Intellectual capital
and sustainability practices

of manufacturing firms in Uganda
Kassim Alinda, Sulait Tumwine and Twaha Kigongo Kaawaase

Department of Accounting, Makerere University Business School, Kampala, Uganda

St�ale Navrud
School of Economics and Business, Norwegian University of Life Sciences,

As, Norway, and

Arthur Sserwanga and Irene Nalukenge
Makerere University Business School, Kampala, Uganda

Abstract

Purpose – The primary objective of this study is to investigate the association between the dimensions of
intellectual capital (IC) and sustainability practices (SP) within the context of manufacturingmedium and large
(ML) firms inUganda. The study aims to shed light onwhether and howdifferent dimensions of IC contribute to
the adoption and implementation of SP by these firms.
Design/methodology/approach – This study utilized a cross-sectional and quantitative approach,
collecting data through a questionnaire survey from a sample of manufacturing ML firms. The collected data
underwent analysis to identify patterns and relationships using the SmartPLS structural equation modeling
(SEM) technique.
Findings –The findings demonstrated that the three categories of IC (human, structural and relational capital)
influence the SP of ML manufacturing enterprises in Uganda. This suggests that IC is a critical component
of SP.
Practical implications –Manufacturing enterprises should use their IC to create strategies for sustainable
solutions, such as creating new, ecologically and socially responsible products and services and improving
current ones to lessen their environmental effect.
Originality/value – This research advances knowledge of SP by revealing if all aspects of IC are significant
for the SP of manufacturing enterprises in Uganda.

Keywords Sustainability practices, Intellectual capital, Human capital, Structural capital, Relational capital,

Manufacturing firms, Uganda

Paper type Research paper

1. Introduction
In this study, we use data from a least-developed country where there are few empirical
studies to examine whether all the dimensions of intellectual capital (IC) matter for the
sustainability practices (SP) of manufacturing medium and large (ML) enterprises.
Considering the importance of environmental conservation, IC is a significant factor
needed for manufacturing (ML) to implement sustainable strategies (Bananuka, Tauringana,
& Tumwebaze, 2023). As a result, manufacturing companies with higher IC have better odds

IJSBI
1,1

18

© Kassim Alinda, Sulait Tumwine, Twaha Kigongo Kaawaase, St�ale Navrud, Arthur Sserwanga and
Irene Nalukenge. Published in IIMBG Journal of Sustainable Business and Innovation. Published by
Emerald Publishing Limited. This article is published under the Creative Commons Attribution (CC BY
4.0) licence. Anyone may reproduce, distribute, translate and create derivative works of this article (for
both commercial and non-commercial purposes), subject to full attribution to the original publication
and authors. The full terms of this licence may be seen at http://creativecommons.org/licences/by/4.0/
legalcode

The current issue and full text archive of this journal is available on Emerald Insight at:

https://www.emerald.com/insight/2753-4022.htm

Received 31 March 2023
Revised 20 June 2023
Accepted 17 July 2023

IIMBG Journal of Sustainable
Business and Innovation
Vol. 1 No. 1, 2023
pp. 18-38
Emerald Publishing Limited
2753-4022
DOI 10.1108/IJSBI-03-2023-0016

http://creativecommons.org/licences/by/4.0/legalcode
http://creativecommons.org/licences/by/4.0/legalcode
https://doi.org/10.1108/IJSBI-03-2023-0016


of engaging in actions that help the environment overall and the present generation without
compromising the capacity of future generations to satisfy their demands (Ndagire &
Nakabuye, 2021). Furthermore, during the last decade, sustainability literature has risen to
prominence due to the increasing importance that corporations place on issues of
environmental sustainability, social responsibility and economic growth (Kraus, Ribeiro-
Soriano, Sch€ussler, & Brem, 2017). To ensure the well-being of present and future
generations, researchers (Geissdoerfer, Savaget, Bocken, & Hultink, 2017) emphasized the
importance of sustainability in achieving a balanced integration of the triple-bottom line
(TBL), which combines economic prosperity, social inclusion and environmental resilience
with their interdependence.

In response to the adverse environmental, societal and economic impacts associated
with manufacturing firms, a range of SP has emerged. These practices aim to address
these problems by putting various principles into practice, such as design innovation
that follows R’s principles (Earley, 2017), circularity (Lieder & Rashid, 2016; Moorhouse
& Moorhouse, 2017), cradle-to-cradle design (Braungart, McDonough, & Bollinger,
2007), closed-loop design (Ara, Leen, & Hassan, 2019) and eco-design (Kozlowski, Searcy,
& Bardecki, 2018). Scholarly literature by Jia and Jiang (2018) and Dos Santos and
Campos (2020) highlights the potential benefits of implementing SP, such as the
conservation of natural resources, reduction in waste generation and preservation of
operational quality. Moreover, studies by Li, Liu, and Huan (2019) and Desore and Narula
(2018) suggest that these practices can confer a competitive advantage and help address
resource scarcity.

To that end, several countries are rethinking their sustainable-development-goal (SDG)
strategies because their populations are growing, resources are running out, the
environment is getting worse and people are generating more waste (Furstenau, de
Melo, Varela, & Ferreira, 2020). According to Can and Alatas (2017), manufacturers should
prioritize SDG 12 (which deals with both sustainable consumption and production). The
SDG 12 agenda focuses on reducing how people use and produce things, which has an
effect on the environment. This has put manufacturers under the scrutiny of
environmentalists, carbon footprint researchers, and energy efficiency researchers. The
manufacturing sector is a major cause of sustainability problems, contributing to the
present environmental catastrophe on a worldwide scale (Tang, Liu, Wang, Zhu, &Wang,
2018; Schrettle, Hinz, Scherrer-Rathje, & Friedli, 2014). According to the IEA (2015),
manufacturing businesses produced 38% of the world’s carbon dioxide emissions and
used 13% of the world’s energy. While there has been a worldwide push to encourage
sustainability initiatives, many Ugandan firms are still using methods that are harmful to
both the environment and society (Baltacioglu, Gungor, Kaplan, & Simsek, 2017). Despite
the fact that the country is already susceptible to climate change, this issue is of the utmost
importance because unsustainable manufacturing practices are likely to make it worse
(Hassan, Shukla, & Jug, 2019; Namanya & Luukkanen, 2020). Because of this, it is very
important to look at the state of SP in Uganda’s manufacturing sector and find ways to
improve output in a sustainable way.

The United Nations Industrial Development Organization (UNIDO) (2018) reported that,
even though SP could be good for the economy and the environment, only a small number of
manufacturing businesses in Uganda have embraced it. These problems should not be
ignored because manufacturing businesses in Uganda make up more than 10% of the
country’s gross domestic product (GDP) and employ more than 500,000 people (World Bank,
2022). Industrial emissions andwaste threaten the quality of the air, water and soil all over the
country. This is another big reason why the environment is getting worse (NEMA, 2019).
Without enough resources like IC, Uganda’s industrial sector will not use SP as much as
it could.

Intellectual
capital of

manufacturing
firms

19



In-depth research on IC has already been extensively published in the literature. Al-
Khoury et al. (2022) conducted a study on the history and trends of IC and found that a
significant majority of the articles, approximately 89%, originated from developed countries.
This disproportionate focus on developed countries has led to a research gap in
understanding IC in developing countries, particularly in Africa and other regions.
Consequently, there is a lack of comprehensive studies and investigations on IC in these
under-researched areas.

Moreover, Alam, Rana, and Lodhi (2020) noted the significant role of IC in influencing the
adoption of sustainability strategies in manufacturing enterprises. Their findings suggest
that businesses that actively engage in developing and managing IC are more likely to
acquire the necessary expertise and knowledge to effectively implement SP. Similarly,
Jayashree, Venkatesh, and Arunachalam (2021) demonstrated the influence of technological
advancements and IC on SP in manufacturing enterprises. In contrast, Yusoff, Jusoh, Mohd
Noor, and Harun (2019) highlighted the importance of structural and relational capital, as
opposed to human capital, in ensuring cleaner production and supporting economic and
environmental sustainability. This finding contradicts the analysis byMassaro, Dumay, and
Garlatti (2018), which argues that all three aspects of IC impact SP in manufacturing.

