, Langley et al., 2002). 

Tracking and following of risk needs an accident, pathway 

for transport and a receptor that could be impacted at the 

place of exposure. Basically, risk assessment gives a well-



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14  

organized concept for figuring out the nature and extent of 

the relationship between the cause and effect (Petts and 

Eduljee, 1994, Langley et al., 2002). 

Good risk assessment needs a high level of scientific skill 

and objectivity and should be differentiated from the risk 

management process which chooses alternatives as a result 

of the health risk assessments process. Risk management 

needs scientific, social, financial and political data and also 

needs judgments to measure the degree of tolerance required 

of risk and reasonableness of expenses. Risk assessment 

should give a confidential, objective, applicable and equi-

ponderant analysis (Langley et al., 2002). 

HEALTH RISK ASSESSMENT: 

The process used to determine the potential effects of 

physical, biological, chemical or social agents on a certain 

human population under specified conditions within a cer-

tain time period is referred to as health risk assessment 

(Langley et al., 2002). It includes identifying, analyzing and 

presenting information in terms of risk to human health, to 

support planning and making decisions. In this process, fa-

cilitating all social and economic data concerning the deci-

sion making is not always required. Also, its approach is not 

intended to be a part of the planning and management pro-

cesses (MOLEP., 2000). 

In the past two decades, the public’s consciousness of the 

health risks has been greatly raised despite the conducted 

limited risk assessment works. A great portion of the in-

creased public awareness has raised because of the extensive 

risk associated with some wastes such as the nuclear waste, 

and the consequent dumping of such waste into the ground; 

this practice will transfer the toxic substances present in this 

waste to the groundwater and hence its contamination. The 

public generally do not have benchmarks for making a sci-

entific comparison among the different threats to their health 

and the safety and the quality of the environment. The pub-

lics’ increased awareness about the risks due to groundwater 

contamination has an impact not only on looking for clean 

and safe water, but also greatly contributed to searching for 

alternative safe water resources (Garrick, 2002). 

STRENGTHS OF RISK ASSESSMENT: 

 It is a mechanism that aids decision making especially 
the choice between options for risk reduction. 

 It is a means of comparison between risks to determine 
whether there is equity of action or that the action is 

proportionate to the risk. 

 It is a technique that can break down complex systems 
and identify areas of processes or plant where risk re-

duction options can be most effective. 

 It clearly outlines the relationship that connects the 
natural environment and the human activities. 

 It removes the doubt of stakeholders so that probable 
changes to the environment from human activities are 

being taken into account. 

 It is valid scientifically, defensible and applicable 
(MOLEP., 2000). 

UNCERTAINTY OF RISK ASSESSMENT: 

Although risk assessment is a well-established scientific 

approach, it has some demerit. It must be recognized that the 

present state of knowledge concerning the impacts of specif-

ic constituent is incomplete. Thus, each step in the risk as-

sessment involves uncertainty and the best possible utiliza-

tion of available information must be ensured. In hazard 

identification, most assessments depend on animal tests and 

yet the biological systems of animal are different from those 

of humans. In dose response, it is often unknown whether 

safe levels or threshold exists for any toxic chemical. Expo-

sure assessment usually involves modeling, with the at-

tendant uncertainty as to substance release, release charac-

teristics, meteorology and hydrology. Because of these un-

certainties associated with risk assessment; the process gives 

only an estimation of the risk and not the real impacts ac-

companied to a certain proposed project or existing facility, 

so, the results of such an analysis should only be used as a 

guide in decision making (Langley et al., 2002, MOE, 1999, 

MOLEP., 2000). 

To overcome these uncertainties; the worst scenario or rea-

sonable worst scenario of hazard exposures are supposed. 

Using higher than the expected exposure cases confirms any 

expected problems and defines the dangerous pollutants or 

sensitive exposure pathways for more detailed study. In gen-

eral, this will give and over estimation to the real risk values. 

The resulted risk values that exceed the environmental or 

human health protection standard can be considered as a 

warning flag, rather than a real risk or impact (MOE, 1999). 

