Construction 
Economics and 
Building

Vol. 20, No. 2  
June 2020

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Citation: Opoku, A., and 
Akotia, J. 2020. Special 
issue: urban regeneration for 
sustainable development . 
Construction Economics and 
Building, 20:2, 1-5. http://
dx.doi.org/10.5130/AJCEB.
v20i2.7191

ISSN 2204-9029 | Published by 
UTS ePRESS | https://epress.
lib.uts.edu.au/journals/index.
php/AJCEB

GUEST EDITORIAL

Special issue: urban regeneration for 
sustainable development

Alex Opoku1* and Julius Akotia2
1 UCL Bartlett School of Construction & Project Management, University College London, UK
2 School of Architecture, Computing and Engineering, University of East London, UK

*Corresponding author: Alex Opoku, UCL Bartlett School of Construction & Project 
Management, University College London, UK; Email - alex.opoku@ucl.ac.uk

DOI: 10.5130/AJCEB.v20i2.7191
Article history: Received 5/9/2020; Revised 5/30/2020; Accepted 6/1/2020; Published 22/06/2020

Background
Cities are currently facing numerous challenges to cope with population growth and rural 
urban drift and these are having impact on quality of life and a range of opportunities that 
urban environments can offer its residents (Evans and Jones, 2009). These challenges can 
largely be put into threefold: social, economic, and environmental sustainability disparities. 
Cities are intricate entwined collections and centres of human interaction, creativity, 
knowledge, diversity, culture, commerce, and economic creativity (Elnokaly and Elseragy, 
2011). With more than half of humanity living in cities and the number of urban residents 
growing by nearly 73 million every year, it is estimated that urban areas account for 70 per 
cent of the world’s gross domestic product and has therefore generated economic growth and 
prosperity for many. It is expected that two-thirds of the world population will be living in 
urban areas (UN, 2018). 

In this regards, urban regeneration concept has become central and a key driver towards 
the sustainable development of cities (Akotia and Opoku, 2018). Urban regeneration practices 
provide the opportunity to transform the decline areas as well as the entire urban built 
environment. Roberts (2000, p.17) defines Urban Regeneration as the “comprehensive and 
integrated visions and actions, which lead to the resolution of urban problems and which seek 
to bring about a lasting improvement in the economic, physical, social and environmental 
conditions of an area that has been subject to change”.  Despite the developmental challenges 
brought about as a result of urbanisation, it also has the opportunity to drive sustainable 
development (Teferi and Newman, 2018). Sustainable urban regeneration should deliver city 

DECLARATION OF CONFLICTING INTEREST The author(s) declared no potential conflicts of interest with  
respect to the research, authorship, and/or publication of this article. FUNDING The author(s) received no  
financial support for the research, authorship, and/or publication of this article.

1

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level policies and processes that address the socio-economic challenges faced by the society 
with the aim of minimising the negative impacts on the environment. Urban regeneration 
is considered as means to regenerate and upgrade existing declined places towards the 
achievement of the sustainable development goals (SDGs). It is believed that a sustainable 
built environment could greatly impact on the realisation of SDG 2 (End Hunger), SDG 
3 (Good Health & Well-Being), SDG 4 (Quality education), SDG 6 (Clean Water & 
Sanitation), SDG 7 (Affordable & Clean Energy), SDG 8 (Decent Work & Economic 
Growth), SDG 9 (Industry, Innovation & Infrastructure), SDG 10 (Reduced Inequalities), 
SDG 11 (Sustainable Cities & Communities), SDG 13, (Climate Action) and SDG 15 
(Biodiversity) (Opoku, 2016; Opoku, 2019).

There is also recognition that, the cross-cutting nature of urban planning, design and 
development issues has an enormous impact on most of the sustainable development goals 
(UN, 2018). The recent Habitat III conference in Quito outlined the new urban planning 
and development agenda, which provides that, cities are made sustainable, shape to ensure 
liveability, provide homes and sustainable neighbourhoods. The agenda frames global policy 
for cities and urban regeneration for the next 20 years and beyond. Urbanization should 
be at the heart of the 2030 sustainable development agenda and SDG 11 in particular is 
aimed at making cities and human settlements inclusive, safe, resilient and sustainable (UN, 
2015). However Teferi and Newman (2018) believe that regenerating the urban slums in the 
developing world could greatly contributes to the realisation of many of the SDGs including 
SDG 1 (End poverty), SDG 6 (Clean Water & Sanitation), SDG 7 (Affordable & Clean 
Energy) and SDG 11 (Sustainable Cities & Communities). Urban regeneration is an essential 
activity impacting on the agenda towards a more sustainable society (Lombardi et al., 2010). 
Sustainable development goal 11, target 11.3 sets a global ambition to “enhance inclusive and 
sustainable urbanization and build capacity for participatory, integrated and sustainable human 
settlement planning and management by 2030” (UN, 2016, p.14).

This Special Issue
This special issue presents high-quality research papers that address sustainability issues of 
urban regeneration towards the delivery of Sustainable Development Goals (SDGs) for cities. 
The special issue is based on contributions from authors’ response to an open call for papers; 
the papers went through a very rigorous double-blind review process resulting in nine (9) 
accepted papers with five (5) papers addressing regeneration issues in the global south while 
the remaining four (4) papers are based on cases from the global north.

De Kock and Carta begin this special issue by examining the confused meaning of modern-
day regeneration projects. The paper presents a theoretical framework that helps identify visual 
sustainability in urban projects and evaluates its relevance for the use, design and making of 
public space. It is aimed at showing how the process of urban regeneration is far more nuanced 
and sophisticated than much of today’s building industry allows for. Visual sustainability 
represents ‘the technology before the technology’ and future research must recognise how 
human needs, not technology, provide the meaning into ‘how’ we may create a successful, 
smart, and sustainable urban.