Additionally, Bananuka et al. (2023) conducted a separate investigation and found a
positive influence of human capital and relational capital on sustainability reporting
practices within the financial institution sector in Uganda. However, they did not observe a
significant impact of the structural capital element on these practices. It is important to
acknowledge that their study focused specifically on sustainability reporting practices in the
financial sector, limiting the generalizability of their findings to other sectors of the economy.
Furthermore, Bananuka et al.’s (2023) study primarily examined the disclosure and
communication aspects of sustainability efforts, while the present study aims to explore SP
as a broader concept encompassing various actions and initiatives (Nasreen, Baker, &
Rezania, 2023). Therefore, caution should be exercised when extrapolating their results to
industries beyond the financial sector, as the specific contextual factors and characteristics of
financial institutions may influence the relevance and applicability of their findings to other
sub-sectors.

It is crucial to recognize that SP encompasses a wide range of actions and initiatives
undertaken by organizations to minimize their negative impacts on the environment, society
and economy while promoting long-term sustainable development (Nave et al., 2021). Despite
the existing literature suggesting the importance of IC in supporting SP, there is a lack of
empirical studies specifically focusing on manufacturing firms in Uganda. This research gap
highlights the need for further investigations in this specific context.

The purpose of this research is to ascertain if all dimensions of IC are significant for the SP
of manufacturing ML firms in Uganda. The results give insights into manufacturing
businesses SP, which might stimulate ML manufacturing enterprises toward the
implementation efforts of SP. Moreover, the third National Development Plan has the
theme “Sustainable Industrialization for Inclusive Growth, Employment, and Wealth
Creation” (National Planning Authority Uganda (NPA), 2020). In order to achieve this theme,
it is inevitable to use SP. Moreover, SDG 9 focuses on fostering long-term economic growth
and development via sustainable industrialization and infrastructure, including the
deployment of ecologically sound technologies and practices by manufacturing
businesses. This study helps to improve knowledge of both SDG 9 and SDG 12
(sustainable consumption and production). In addition, the African Agenda 2063 is a
strategic framework for Africa’s socioeconomic development over the next 50 years. The
African Union (AU) (2015) approved it in January with the goal of promoting equitable
growth, sustainable development and regional integration across the continent. To that end,
this study may be beneficial towards the attainment of this agenda.

IJSBI
1,1

20



The rest of the paper is organized as follows: Section 2 reviews the literature and develops
hypotheses. Section 3 presents the research methodology. Section 4 presents the results, and
the discussion of the results follows in Section 5. The final section delves into conclusions and
areas for further research.

2. Literature review and hypothesis development
2.1 Theoretical underpinning
SPs in literature derive from IC as a firm’s strategic resource. The latter may arise via human
capital, structural capital and relational capital to motivate manufacturing enterprises to
undertake sustainability efforts (Sunday, 2017). Corresponding with this knowledge gap, the
major goal of this research is to explore SPs in Uganda via the resource-based theory (RBT)
theoretical lens and to investigate the link between IC and SP quantitatively. The appropriate
examination of this link necessitates the use of resource-based theory, whichwill be described
further below.

This study is based on the RBT proposed by Barney (1991). According to Barney (1991),
firms with valuable, rare, unique and nonsubstitutable internal resources and capabilities
have a competitive edge over those without. The RBT emphasizes the value of assets and
competencies in attaining a competitive edge. Wernerfelt (1984) defined resources as
anything that could be considered a firm’s strengths and weaknesses. According to Barney
(1991), the concept includes all resources, organizational capabilities, procedures, knowledge
and information within the control of the corporation that have the potential to increase its
effectiveness and efficiency. In this study, it is anticipated that firms with internal resources
including human capital, structural capital and relational capital would implement SP.
A company’s potential to create value will likely be constrained if it has a limited pool of
general intellectual and knowledge-related resources.

2.2 Intellectual capital and sustainability practices
In this section, we present a complete assessment of the literature on the three facets of IC
(human capital, structural capital and relational capital) and their relationship to SP, after
which hypotheses are generated.

2.2.1 Human capital and sustainability practices. The term “human capital” in business
refers to the body of information that employees have accumulated over the course of their
careers, including knowledge, skills, attitudes and experience (Cabrita & Bontis, 2008).
Studies suggest that human capital plays a significant role in the adoption and
implementation of SP. Corredor and Gomez (2019) found that firms with higher levels of
human capital aremore likely to adopt SP, such aswaste reduction, energy efficiency and eco-
design. Sunday (2017) also revealed a substantial association between human capital and
both economic and environmental social determinants. Additionally, studies (Akhtar,
Waseem, & Hussain, 2015; Arshad et al., 2016; Widodo & Shahab, 2015) claimed that higher
levels of human capital boosted sustained competitive advantage. In addition, Malik, Cao,
Mughal, Kundi, Mughal, & Ramayah (2020) found a positive effect of human capital on a
firm’s sustainability. However, Yusoff et al. (2019) revealed that green human capital has
minimal influence on corporate sustainability. The following hypothesis is thus formulated:

H1. There is a significant relationship between human capital and SP.

2.2.2 Structural capital and sustainability practices.Arshad et al. (2016) argued that a firmwith
a high level of structural capital has a strong organizational culture and staff who are willing to
share knowledge and incorporate it into formal processes and structures. Akhtar et al. (2015)
claim that structural capital is crucial for SP to take place. In addition, Yusoff et al. (2019), who

Intellectual
capital of

manufacturing
firms

21



looked at whether all three parts of ICmatter for sustainability, found evidence of a positive and
significant effect of green structural capital on corporate sustainability. Relatedly, Dal Mas
(2019) discovered a strong correlation between structural capital and each of the three aspects of
sustainability in his research on the link between IC and sustainability based on an examination
of practitioner thought. In their empirical study of corporate sustainability, Malik, Khan, et al.
(2020) found that structural capital and sustainability have a strong and significant link. In
contrast, Jarrar andAbu-Zaid (2016), in a study of 72 Jordanian companies, found that structural
capital did not have a significant impact on corporate social responsibility (CSR) practices.
Herein, the following hypothesis is formulated:

H2. There is a significant relationship between structural capital and SP.

2.2.3 Relational capital and sustainability practices. The link between relational capital and
SPs is important because relational capital can help firms adopt SPs by giving them the
resources, skills and relationships they need. Strong ties with suppliers, for example, may
assist manufacturing enterprises in sourcing sustainable materials and reducing their carbon
footprint, while good relationships with consumers can lead to increased demand for
environmentally friendly products and services.

Several studies have explored the relationship between relational capital and SP in the
manufacturing sector. A study by Castka, G€olgeci, and Piterou (2021) found that companies
that prioritize SP tend to have higher levels of relational capital, which enables them to build
stronger relationships with stakeholders and gain competitive advantages. Similarly, a study
by Santi, Figueiredo, Formentini, and Oliva (2021) found that relational capital plays a key
role in promoting sustainable supply chain management practices in manufacturing firms.
However, it is important to note that the relationship between relational capital and SP is not
always straightforward. A study by Han, Shi, and Wang (2020) found that while relational
capital can facilitate the adoption of SP, it can also inhibit innovation and change if companies
become too reliant on established relationships and fail to seek out new partnerships and
opportunities. Overall, the relationship between relational capital and SP is complex and
multifaceted. Manufacturing firms that prioritize both concepts and work to build strong
relationships with stakeholders are likely to achieve long-term success and competitive
advantages in today’s rapidly changing business landscape.

Relational capital includes a company’s intangible assets, like its relationships with
customers, suppliers and the global business environment, as well as its stakeholders’ sense of
responsibility, trust and identity (Cucculelli, Bettinelli, & Rialti, 2019; Daspit & Long, 2014). Sun,
Zhang, Li, and Xie (2018) found that relational capital makes people more aware of the
environment, including how to deal with waste, save resources and understand climate change.
Researchers (Tortoriello, Reagans, &McEvily, 2011; Yu&Huo, 2019) have shown that relational
capital is very important for small andmedium-sized enterprises (SMEs) to share environmental
knowledge resources. This information transfer may help organizations address unsustainable
practices. DalMas (2019) found via textmining of 1651 practitioner postings in one of the leading
sustainability sources that relational capital is essential to SP realization. This shows how trust
and collaborationmay improve information sharing and organizational activities in a company’s
membership and employee connections. According to previous research, relational capital boosts
SPs (Yusoff et al., 2019). Herein, the following hypothesis is formulated:

H3. There is a significant relationship between Relational capital and SP.