V. METHODS AND MATERIALS 

RISK ASSESSMENT MODELS: 

The risk assessment work is mainly dependent on deter-

ministic approaches whose objective is to track and follow 

the transport of the contaminants from its source to the re-

ceptor by different pathways. These approached are usually 

simple, and not necessary to be complicated. The determin-

istic analysis models usually use the mean or the median 

values that are at the central part of their distributions. An-

other method of analysis is the use of model parameter val-

ues to foresee the risks for people of exposure more than the 

90
th

 percentile of the population. To overcome the parameter 

and approach uncertainty, and to estimate the risk at differ-

ent pre-selected percentiles of the population, probabilistic 

analysis is utilized in the risk assessment process. The out-

puts of such approaches can be presents as point estimates or 

as probabilistic risk estimates (50
th

, 90
th

, 95
th

, 97.5
th
 and 

100
th

 percentiles). The values of the estimated risk can be 

obtained for different categories of receptors; for example; 

adults, children, residents, etc. (Metcalf and Eddy, 2003). 



Luay I. Qrenawi, Reem Abu Shomar/ Health Risk Assessment of Groundwater Contamination  Case Study: Gaza Strip (2020) 

  

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STEPS OF RISK ASSESSMENT: 

Risk assessment involves four distinct steps; they are: 

1. Hazard Identification: It includes defining the pollu-
tants that are assumed to pose human health hazards, 

measuring their concentrations in the environment and 

identifying the exact form of toxicity and the conditions 

under which these forms of toxicity may be found in ex-

posed population. The step also includes determining the 

available evidence and specifying whether a substance or 

pollutant causes a certain adverse health hazard. As a part 

of hazard identification, evidence is gathered on the po-

tential for a substance to cause negative health impacts to 

human or unacceptable environmental impacts. For hu-

mans, the principal sources of this information are clini-

cal studies, controlled epidemiological studies, experi-

mental animal studies and from evidence gathered from 

accidents and natural disasters (Garrick, 2002, Metcalf 

and Eddy, 2003). 

2. Exposure Assessment: Exposure is the method by which 
the hazard comes into contact with the organism; expo-

sure or access is the path that links the gap between the 

hazard and the population. For humans, exposure can oc-

cur through different pathways including air breathing, 

food ingestion or water drinking, absorption through the 

skin either via dermal contact or exposing to radiation. 

The main steps of exposure assessment are: defining the 

expected receptors from a given population, evaluating 

pathways and routes of exposure and quantifying the 

amount of exposures (Garrick, 2002, Watts, 1998, 

Metcalf and Eddy, 2003). 

3. Dose Response Assessment: The fundamental goal of 
this step is to define a relation – usually mathematical – 

between the toxic substance quantity to which human is 

exposed and the risk (unhealthy response) of that dose in 

humans. Typical dose response models that have been 

proposed and used for human exposure include: the sin-

gle hit model, the multi-stage model, the linear multi-

stage model, the multi-hit model and the probit model 

(Metcalf and Eddy, 2003).  

4. Risk Characterization: It is the last step in risk assess-
ment, in which the question of who is affected and what 

are the likely effects are defined to the extent they are 

known. It involves the integration of hazard identifica-

tion, dose response, and exposure assessments. It gives a 

general evaluation of the whole risk assessment process 

quality, as well as the confidence levels the assessors will 

have to estimate the risk and to formulate conclusions. It 

provides a risk description to individual persons and to 

communities in terms of extent and sharpness of poten-

tial harm. This step also connects the outputs of the risk 

assessment process to the risk manager (Garrick, 2002, 

Metcalf and Eddy, 2003). 
For carcinogenic pollutants, human exposures were trans-

formed into a lifetime cancer risk. Many standards specify a 

lifetime risk of 0.000001 or 10
-6

 or less to be insignificant. 

For pollutants responsible for other effects of toxicity – lung 

disease, birth defects or nerve damage – exposure to such 

pollutants is compared to an established standards of health 

protection, and the exposure ratio is then estimated. Obtain-

ing a ratio < 1 indicates that minimal or no negative health 

impacts are expected (MOE, 1999). 

Based upon the previous steps, the risk value can be cal-

culated by using the Equation adopted by Watts, 1998. 