Sørensen, Rasmussen, Øien and Frandsen adopt interview approach in clarifying how 
different actors employ parameters of sustainability in the building design and what enables 
the holistic perspective of the interrelating social, economic, and environmental parameters. 
The study shows that decision support tools are used late in the design process and commonly 

Opoku and Akotia

Construction Economics and Building,  Vol. 20, No. 2, June 20202



focused on single parameters of sustainability. The analysis shows how practitioners of the 
planning and early design phases operate at general levels of geometrical clusters and volumes 
but must continuously evaluate each project in perspective of the specifications of end-users 
and the public to ensure holistic sustainability.

However, Oke, Aghimien, Akinradewo and Aigbavboa examine the various factors 
influencing the ability of cities to develop resilience through smart city drivers through a 
survey of construction professionals involved in the design, planning, development and general 
management of cities and infrastructure. The study grouped the factors influencing resilience 
into five including climate change, education, food security, public safety, and threat to disease, 
in order of their importance. Findings revealed that the most important of these factors are 
development of literacy and technical skills of citizens, regeneration of agricultural land and 
increased localised food production. The paper also examined the effects of these factors on six 
smart city drivers and found out that smart economy has the most influence on the resilience 
of a city. 

Das applied Systems Analysis (ASA) linked System Dynamics (SD) conceptual models 
based on the interlinkage and causal feedback relationships among various factors developed, 
which could assist in offering perspectives that would enable eliciting of policy interventions to 
develop smart cities. Using the context of the city of Bloemfontein, South Africa and drawing 
on the perceptions of stakeholders, the paper offers a perspective on such a transformation by 
first assessing the performance of various factors and attributes that influence three important 
aspects of a smart city: economy, mobility and governance system. It then recorded the 
viewpoints of stakeholders about how these aspects can contribute to the development of a 
smart city.

On the other hand, Akotia, Manu, Opoku and Sackey adopt qualitative research approach 
using a semi-structured interview to provide an overview of sustainability benefits within the 
context of the sustainable regeneration projects in the UK from a study that examines the 
roles and sustainability drivers of construction industry practitioners’ towards the promotion of 
sustainability on their regeneration projects. The findings revealed that out of the eight socio-
economic sustainability drivers presented to practitioners, enhancement of reputation was the 
most important ‘socio-economic’ sustainability driver while the least important driver was 
legislative and legal requirement. The findings further revealed that majority of practitioners/
organisations were promoting the socio-economic sustainability drivers that meet corporate 
business objectives.

Oke, Aghimien, Aigbavboa, and Akinradewo appraise the Drivers of Smart City 
Development in South Africa. Using the drivers (smart environment, smart economy, smart 
people, smart governance, smart mobility, and smart living) the study adopts multiple-choice 
questionnaire. Smart environment was found to be a major driver of a smart city while smart 
people, smart governance and smart living are also key to the achievement of the goals and 
objectives of the concept. The developed key smart city drivers are a workable, adaptable, and 
efficient city design mechanism and it will be useful for city planners, statutory agencies as well 
other stakeholders in the development of smart cities.

Peel, Ahmed and Saboor investigate the barriers and enablers to energy efficiency retrofitting 
in social housing in London, UK based on the perception of experts employed in construction 
companies. The paper group the barriers and enablers into seven categories that include: 
financial matters, technical, IT, government policy and regulation, social factors (including 
awareness of the energy efficiency agenda), quality of workmanship and disruption to residents 

Special issue: urban regeneration for sustainable development 

Construction Economics and Building,  Vol. 20, No. 2, June 20203



using literature review, interviews and surveys with key stakeholders within the housing sector 
and draws recommendations to enable effective and efficient retrofitting for social housing 
projects.

Again, Boyle and Michell identify the key ingredients required to drive collaborative 
urban regeneration in marginalised communities in the global south using case study 
methodology which included a series of interviews and community engagement workshops. 
The study established that in the absence of effective leadership and service delivery from 
local authorities the community feel disenfranchised as their community is not seen as an 
immediate priority. It is concluded that fundamental ingredients for effective collaborative 
urban regeneration is trust between the key stakeholders, a diverse assortment of expertise and 
skills, and an in-depth engagement process. Without these factors urban regeneration is likely 
to only entrench the complex urban issues it seeks to reconcile.

Finally, Adinyira, Agyekum, Baiden, Ebohon and Ampratwum present a case study of the 
regeneration redevelopment of the largest open-air market in West Africa (Kumasi Central 
Market-Ghana) and the role of stakeholder participation in the entire regeneration. The 
determination of the most important stakeholders during the regeneration of the market is 
followed by a comparison of the regeneration process regeneration with the literature on urban 
regeneration, sustainable development, participation, and project management. Identification 
of all-important stakeholders by the consideration of their attributes of power, legitimacy 
and urgency and distrustfully engaging all stakeholders is vital to the success of any urban 
regeneration project.

Reference
Akotia, J. and Opoku, A., 2018. Sustainable regeneration project delivery in UK: A qualitative Analysis 
of practitioners’ engagement, Journal of Facilities Management, 16(1), pp.87-100. https://doi.org/10.1108/
jfm-05-2017-0024

Elnokaly, A. and Elseragy, A., 2011. Sustainable urban regeneration of historic city centres: lessons learnt. 
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Evans, J. and Jones, P., 2009. Rethinking Sustainable Urban Regeneration: Ambiguity, Creativity, and 
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