2.2.4 Intellectual capital and sustainability practices. Organizations that engage in human
capital activities, such as staff training and development, are more likely to implement SP
initiatives like energy efficiency, waste reduction and eco-design, according to research by
Farneti, Battisti, and Mora (2021). Numerous studies have shown a correlation between IC
and SP. For instance, research by Kianto, Ritala, Spender, and Vanhala (2019) found that

IJSBI
1,1

22



businesses are more likely to use SP if they invest in IC. According to the authors, businesses
that invest in the education and training of their personnel are better able to provide creative
and long-lasting solutions. In a similar vein, Lee and Kim’s (2018) research discovered that
businesses with higher levels of IC are more likely to adopt SP, such as lowering greenhouse
gas emissions, incorporating renewable energy sources and enhancing waste management.
While several studies have shown a link between IC and sustainability strategies, more recent
research reveals that this connectionmay bemore nuanced than first believed. For instance, a
study by Taticchi, Garengo, Nudurupati, Tonelli, and Pasqualino (2018) discovered that
organizational culture may act as a moderator in the relationship between IC and SP.
Particularly, the authors discovered that businesses with an innovative culture are more
likely to adopt SP. In addition, research by Gallardo-V�azquez, Su�arez-Barraza, and Ram�ırez-
Portilla (2020) discovered that the environment in which businesses operate may have an
impact on the link between IC and SP. In particular, the researchers noted that organizations
in developing countries can encounter distinct difficulties in adopting SP compared to
companies in developed economies, such as a lack of resources and access to technology. We
thus hypothesize that:

H4. There is a significant positive relationship between IC and SP.

2.2.5 Summary of literature review. The existing body of literature on sustainability
encompasses various aspects, although the predominant focus has been on specific areas such
as sustainability reporting practices (Van der Zahn, 2023; Bananuka et al., 2023), sustainability
performance disclosures (Bananuka, Nkundabanyanga, Kaawaase, Mindra, & Kayongo, 2022),
environmental practices in the wine industry (Bandinelli, Acuti, Fani, Bindi, & Aiello, 2020),
environmental SP of multinational mining companies (Amoah & Eweje, 2022), sustainability
implementation in the mining industry (Amoah & Eweje, 2023), business sustainability (Li,
Bhutto,Waris,&Hu, 2023), stakeholder pressures andSP inmanufacturing (Bello-Pintado et al.,
2023), the impact of digital technologies and SP on circular supply chain management
(Romagnoli, Tarabu, Maleki Vishkaei, & De Giovanni, 2023), the operationalization of
sustainable business models (Bonfanti, Mion, Brunetti, & Vargas-S�anchez, 2023), IC and
sustainable development (Alvino, Di Vaio, Hassan, & Palladino, 2021), SP among
manufacturing firms in Uganda (Alinda et al., 2022). However, it is noteworthy that studies
specifically focusing on the IC and SP of manufacturing firms are relatively scarce in the
literature. This highlights the need for more research in this area to gain a comprehensive
understanding of the relationship between IC and SP in the manufacturing sector.

3. Methodology
3.1 Research design, population and sample
This research used a positivist and objective epistemology. For this investigation, we used a
quantitative approach. The positivist research paradigm is theory-driven, with the conviction
that reality is presented objectively andmay operate as a foundation for directing the behavior
of enterprises, their staff and their clientele. The questionnaire used in this study, which was
constructed based on a thorough review of the literature, largely includedLikert-type questions
with a 6-point scale. In order to measure SP, this research utilized a scale developed by
Høgevold et al. (2015). The reliability of the scale was assessed using Cronbach’s alpha, with
scores for each component ranging from 0.66 to 0.68. These values exceed the minimum
threshold of 0.6, indicating satisfactory internal consistency for the measurement of SP.

According to the Uganda Bureau of Statistics (Uganda Bureau of Statistics (UBOS), 2018), the
manufacturing subsector in Uganda encompasses a large number of small firms, approximately
3,859, with uncertain geographic distribution and limited contact information. Given this context,
the present study focused specifically on the central region of Uganda, where 638 ML

Intellectual
capital of

manufacturing
firms

23



manufacturing firms are situated. Employing Krejcie and Morgan’s (1970) selection table, a
sample size of 229 members from the Uganda Manufacturers’ Association (UMA) would have
been drawn from this target population. However, we collected data from a purposive sample of
102 firms, yielding a response rate of 44.5%. This response rate exceeded the minimum
requirement of 30 businesses necessary for conducting reliable inferential statistics. The survey
instruments were physically distributed and the gathered data from the 102 firms were
considered appropriate for analysis in the study. The choice to focus on the central region of
Uganda was motivated by its notable economic activity, as reported by Uganda Bureau of
Statistics (UBOS) (2018). Furthermore, the central region was identified by the National
Environment Management Authority (NEMA, 2019) as the area where the most significant
environmental damage occurs. For the study, key personnel such as the Chief Financial Officer,
Production Manager, Operations Manager, Environmental Manager and Human Resource
Managerwere purposefully selected as respondents and the data collectedwas aggregated at the
firm level. These individuals were specifically chosen due to their presumed knowledge and
expertise regarding sustainability issues within their respective organizational roles.

3.2 Demographic characteristics
Table 1 indicates that the majority of respondents (59.2%) in ML manufacturing enterprises
in Uganda are male. This finding suggests that there is a higher representation of men in

Gender Frequency (%) Cumulative (%)

Male 189 59.2 59.2
Female 130 40.8 100.0

Age Group
Less than 35 years 105 32.9 32.9
36–45 years 162 50.8 83.7
46–55 years 45 14.1 97.8
above 55 years 7 2.2 100.0

Highest education level
Diploma 53 16.6 16.6
Bachelor’s degree 178 55.8 72.4
Master’s degree 81 25.4 97.8
PhD 5 1.6 99.4
Others 2 0.6 100.0

Length of service in this firm
Less than 5 years 112 35.1 35.1
5–10 years 149 46.7 81.8
11–15 years 39 12.2 94.0
16 years and above 19 6.0 100.0

Position in the organization
Environmental manager 21 6.6 6.6
Operations manager 51 16.0 22.6
Human Resource manager 144 45.1 67.7
Production manager 54 16.9 84.6
Chief finance officer 49 15.4 100.0

Note(s): Table 1 provides an overview of the respondents’ characteristics, including gender, age group,
highest level of education, length of service in the firm and position held by each respondent. The table presents
demographic information that helps contextualize the sample population and provides insights into the
diversity and composition of the participants in the study
Source(s): Primary data

Table 1.
Respondents’
characteristics, total
n 5 319 respondents

IJSBI
1,1

24



these industries compared to women. The majority of respondents were between the ages of
36 and 45, indicating that persons who are mature, energetic and active enough to take on
onerous duties in managing the operations of manufacturing organizations dominate. The
education levels of the respondents show that the most have a bachelor’s degree (55.7%) and
the least have a PhD and other categories not defined (1.6% and 0.6%, respectively).
Concerning their length of service in the firm, 46.7% have experience of 5-10 years and 6%
have experience of 16 years or more in a manufacturing firm setting, implying that most
managers have sufficient experience to integrate sustainability initiatives.

3.3 Questionnaire and variables measurement
We used a self-administered questionnaire with closed-ended items anchored on a six-point
Likert scale to measure the extent to which the respondents agreed or disagreed with the
items put forward to measure the study variables. McBride and Adamson’s (2015) research
supports a six-point Likert scale. The research examined the reliability and validity of a five-
and six-point Likert scale used to gauge attitudes about education technology. The six-point
Likert scale was more reliable and valid than the five-point scale because it offered more
answers and eliminated neutral or midway responses. A questionnaire was used because we
targeted a large sample and aimed at obtaining the mean ratings of the questionnaire items.
We reviewed existing literature on IC and SP in order to develop the questionnaire. IC was
operationalized in terms of human capital, structural capital and relational capital (Kianto,
S�aenz, & Aramburu, 2017; Bontis, 1998). On the other hand, SP were operationalized in terms
of environmental, social and economic SP (Høgevold et al., 2015; Chow & Chen, 2012; Yacob,
Zhou, & Shi, 2019). In this study, Figure 1 depicts the authors’ conceptualization of the study
variables and their interrelationships as derived from the existing literature as well as the
direction of the hypotheses formulated.