 

𝐼 =
𝐶𝑊 × 𝐼𝑅 × 𝐸𝐹 × 𝐸𝐷

𝐵𝑊 × 𝐴𝑇
          (1) 

𝑅𝑖𝑠𝑘 = 𝐻𝐼 =
𝐼

𝑅𝑓𝐷
          (2) 

Where; 

I = Daily intake (mg/kg.day) 

CW = Contaminant Concentration (mg/l) 

IR = Ingestion Rate (l/day) 

EF = Exposure Frequency (days/year) 

ED = Exposure Duration (years) 

BW = Body Weight (kg) 

AT = Averaging Time (years) 

HI = Hazard Index 

RfD = Reference Dose 

VI. RESULTS AND DISCUSSION 

Nitrate, a soluble non-carcinogenic chemical, will be 

used in the risk assessment task. It is a pollutant that has a 

reference dose (RfD) of 1.6 mg/kg/day and the exposure 

route is ingestion. Nitrates level in excess of 150 mg/L poses 

an extreme risk to infants' health in the form of blue baby 

syndrome. Moreover, high nitrates may have carcinogenic 

effects for adults (Sharma and Reddy, 2004, Agha, 2006). 

The concentrations for the years 2007, 2011, 2015 and 2018 

of municipal wells in Gaza Governorates will be used in risk 

assessment calculation and presentation. 

By referring to Figures 8 to 11, it is clear that the risk value 

of adults is acceptable (slightly less than 1) in 27, 45, 38 and 

22 municipal wells only for the years 2007, 2011, 2015 and 

2018 respectively. This indicates that these wells may be 

used for municipal purposes. Most of these wells are located 

the Middle and Gaza Governorates. Few of them are located 

in Rafah, North and Khan Younis Governorates. This un-

balanced distribution is due to intensive agricultural activi-

ties the Northern and Rafah Governorates and lack of full 

sewage network coverage in Khan Younis Governorate. The 

remaining wells all over the Gaza Strip can't be used for 

some municipal purposes since the associated health risk to 

its direct use is unacceptable. Therefore, the probability the 

appearance of adverse health effects on people who drink 

this water is high. It is worth to mention that the number of 

suitable wells for municipal purposes increases in the year 

2011 due to digging new wells in Al-Mawassi area (that has 

good water quality). Unfortunately, the quality of this water 

is deteriorated immediately. This is because Gaza aquifer is 

over pumped with four folds of its sustainable yield, result-

ing in sweater intrusion. 



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The situation is riskier for the case of children (as indicated 

in Figures 12 to 15) once they depend on theses municipal 

wells for drinking purposes. For the case of infants, the situ-

ation is the riskiest once they depend on theses municipal 

wells for drinking purposes, as shown in Figures 16 to 19. 

By referring to Figures 12 to 19; one may conclude that the 

risk value for children and small infants is unacceptable in 

almost all wells of Gaza Governorates. For the case of chil-

dren, the number of wells with acceptable risk value is 3, 5, 

1, 0 wells for the years 2007, 2011, 2015, and 2018 respec-

tively. On the other hand, for the case of infants, only 2 

wells had acceptable risk value for the year 2011. Currently, 

none of the wells is suitable for drinking purposes for chil-

dren and infants all over Gaza Strip. Be referring to the risk 

values for the year 2018, it is noted that the smallest value of 

the risk for the children is 1.5 while for infants it is 2.1 (>1), 

which is unacceptable while the largest value is > 30 and 40 

for children and small infants respectively; which is ex-

tremely risky.  

 

 

 

 

Figure 8 Risk Map for Adults (2007) Figure 9 Risk Map for Adults (2011) 



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Figure 10 Risk Map for Adults (2015) Figure 11 Risk Map for Adults (2018) 

 

  

Figure 12 Risk Map for Children (2007) Figure 13 Risk Map for Children (2011) 



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Figure 14 Risk Map for Children (2015) Figure 15 Risk Map for Children (2018) 

  



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Figure 16 Risk Map for Infants (2007) Figure 17 Risk Map for Infants (2011) 

  

Figure 18 Risk Map for Infants (2015) Figure 19 Risk Map for Infants (2018) 

  



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The causes of higher risk values for small infants and chil-

dren than adults are that; the dose is normalized to the body 

weight which is small for children and infants in addition to 

that the immunity system of children and infants is still fee-

ble. Groundwater should not be used for drinking purposes 

to children and small infants all over the Gaza Governorates. 