H1

H2

H3

H4

Intellectual capital
Human capital

Structural capital

Relational Capital

Sustainability 
Practices

Source(s): Authors conceptualization

Note(s): Figure 1 depict the study model, illustrating the interrelationships between the
dimensions of intellectual capital (including human capital, structural capital, and
relational capital) and sustainability practices. The figure provides a visual representation
of the conceptual framework guiding the research, highlighting the hypothesized
connections between these key variables. The arrows in the figure indicate the direction
of the relationships, suggesting how the dimensions of intellectual capital influence
sustainability practices. The model serves as a theoretical foundation for understanding
the complex dynamics and mechanisms underlying the relationship between intellectual
capital and sustainability practices. By visualizing these interconnections, Figure 1 offer
a comprehensive overview of the proposed conceptual framework, guiding further
analysis and interpretation of the study findings Figure 1.

Study model

Intellectual
capital of

manufacturing
firms

25



3.4 Validity and reliability
The idea of validity relates to how closely a particular statistic represents the main concept.
The researchers asked a group of sustainability specialists (professors, government officials
and academics) to assess the survey’s questions on a Likert scale of 1 (strongly disagree) to 6
(strongly agree). The estimated content validity indices (CVIs) for the experts’ responses for
all variables were more than the cutoff value of 0.7 (Field, 2009). All estimated CVIs for
research variables supported the survey’s dependability. In contrast, in this study, the
Cronbach’s alpha coefficient was employed to assess the instrument’s reliability. Cronbach’s
alpha was more than 0.7, above Nunnally’s (1978) suggested criterion, implying that the
instrument showed internal consistency (see Table 2).

3.5 Data analysis
The collected data was input into SmartPLS Structural EquationModeling (SEM)Version 3 for
assembly, sorting, editing, coding, capturing and analysis. Before analyzing the data, it was
cleaned in Statistical Software for the Social Sciences (SPSS) 23. SmartPLS version 3 software
was utilized for analyzing the cleaned data. The valid sample size of 102 manufacturing firms
made SmartPLS a suitable analytic tool. According to Fornell and Bookstein (1982), neither the
measurement scale nor the population size is assumed in partial least squares (PLS) path
modeling. Both the measurement and structural models should be addressed when analyzing
and interpreting PLS-SEM data, with the structural model evaluating the relationship between
the explanatory and criterion latent variables (Henseler, Ringle, & Sarstedt, 2014).

4. Results
4.1 The measurement models
Construct validity was analyzed from two different angles: convergent validity and
discriminant validity (Neuman, 2007). The concept of convergent validity describes the
degree to which a measurement instrument closely tracks the target construct. We used the
average variance extracted (AVE) to demonstrate convergence. Table 2 displays the results,
which show that all the calculated AVE values are larger than the acceptable threshold of 0.5,
indicating the presence of convergent validity (Henseler et al., 2014).

Composite
reliability

Average variance extracted
(AVE)

Variance inflation
factor

Intellectual capital
Human capital 0.829 0.550 1.439
Relational capital 0.857 0.547 1.407
Structural capital 0.829 0.617 1.324

Sustainability practices
Economic sustainability
practices

0.825 0.703 1.161

Environmental sustainability
practices

0.860 0.606 1.550

Social sustainability practices 0.768 0.531 1.466

Note(s):Table 2 presents the results of the reliability and validity analysis of the research instrument used in
the study. The table provides an assessment of the instrument’s reliability, as measured by composite
reliability, for the dimensions of human capital, structural capital, relational capital and sustainability
practices. The findings demonstrate the soundness of the research instrument, ensuring the reliability and
validity of the collected data for further analysis
Source(s): Primary data

Table 2.
Reliability and validity
of the research
instrument

IJSBI
1,1

26



On the other hand, a measure’s discriminant validity is how well it does not measure (or
discriminates against) other things it was not made to measure. It is common to look at both
convergent and discriminant validity for a group of related constructs at the same time. Fornell
and Larcker (1981) suggested that the outer loadings of an indicator on a construct must be
higher than the indicator’s highest correlation with any other construct in order to show that it is
discriminant. Since this requirementwasmet, discriminant validitywas established (seeTable 3).

We also tested the internal consistency of the scales used to assess the variables and
validated the instrument’s reliability using the SmartPLS Cronbach Alpha coefficient and
composite reliability (Cronbach, 1951). Table 2 displays the results of the reliability analysis,
showing that the instrument was consistent and acceptable (Fornell & Larcker, 1981;
Nunnally, 1978) because all of the alpha coefficients and composite reliability values for
individual test values were greater than the recommended threshold of 0.7. Yet, composite
reliability was favored here since it considers various outer loadings of the indicator variables
(Hair, Hult, Ringle, & Sarstedt, 2017).

4.2 Structural model
4.2.1 Test of hypothesis. In this study, we looked at the relationships between variables by
using path coefficients and t statistics (Wong, 2013). This is called a “bootstrapping”method.
The importance of loadings and path coefficients was examined by bootstrapping. The
results of these tests of three hypotheses are shown in Figure 2, Tables 4 and 5.

Figure 2 shows that all threemeasures of IC (structural capital, relational capital and human
capital) have statistically significant estimates,which shows that they all play an important role
in explaining IC. There is a significant relationship between structural capital and IC (β5 0.448,
p < 0.05), relational capital and IC (β 5 0.352, p < 0.05) and human capital and IC (β 5 0.314,
p < 0.05). There are three components to this construct that together explain 76.7% of the
variation in IC. Table 4 provides an additional illustration of estimated prediction values for IC.

According to Table 4, structural capital accounts for the greatest share of unexplained
variation in IC, followed by relational capital and finally human capital.

Figure 3 shows that social, economic and environmental SP all produced statistically
significant estimates, showing their importance in explaining SP. All outer model item

Intellectual capital HC RC SC

Human capital [HC]
Relational capital [RC] 0.734
Structural capital [SC] 0.567 0.362

Sustainability
practices EC EV SS

Economic sustainability practices [EC]
Environmental
sustainability
practices [EV]

0.723

Social sustainability
practices [SS]

0.874 0.820

Note(s): Table 3 presents the results of the discriminant validity analysis using the heterotrait-monotrait
(HTMT) ratio for the variables included in the study, namely human capital, structural capital, relational
capital, and sustainability practices. The HTMT ratio is a widely used measure to assess the distinctiveness of
constructs and determinewhether they are sufficiently different from each other. The table displays the HTMT
ratio values for each pair of variables, indicating the level of discriminant validity between them
Source(s): Primary data

Table 3.
Discriminant validity

for variables using the
heterotrait-monotrait

(HTMT) ratio

Intellectual
capital of

manufacturing
firms

27



Intellectual Capital F-square R-square R-square adjusted

Human capital 0.189 0.767 0.759
Relational capital 0.243
Structural capital 0.768

Note(s): Table 4 presents the F-square values and prediction value estimates for the independent variable,
intellectual capital, in the study. The F-square values indicate the proportion of the variance in intellectual
capital that can be explained by human capital, relational capital and structural capital
Source(s): Primary data

Sustainability practices F-square R-square R-square adjusted

Economic sustainability practices 0.154 0.641 0.630
Environmental sustainability practices 0.128
Social sustainability practices 0.232

Note(s): Table 5 presents the F-square values and prediction value estimates for the dependent variable,
sustainability practices, in the study. The F-square values indicate the proportion of variance in the
sustainability practices that can be explained by the three dimensions of environmental, social and economic
sustainability practices
Source(s): Primary data

Figure 2.
Measurement model
for intellectual capital

Table 4.
F-square values and
prediction value
estimates for
intellectual capital

Table 5.
F-square values and
prediction value
estimates for
sustainability practices

IJSBI
1,1

28



loadings were greater than 0.400, the threshold set by Hair, Sarstedt, Ringle, andMena (2012).
Hence, all the manifest variables may be relied upon as reliable indicators of their latent
variables. The highest loading on SP is found for social SP (β 5 0.387, p < 0.05), indicating
that this variable best explains the observed variation in SP. A total of 64.1% of the variation
in SP may be attributed to these factors when taken together. Table 5 provides SP prediction
values.

From Table 5 we note that social SP offer the highest explanation of the variance in SP
followed by economic and finally environmental SP.

From Table 6 we present the structural model prediction results for SPs in the study.
Results show a positive and statistically significant relationship between human capital

and SP (β 5 0.174, t -statistic 2.601, p-values < 0.05). This lends credence to H1. When
individuals with the necessary competencies are brought into the organization, implementing
SP becomes relatively simple. In addition, if all workers are kept up-to-date on the company’s
sustainability-friendly actions, it will be easy to reduce the amount of air pollution caused by

Figure 3.
Measurement model

for sustainability
practices

Intellectual
capital of

manufacturing
firms

29



the manufacturing firm’s operations, with companies prioritizing community safety. In
addition, increased investment in training and development programs that focus on
sustainability issues such as environmental conservation, social inclusion and economic
prosperity will help develop the knowledge and skills of employees necessary for promoting
these sustainability initiatives.

Moreover, structural capital and SP exhibit a positive and statistically significant
relationship (β5 0.306, t -statistic 3.973, p-values < 0.05). As a consequence, H2 was supported.
This indicates that when a firm incurs the lowest cost of conducting business for long-term
advantage in contrast to others in the sector, the deployment of techniques like SP becomes
apparent. Furthermore, a company with a clear system for capturing information related to SP
streamlines manufacturing firms’ activities to be focused on environmental conservation
through pollution control, waste minimization and improving efficiency and productivity, all
with the goal of saving money for the firm in order to survive in the market place.

Additionally, the findings show a positive and significant connection between relational
capital and SP (β 5 0.501, t -statistic 8.234, p-values < 0.05). This means that H3 was
supported. This implies that when the company and its suppliers collaborate to solve
challenges associated with sustainability initiatives, it becomes easier for the spread of SP
across the entire supply chain because of increased support for local suppliers by purchasing
from them and increased use of easily degradable materials. This is because teamwork offers
a fresh perspective on one’s decisions. Improved reputation-sustainability is valued by both
clients and partners. You may increase your positive market presence by ensuring that the
company operates in a sustainable way. As a consequence, some members of the community
may gather recyclable waste and sell it to the corporation, thus boosting their ownwell-being.

Ultimately, results in Figure 4 demonstrated that the coefficient of determination r2 is
69.9% and the adjusted r square is 68.9% for the endogenous latent variable SP. This
suggests that the three dimensions of IC account for 68.9% of the variation in the SP of
Ugandan manufacturing enterprises. This indicates that H4 was supported. All the
dimensions of IC matter for the SP of manufacturing ML firms in Uganda.

5. Discussion
The RBT that the structural model of this study is based on supports the idea that IC
dimensions matter in SP. Moreover, IC significantly predicts SP. This suggests that more IC
results in more SP. Hence, it follows that changes in IC will have substantial effects on the
degree to which SP is reduced or enhanced. Bananuka et al. (2023) backs up these findings by

R square R square adjusted

Sustainability practices 0.699 0.689
β Std. Error T-statistics P-value

Human capital ▬< Sustainability practices 0.174 0.067 2.601 0.009
Relational capital ▬< Sustainability practices 0.501 0.061 8.234 0.000
Structural capital ▬< Sustainability practices 0.306 0.077 3.973 0.000

Note(s): Table 6 presents the structural model for predicting the sustainability practices in the study. The
structural model showcases the relationships between intellectual capital dimensions and the dependent
variable, sustainability practices. The table displays the estimated path coefficients, which indicate the
strength and direction of the relationships between the variables. Additionally, the table provides information
on the significance levels of the path coefficients, which determine the statistical significance of the
relationships. The findings in Table 6 offer insights into the extent to which intellectual capital dimensions
contribute to the prediction of sustainability practices
Source(s): Primary data

Table 6.
Structural Model for
prediction of the
sustainability practices

IJSBI
1,1

30



adding that investing in human capital via means like training and development will lead to
long-term success for any firm. Human capital is favorably and strongly related to the SP of
Uganda’s manufacturing enterprises, according to the study’s findings. These results are in
line with those of prior studies that indicated a favorable and substantial correlation between
human capital and sustainability strategies, including waste minimization, energy efficiency
and eco-design among industrial companies (Corredor & Gomez, 2019).

Also, our results show a positive and statistically significant link between relational
capital and SP. Solid stakeholder connections give a company better access to the networks,
experience and resources it needs to make long-lasting breakthroughs. Our findings are in
line with those of Capaldo, Messeni Petruzzelli, and Petti (2019), who discovered that a
company’s relational capital level improves its capacity for sustained innovation. Ritala and

Figure 4.
Structural model for

prediction of the
sustainability practices

Intellectual
capital of

manufacturing
firms

31



Huotari (2017) also found that corporations can help society and the environment inways that
are good for both parties when they have access to relational capital. In addition, Kazemi and
Aghdasi (2020) found that companies are more likely to adopt policies that are good for the
environment, society and the economy when they have strong relationships with their
constituents, which increases their credibility and standing in the market. Through this
process, stakeholders are met and the company’s goals for sustainability are moved forward.

Concerning the relationship between structural capital and SP in manufacturing ML, our
results revealed that structural capital is positively and significantly related to SP. This
research lends credence to the idea that there is a connection between structural capital and
SP. Findings corroborated H3. This suggests that there is a connection, contrary to the null
hypothesis. These results are in tandem with those of Liao, Lin, Chen, andWang (2021), who
found that structural capital positively affected the environmental performance of Chinese
industrial enterprises. Moreover, Liao et al. (2021) claimed that SP may be adopted and
implemented via the use of organizational structures, systems and processes by providing
resources, incentives and coordinating mechanisms.

6. Summary and conclusions
The primary objective of this study was to examine the impact of IC on the SPs of ML
manufacturing firms in Uganda. Additionally, the study aimed to investigate the individual
significance of different dimensions of IC, as identified in existing literature, on SP. To achieve
these objectives, a questionnaire survey was conducted, involving 102 manufacturing firms in
Uganda. The units of inquirywere key personnel including the productionmanager, operations
manager, environmental manager, human resource manager and chief finance officer. The
findings indicate a significant relationship between IC and SP. Notably, relational capital and
structural capital exhibited the strongest predictive potential, while human capital displayed the
lowest predictive potential for SP among ML manufacturing firms in Uganda.

This work contributes to the theory (RBT) and literature on SP and suggests that human,
social and structural IC can help Ugandan manufacturing ML firms operate sustainably. All
IC components are strategic resources and SP toolkits that may inspire other research.

In terms of managerial and practical implications, the current study highlights the
importance of managing IC effectively within manufacturing firms. To improve SP, companies
should invest in strategies that promote knowledge creation, sharing andutilization.This can be
achieved through initiatives suchas employee trainingprograms, knowledge-sharing platforms
and the establishment of cross-functional teams. Sharing information and best practices can
boost sustainability efforts and stakeholder engagement can expose sustainability issues and
solutions. Manufacturing enterprises should use their IC to create sustainable solutions, such as
creating new ecologically and socially responsible goods and services and improving current
ones to lessen their environmental effect. More so, by actively managing IC, firms can foster
innovation, improve decision-making and gain a competitive edge.

The study further emphasizes the need for manufacturing firms to adopt a culture of
continuous improvement andmeasurement in their SP.This involves setting clear goals, tracking
key performance indicators (KPIs) and regularly monitoring progress. Manufacturing firms
should establishmechanisms for collecting and analyzing relevant sustainability data, which can
guide decision-making and enable benchmarking against industry peers. By continuously
improving and measuring sustainability efforts, firms can identify areas for optimization,
demonstrate their commitment to sustainability and communicate their achievements effectively.

Our study emphasizes the need for manufacturing firms to integrate SP into their core
business operations. This includes adopting environmentally friendly manufacturing
processes, reducing waste generation and optimizing resource utilization. Companies can
explore opportunities to implement cleaner production technologies, engage in eco-design

IJSBI
1,1

32



practices and establish partnerships with suppliers that prioritize sustainability. By
embedding sustainability into their operations, firms can minimize their environmental
footprint and contribute to long-term ecological preservation.

The study accentuates the significance of collaboration and stakeholder engagement for
SP within the manufacturing domain. Manufacturing firms should actively involve their
employees, customers, suppliers and local communities in sustainability initiatives. This can
be achieved through regular communication, feedback mechanisms and collaborative
projects. By engaging stakeholders, firms can foster a culture of sustainability, gain insights
into emerging sustainability trends and build mutually beneficial relationships.