In Gaza Governorates, it is recognized that the health risk 

value due to drinking of groundwater is acceptable for adults 

at a very limited number of wells, while it is un-acceptable 

at all for small infants. The risk value is expected to increase 

in the future since the concentrations of nitrate are likely to 

increase unless immediate actions and intervention plans are 

taken. 

Qrenawi in 2006 performed risk assessment of drinking 

groundwater in Northern Jordan. The study was supported 

by experimental measurements and the health risk values 

were acceptable for adults (0.269 < 1) while it was unac-

ceptable for small infants (1.037 > 1). The outcomes of these 

studies indicate that the problem of groundwater contamina-

tion is a regional problem and therefore efforts are to be 

united and cooperation should be implemented to the highest 

levels to find reliable solutions. 

VII. RISK MANAGEMENT 

Risk assessment alone gives a quantification of the risk 

(numeric value); however, the risk assessment is usually 

performed through risk management. Risk management is 

considered as a decision making process and is based on a 

quantitative value obtained from risk assessment coupled 

with judgment and experience (Watts, 1998). The primary 

function of risk management is to propose mitigation op-

tions that should minimize the risk and this can be accom-

plished by different actions, including: avoidance of the ac-

tion, lowering the amount of the action, correcting the im-

pacts by rehabilitation or restoration, compensating for the 

impact by providing substitute resources or environments 

(Petts and Eduljee, 1994). 

Risk management is commonly described as the process of 

evaluating alternative regulatory or other actions directed at 

reducing the health risk, and selecting among these alterna-

tives. The selected alternative should be applicable, for ex-

ample; reducing the risk values in Gaza Governorates' wells 

to the acceptable levels needs the reduction of nitrate to 50 

mg/l, 16 mg/l and 11 mg/l for adults, children and small in-

fants respectively which is not applicable at this time for the 

case of children and small infants due to the current local 

complicated situation. 

Health risk can be managed when dependency of groundwa-

ter for drinking purposes is reduced or eliminated. Residents 

of Gaza Governorates have the right to know that their 

sources of water are contaminated to unsafe levels. 

VIII. CONCLUSIONS AND RECOMMENDATIONS 

 The problem of groundwater in Gaza Governorates is a 
combined one since it is a quantity and a quality prob-

lem. 

 The health risk values for adults are acceptable in only 8 
municipal wells in Gaza Governorates which means that 

237 wells should not be used for some municipal uses 

and direct drinking without proper treatment. 

 The risk values for small infants is unacceptable in all 
municipal wells in Gaza Governorates indicating that 

none of them is suitable for drinking. 

 The main sources of nitrate in Gaza Governorates are: 
infiltration of untreated wastewater to the subsurface lay-

ers, leaching of chemical fertilizers and landfills' leach-

ate. 

 The problem of groundwater contamination is a regional 
problem that needs gathering efforts to find suitable and 

sustainable solutions. 

 Risk assessment is widely used in the last decades as a 
powerful decision support tool. 

 Immediate actions should be taken to minimize the risk 
associated with drinking groundwater to the acceptable 

levels in order to protect the public health of people who 

rely on this groundwater. 

 Looking for alternative water resources is to be put on 
the top of the agenda of responsible authorities to play 

their roles so that the public health is protected. 

 Community participation should be encouraged through 
education and awareness campaigns. Schools, universi-

ties and Non-Governmental Organizations (NGOs) have 

the right form to conduct such activities. 

 Residents of Gaza Governorates who depend on ground-
water in drinking have the right to know that their source 

of water is unsafe. 

 Further studies that consider the impact of nitrate in 
groundwater on the public health in Gaza Strip should be 

performed. These studies are to be supported by field 

surveys and reviewing medical reports to find a relation-

ship between nitrate concentration and accompanied dis-

eases.  