This study acknowledges several limitations that warrant consideration. The reliance on
self-reported questionnaires introduces potential biases, such as social desirability or recall bias,
which may affect the accuracy and reliability of the collected data. Furthermore, the small
sample size and geographic limitation to the central region of Uganda limit the generalizability
of the findings to the broader manufacturing industry. Caution should be exercised when
extrapolating the results to the entire population of manufacturing firms in Uganda.
Additionally, given the evolving nature of SP and IC, researchers must carefully assess the
scope,methodologyand interpretation of their data before drawing cautious conclusions. Future
research endeavors should consider employing mixed-methods approaches, incorporating
qualitativemethods to provide deeper insights andadopting longitudinal designs to examineSP
and IC over time. Comparative studies across industries and countries, as well as multi-level
analyses, would offer valuable insights into contextual factors and industry-specific nuances
that shape and influence these practices. By addressing these limitations and pursuing these
avenues of inquiry, scholars can enhance their understanding of IC and SP in themanufacturing
industry, contributing to more robust theoretical frameworks and practical implications.

References

African Union (AU) (2015). Agenda 2063: The Africa we want. Addis Ababa: African Union. Available
from: https://au.int/en/agenda2063/about

Akhtar, P., Waseem, M., & Hussain, M. (2015). Intellectual capital and sustainability: An empirical
study of the Pakistani cement industry. Journal of Cleaner Production, 107, 432–444. doi: 10.
1016/j.jclepro.2015.05.076.

Al-Khoury, A., Hussein, S. A., Abdulwhab, M., Aljuboori, Z. M., Haddad, H., Ali, M. A., . . . & Flayyih,
H. H. (2022). Intellectual capital history and trends: A bibliometric analysis using scopus
database. Sustainability, 14(18), 11615.

Alam, M., Rana, M. P., & Lodhi, S. A. (2020). Intellectual capital and sustainability practices in
manufacturing firms: A developing country perspective. Sustainability, 12(8), 3266.

Alinda, K., Tumwine, S., Kaawaase, T., Navrud, S., Nalukenge, I., & Sserwanga, A. (2022).
Sustainability practices among manufacturing firms in Uganda: An overview of challenges and
opportunities. Advances in Research, 23(1), 1–21.

Alvino, F., Di Vaio, A., Hassan, R., & Palladino, R. (2021). Intellectual capital and sustainable
development: a systematic literature review. Journal of Intellectual Capital, 22(1), 76–94. doi: 10.
1108/JIC-11-2019-0259.

Amoah, P. & Eweje, G. (2022). Barriers to environmental sustainability practices of multinational
mining companies in Ghana: An institutional complexity perspective. Corporate Governance:
The International Journal of Business in Society, 22(2), 364–384.

Amoah, P., & Eweje, G. (2023). Organisational drivers and sustainability implementation in the mining
industry: A holistic theoretical framework. Business Strategy and the Environment, 1–13. doi: 10.
1002/bse.3438.

Intellectual
capital of

manufacturing
firms

33

https://au.int/en/agenda2063/about
https://doi.org/10.1016/j.jclepro.2015.05.076
https://doi.org/10.1016/j.jclepro.2015.05.076
https://doi.org/10.1108/JIC-11-2019-0259
https://doi.org/10.1108/JIC-11-2019-0259
https://doi.org/10.1002/bse.3438
https://doi.org/10.1002/bse.3438


Ara, H., Leen, J. Y. A., & Hassan, S. H. (2019). GMS for sustainability performance in the apparel
manufacturing industry: A conceptual framework. Vision: The Journal of Business Perspective,
23(2), 170–179.

Arshad, R., Yousafzai, S., & Syed, F. (2016). Role of human capital in gaining sustainable competitive
advantage: Mediating role of relational capital. International Journal of Human Resource
Management, 27(1), 109–126. doi: 10.1080/09585192.2015.1025468.

Baltacioglu, T., Gungor, A., Kaplan, M., & Simsek, A. (2017). Sustainability in manufacturing and its
impact on profitability. In Sustainability in Engineering Design and Construction (pp. 89–98).
Springer.

Bananuka, J., Nkundabanyanga, S. K., Kaawaase, T. K., Mindra, R. K., & Kayongo, I. N. (2022).
Sustainability performance disclosures: The impact of gender diversity and intellectual capital
on GRI standards compliance in Uganda. Journal of Accounting in Emerging Economies, 12(5),
840–881. doi: 10.1108/JAEE-09-2021-0301.

Bananuka, J., Tauringana, V., & Tumwebaze, Z. (2023). Intellectual capital and sustainability reporting
practices in Uganda. Journal of Intellectual Capital, 24(2), 487–508. doi: 10.1108/JIC-01-2021-0019.

Bandinelli, R., Acuti, D., Fani, V., Bindi, B., & Aiello, G. (2020). Environmental practices in the wine
industry: An overview of the Italian market. British Food Journal, 122(5), 1625–1646.

Barney, J. (1991). Firm resources and sustained competitive advantage. Journal of Management, 17(1),
99–120. doi: 10.1177/014920639101700108.

Bello-Pintado, A., Machuca, J. A., & Danese, P. (2023). Stakeholder pressures and sustainability
practices in manufacturing: Consideration of the economic development context. Business
Strategy and the Environment, 1–19. doi: 10.1002/bse.3355.

Bonfanti, A., Mion, G., Brunetti, F., & Vargas-S�anchez, A. (2023). The contribution of manufacturing
companies to the achievement of sustainable development goals: An empirical analysis of the
operationalization of sustainable business models. Business Strategy and the Environment,
32(4), 2490–2508.

Bontis, N. (1998). Intellectual capital: An exploratory study that develops measures and models.
Management Decision, 36(2), 63–76.

Braungart, M., McDonough, W., & Bollinger, A. (2007). Cradle-to-cradle design: Creating healthy
emissions: a strategy for eco-effective product and system design. Journal of Cleaner
Production, 15, 1337–1348.

Cabrita, M. R. & Bontis, N. (2008). Intellectual capital and business performance in the Portuguese
banking industry. International Journal of Technology Management, 44(1-3), 77–98, doi: 10.
1504/ijtm.2008.015733.

Can, E. F. & Alatas, B. (2017). Sustainable development goals and their implication for business.
European Scientific Journal, 13(34), 15–24.

Capaldo, A., Messeni Petruzzelli, A., & Petti, C. (2019). Investigating the effect of relational capital on
sustainable innovation performance. Journal of Cleaner Production, 208, 1265–1277.

Castka, P., G€olgeci, I., & Piterou, A. (2021). Relational capital and sustainability practices: A dynamic
capabilities perspective. Journal of Business Research, 126, 624–634.

Chow, W. S. & Chen, Y. (2012). The effects of internal resources and external network on the
innovation performance of SMEs. Technovation, 32(5), 284–295.

Corredor, P. & Gomez, J. (2019). Human capital and sustainable manufacturing practices. Journal of
Cleaner Production, 222, 411–421. doi: 10.1016/j.jclepro.2019.03.081.

Cronbach, L. J. (1951). Coefficient alpha and the internal structure of tests. Psychometrika, 16(3),
297–334. doi: 10.1007/BF02310555.

Cucculelli, M., Bettinelli, C., & Rialti, R. (2019). Relational capital and firm performance: The effect of
intangibles drivers. International Journal of Entrepreneurial Behavior and Research, 25(3),
490–510.

IJSBI
1,1

34

https://doi.org/10.1080/09585192.2015.1025468
https://doi.org/10.1108/JAEE-09-2021-0301
https://doi.org/10.1108/JIC-01-2021-0019
https://doi.org/10.1177/014920639101700108
https://doi.org/10.1002/bse.3355
https://doi.org/10.1504/ijtm.2008.015733
https://doi.org/10.1504/ijtm.2008.015733
https://doi.org/10.1016/j.jclepro.2019.03.081
https://doi.org/10.1007/BF02310555


Dal Mas, F. (2019). Intellectual capital and sustainability: An empirical investigation of the
relationship between intellectual capital components and sustainability. Journal of Intellectual
Capital, 20(1), 43–67. doi: 10.1108/JIC-08-2018-0150.

Daspit, J. J. & Long, R. G. (2014). The influence of relational capital on strategic decision- making
transparency in small and medium-sized enterprises. Journal of Business Research, 67(5),
778–784.

Desore, A., & Narula, S. A. (2018). An overview on corporate response towards sustainability issues in
textile industry. Environment, Development and Sustainability, 20(4), 1439–1459.

Dos Santos, P. S., & Campos, L. M. S. (2020). Green practices in the fashion supply chain: A literature
review. In Leal Filho, W., Tortato, U., & Frankenberger, F. (Eds), Universities and sustainable
communities: Meeting the goals of the agenda 2030 (1, pp. 115–132). Springer.

Earley, R. (2017). Designing fast & slow. Exploring fashion textile product life cycle speeds with
industry designers. The Design Journal, 20, 2645–2656.

Farneti, F., Battisti, F., & Mora, C. (2021). The role of human capital in the adoption of sustainable
practices by firms. Journal of Cleaner Production, 279, 123813. doi: 10.1016/j.jclepro.2020.
123813.

Field, A. (2009). Discovering statistics using SPSS (3rd ed., 896). Sage Publications.

Fornell, C. & Bookstein, F. L. (1982). Two structural equation models: LISREL and PLS applied to
consumer exit-voice theory. Journal of Marketing Research, 19(4), 440–452.

Fornell, C. & Larcker, D. F. (1981). Evaluating structural equation models with unobservable variables
and measurement error. Journal of Marketing Research, 18(1), 39–50. doi: 10.1177/
002224378101800104.

Furstenau, L. B., de Melo, M. T., Varela, E. R., & Ferreira, P. M. (2020). Sustainable development goals:
A review of the measures for economic, social, and environmental impact. Business Strategy
and the Environment, 29(5), 2023–2042.

Gallardo-V�azquez, D., Su�arez-Barraza, M. F., & Ram�ırez-Portilla, A. (2020). Intellectual capital and
sustainability practices in emerging economies: Evidence from Mexico. Sustainability,
12(7), 2905.

Geissdoerfer, M., Savaget, P., Bocken, N. M. P., & Hultink, E. J. (2017). The Circular Economy – a new
sustainability paradigm? Journal of Cleaner Production, 143, 757–768. doi: 10.1016/j.jclepro.
2016.12.048.

Hair, J. F., Sarstedt, M., Ringle, C. M., & Mena, J. A. (2012). An assessment of the use of partial least
squares structural equation modeling in marketing research. Journal of the Academy of
Marketing Science, 40(3), 414–433. doi: 10.1007/s11747-011-0261-6.

Hair, J. F., Hult, G. T. M., Ringle, C. M., & Sarstedt, M. (2017). A primer on partial least squares
structural equation modeling (PLS-SEM) (2nd ed.). Thousand Oaks, CA.: Sage Publications.

Han, K., Shi, Y., & Wang, Y. (2020). Relational capital and sustainability innovation: The mediating
role of organizational learning. Journal of Cleaner Production, 244, 118670.

Hassan, M. K., Shukla, N., & Jug, M. N. (2019). Sustainability practices and their impact on firm
performance: Evidence from the manufacturing sector in Uganda. Sustainable Production and
Consumption, 20, 200–212.

Henseler, J., Ringle, C. M., & Sarstedt, M. (2014). A new criterion for assessing discriminant validity in
variance-based structural equation modeling. Journal of the Academy of Marketing Science,
43(1), 115–135.

Høgevold, N. M., Svensson, G., Klopper, H. B., Wagner, B., Valera, J. C. S., Padin, C., . . . Petzer, D.
(2015). A triple bottom line construct and reasons for implementing sustainable business
practices in companies and their business networks. Corporate Governance, 15(4), 427–443.

IEA (2015). Energy and climate change. Available from: https://www.iea.org/reports/energy-and-
climate-change

Intellectual
capital of

manufacturing
firms

35

https://doi.org/10.1108/JIC-08-2018-0150
https://doi.org/10.1016/j.jclepro.2020.123813
https://doi.org/10.1016/j.jclepro.2020.123813
https://doi.org/10.1177/002224378101800104
https://doi.org/10.1177/002224378101800104
https://doi.org/10.1016/j.jclepro.2016.12.048
https://doi.org/10.1016/j.jclepro.2016.12.048
https://doi.org/10.1007/s11747-011-0261-6
https://www.iea.org/reports/energy-and-climate-change
https://www.iea.org/reports/energy-and-climate-change


Jarrar, A. & Abu-Zaid, M. (2016). The influence of intellectual capital on corporate social responsibility
and financial performance. Journal of Intellectual Capital, 17(1), 162–182. doi: 10.1108/JIC-02-
2015-0015.

Jayashree, S., Venkatesh, R., & Arunachalam, S. (2021). Impact of technological advancements and
intellectual capital on sustainability practices of manufacturing enterprises: A review. Journal
of Cleaner Production, 278, 123789. doi: 10.1016/j.jclepro.2020.123789.

Jia, F., & Jiang, Y. (2018). Sustainable global sourcing: a systematic literature review and bibliometric
analysis. Sustainability, 10(3), 595–616.

Kazemi, A. & Aghdasi, M. (2020). Investigating the effects of relational capital and organizational
learning on sustainable manufacturing practices: A study of SMEs. Journal of Cleaner
Production, 256, 120513.

Kianto, A., S�aenz, J., & Aramburu, N. (2017). Intellectual capital and innovation in SMEs. Journal of
Intellectual Capital, 18(1), 187–210.

Kianto, A., Ritala, P., Spender, J. C., & Vanhala, M. (2019). Intellectual capital and sustainability in
SMEs: A comprehensive literature review. Journal of Cleaner Production, 233, 1392–1406.

Kozlowski, A., Searcy, C., & Bardecki, M. (2018). The reDesign canvas: Fashion design as a tool for
sustainability. Journal of Cleaner Production, 183, 194–207.

Kraus, S., Ribeiro-Soriano, D., Sch€ussler, M., & Brem, A. (2017). Foresight and sustainability:
Antecedents, research methods, and future developments. Futures, 91, 1–6. doi: 10.1016/j.
futures.2017.05.003.

Krejcie, R. V. & Morgan, D. W. (1970). Determining sample size for research activities. Educational and
Psychological Measurement, 30(3), 607–610.

Lee, S., & Kim, H. (2018). The effect of intellectual capital on corporate sustainability: Evidence from
the Korean manufacturing industry. Sustainability, 10(9), 3172.

Li, W., Bhutto, M. Y., Waris, I., & Hu, T. (2023). The nexus between environmental corporate social
responsibility, green intellectual capital and green innovation towards business sustainability:
An empirical analysis of Chinese automobile manufacturing firms. International Journal of
Environmental Research and Public Health, 20(3), 1851.

Li, Y., Liu, B., & Huan, T.-C. (2019). Renewal or not? Consumer response to a renewed corporate social
responsibility strategy: Evidence from the coffee shop industry. Tourism Management, 72,
170–179.

Liao, Y., Lin, L., Chen, Y., & Wang, Y. (2021). How do innovation, technology and intellectual capital
affect green productivity? Evidence from Chinese manufacturing firms. Journal of Cleaner
Production, 298, 126837. doi: 10.1016/j.jclepro.2021.126837.

Lieder, M., & Rashid, A. (2016). Towards circular economy implementation: A comprehensive review
in context of manufacturing industry. Journal of Cleaner Production, 115, 36–51.

Malik, M. S., Khan, M. A., & Khalid, N. (2020). Sustainable development: An empirical investigation of
the linkages between intellectual capital and sustainability. Journal of Cleaner Production, 253,
119972. doi: 10.1016/j.jclepro.2019.119972.

Malik, S., Cao, Y., Mughal, Y. H., Kundi, G. M., Mughal, M. H., & Ramayah, T. (2020). Pathways
Towards Sustainability in Organizations: Empirical Evidence on the Role of Green Human
Resource Management Practices and Green Intellectual Capital. Sustainability, 8(12), 3228.

Massaro, M., Dumay, J., & Garlatti, A. (2018). Intellectual capital and sustainability in manufacturing
companies: A systematic literature review. Journal of Cleaner Production, 172, 4325–4339.
doi: 10.1016/j.jclepro.2017.11.178.