IX. ACKNOWLEDGEMENTS 

This work has been performed during the study at PhD Pro-

gram in Water Technology, Civil Engineering Department at 

The Islamic University of Gaza. Special thanks are directed 

to the Middle East Desalination Research Centre (MEDRC) 

for their fellowship and financial support, and for the Pales-

tinian Water Authority (PWA) for providing data. 

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Luay I. Qrenawi: Mr. Qrenawi is a PhD student at the joint 

Water Technology program between the Islamic University 

and Al Azhar University. He has the MSc In Environmental 

and Water Resources Engineering from the Jordan Universi-

ty of Science and Technology (2006), and the BSc in Civil 

Engineering from the Islamic University of Gaza (2002). 

Currently, he is a lecturer at the University College of Ap-

plied Sciences. He has more than 15 years in both the aca-

demic and professional fields related to Civil Engineering. 

He has a strong experience in the field of Environmental and 

Water Resources Engineering, with a focus on solid waste, 

wastewater and water sectors. He occupied the position of 

wastewater reuse expert at the Palestinian Water Authority. 

He also was the project coordinator at the Islamic University 

of Gaza on a project concerning the improvement of drink-

ing water quality in elementary schools using reverse osmo-

sis technique. He effectively worked on many local and re-

gional projects concerning solid waste management, solid 

waste reuse, recycling and recovery, as well as assessing the 

impacts and risks associated with landfilling practices. He 

participated in a comprehensive study about solid waste 

dumpsites in Gaza Strip. During many research and envi-

ronmentally oriented projects, he mastered the concepts and 

techniques of compost production from agricultural and mu-

nicipal solid wastes. Mr. Qrenawi publications are: 

1. Sludge Management in Water Treatment Plants: 

Literature Review, International Journal of Envi-

ronment and Waste Management, July, 2019 (Ac-

cepted for publication). 

2. Developing an Automated System for Irrigation, 

University College of Applied Sciences, 2014  

3. Solid Waste Landfills as a Source of Green Energy: 

Case Study of Al Akeeder Landfill. International 

Conference and Exhibition on Green Energy & 

Sustainability for Arid Regions & Mediterranean 

Countries, 2009 

4. Simulation of Leachate Production from an Arid 

Landfill Using HELP Model. Solid Waste Tech-

nology and Management, 2008 

5. Health Risk Assessment of Groundwater Contami-

nation in Gaza Strip, Jan., 2008 

6. Agricultural Wastewater Reuse Guidelines and 

Standards in Selected Countries, November, 2007 

7. Wastewater Situation in Gaza Governorates (Facts 

and Challenges), November, 2007 

8. Assessment of Solid Waste Dumpsites in Gaza 

Strip, March, 2007 (Arabic + English Versions) 

9. Monitoring Program Report of Rafah Beach, 2007 

10. Protection of Marine Environment, the Safe and 

Sustainable Utilization of Fish, October, 2006 

11. Pesticides and their Effects on the Environment and 

Public Health, August, 2006 

12. Utilization of Construction and Demolition Waste 

in Making Concrete Hollow Blocks, ICPCM - A 

New Era of Building, Egypt, 2003 

https://www.researchgate.net/profile/Luay_Qrena

wi2 

 

Reem Abu Shomar: Mrs. Abu Shomar is a PhD student at 

the joint Water Technology program between the Islamic 

University and Al Azhar University. She is a senior Public 

Health Specialist who hold master degree in public health 

from AL Quds University, Jerusalem.  She has professional 

experience in management of public health research projects 

implemented by multi-disciplinary teams and coordinated 

with multi-stakeholders.  Her working experience involved 

national and international organizations and she is currently 

working as a public health and environmental specialist at 

the program coordination unit hosted by the Palestinian Wa-

ter Authority.  She participated in the developing of national 

strategies and guidelines. She also participated in many local 

and international conferences related to public health, water, 

sanitation and hygiene.   

Research Gate: 

https://www.researchgate.net/profile/Reem_Abu_Shomar 

 

https://www.researchgate.net/profile/Luay_Qrenawi2
https://www.researchgate.net/profile/Luay_Qrenawi2
https://www.researchgate.net/profile/Reem_Abu_Shomar