McBride, R. B., & Adamson, K. A. (2015). Using a six-point Likert scale to evaluate attitudes toward
the use of technology in education. Journal of Educational Computing Research, 52(2), 199–208.
doi: 10.1177/0735633114562467.

IJSBI
1,1

36

https://doi.org/10.1108/JIC-02-2015-0015
https://doi.org/10.1108/JIC-02-2015-0015
https://doi.org/10.1016/j.jclepro.2020.123789
https://doi.org/10.1016/j.futures.2017.05.003
https://doi.org/10.1016/j.futures.2017.05.003
https://doi.org/10.1016/j.jclepro.2021.126837
https://doi.org/10.1016/j.jclepro.2019.119972
https://doi.org/10.1016/j.jclepro.2017.11.178
https://doi.org/10.1177/0735633114562467


Moorhouse, D., & Moorhouse, D. (2017). Sustainable design: Circular economy in fashion and textiles.
The Design Journal, 20, S1948–S1959.

Namanya, D. B. & Luukkanen, J. (2020). Environmental sustainability practices and firm
competitiveness: Evidence from the manufacturing sector in Uganda. Journal of Business
Ethics, 165(2), 307–325.

Nasreen, T., Baker, R., & Rezania, D. (2023). Sustainability reporting–a systematic review of various
dimensions, theoretical and methodological underpinnings. Journal of Financial Reporting and
Accounting, (ahead-of-print). doi: 10.1108/JFRA-01-2022-0029.

National Environment Management Authority (NEMA) (2019). State of the environment report for
Uganda 2019. NEMA.

National Planning Authority Uganda (NPA) (2020). National development plan III (2020/21-2024/25).
Kampala: NPA. Kampala, Uganda. Available from: https://www.npa.go.ug/ndp-iii/

Nave, A., do Paço, A., & Duarte, P. (2021). A systematic literature review on sustainability in the wine
tourism industry: Insights and perspectives. International Journal of Wine Business Research,
33(4), 457–480.

Ndagire, R. K. & Nakabuye, Z. (2021). The impact of intellectual capital on corporate sustainability:
A case of selected Ugandan financial institutions. Journal of Business and Management, 23(8),
44–56.

Neuman, W. L. (2007). Basics of social research methods: Qualitative and quantitative approaches (2nd
ed.). Allyn and Bacon, Boston: Pearson Education.

Nunnally, J. C. (1978). Psychometric theory (2nd ed.). New York: McGraw-Hill.

Ritala, P. & Huotari, P. (2017). Relational capital for sustainability: Exploring complementarity in
stakeholder interactions. Journal of Cleaner Production, 141, 148–157.

Romagnoli, S., Tarabu, C., Maleki Vishkaei, B., & De Giovanni, P. (2023). The impact of
digital technologies and sustainable practices on circular supply chain management.
Logistics, 7(1), 1.

Santi, S. V., Figueiredo, K. W., Formentini, M. A., & Oliva, F. L. (2021). The role of relational capital in
promoting sustainable supply chain management practices in manufacturing firms. Journal of
Cleaner Production, 306, 127321.

Schrettle, S., Hinz, A., Scherrer-Rathje, M., & Friedli, T. (2014). Turning sustainability into action:
Explaining firms’ sustainability efforts and their impact on firm performance. International
Journal of Production Economics, 147, 73–84.

Sun, P., Zhang, X., Li, Z., & Xie, X. (2018). Does relational capital matter for environmental
performance? Empirical evidence from China’s energy-intensive firms. Sustainability,
10(10), 3511.

Sunday, O. E. (2017). Sustainable manufacturing practices in developing countries: A conceptual
framework from the intellectual capital perspective. Journal of Cleaner Production, 142,
2275–2288. doi: 10.1016/j.jclepro.2016.11.064.

Tang, Y., Liu, X., Wang, J., Zhu, X., & Wang, W. (2018). CO2 emissions reduction in China’s
manufacturing industry: Evidence from nonparametric additive regression models. Journal of
Cleaner Production, 189, 145–154.

Taticchi, P., Garengo, P., Nudurupati, S. S., Tonelli, F., & Pasqualino, R. (2018). A review of decision-
support tools and performance measurement and sustainable supply chain management.
International Journal of Production Research, 56(1-2), 414–430.

Tortoriello, M., Reagans, R., & McEvily, B. (2011). Bridging the knowledge gap: The influence of
strong ties, network cohesion, and network range on the transfer of knowledge between
organizational units. Organization Science, 22(4), 1024–1039.

Uganda Bureau of Statistics (UBOS) (2018). The national business register: Manufacturing sector
report 2018.

Intellectual
capital of

manufacturing
firms

37

https://doi.org/10.1108/JFRA-01-2022-0029
https://www.npa.go.ug/ndp-iii/
https://doi.org/10.1016/j.jclepro.2016.11.064


United Nations Industrial Development Organization (UNIDO) (2018). Uganda resource efficient and
cleaner production demonstration programme. Vienna: United Nations Industrial Development
Organization.

Van der Zahn, J.-L. W. M. (2023). Sustainability reporting regime transition and the impact on
intellectual capital reporting. Journal of Applied Accounting Research, 24(3), 544–582. doi: 10.
1108/JAAR-06-2021-0143.

Wernerfelt, B. (1984). A resource-based view of the firm. Strategic Management Journal, 5(2), 171–180.
doi: 10.1002/smj.4250050207.

Widodo, B. & Shahab, Y. (2015). Human capital and competitive advantage: An empirical study in
Indonesian retail industry. Procedia Economics and Finance, 31, 712–722. doi: 10.1016/s2212-
5671(15)01251-2.

Wong, K. K. (2013). Partial least squares structural equation modeling (PLS-SEM) techniques using
SmartPLS. Marketing Bulletin, 24(1), 1–32.

World Bank (2022). Uganda. World Bank Group. Washington, DC: World Bank Publications, The
World Bank Group. Available from: https://www.worldbank.org/en/country/uganda

Yacob, T., Zhou, J., & Shi, Y. (2019). An integrated framework for sustainable development in
manufacturing firms. Journal of Cleaner Production, 226, 317–326.

Yu, J. & Huo, B. (2019). Relational capital and environmental performance: A moderating effect of
environmental dynamism. Journal of Business Research, 100, 156–164.

Yusoff, R. M., Jusoh, R., Mohd Noor, N. F., & Harun, A. (2019). Intellectual capital and sustainability in
manufacturing companies: Evidence from Malaysia. Journal of Cleaner Production, 226,
1178–1190. doi: 10.1016/j.jclepro.2019.04.127.

Further reading

Connelly, L. M. (2008). Pilot studies. Journal of Midwifery and Women’s Health, 53(6), 525–530.

Grewal, R., Michalski, T., & Purbey, S. (2019). Sustainable development and learning organizations:
An exploration of the role of training and development in building sustainability capability.
Journal of Cleaner Production, 225, 1183–1193. doi: 10.1016/j.jclepro.2019.03.290.

Mansoor, A., Jahan, S., & Riaz, M. (2021). Does green intellectual capital spur corporate environmental
performance through green workforce? Journal of Intellectual Capital, 22(5), 823–839. doi: 10.
1108/JIC-06-2020-0181.

Rauschmayer, F., Omann, I., Fr€uhmann, J., & Loibl, W. (2018). The role of learning in governance for
sustainable development: A systematic review. Journal of Cleaner Production, 198, 1438–1450.
doi: 10.1016/j.jclepro.2018.07.254.

Yong, J. Y., Yusliza, M. Y., Ramayah, T., Farooq, K., & Tanveer, M. I. (2022). Accentuating the
interconnection between green intellectual capital, green human resource management and
sustainability. Benchmarking: An International Journal. ahead-of-print(ahead-of-print). doi: 10.
1108/BIJ-11-2021-0641.

Corresponding author
Kassim Alinda can be contacted at: kalinda@mubs.ac.ug

For instructions on how to order reprints of this article, please visit our website:
www.emeraldgrouppublishing.com/licensing/reprints.htm
Or contact us for further details: permissions@emeraldinsight.com

IJSBI
1,1

38

https://doi.org/10.1108/JAAR-06-2021-0143
https://doi.org/10.1108/JAAR-06-2021-0143
https://doi.org/10.1002/smj.4250050207
https://doi.org/10.1016/s2212-5671(15)01251-2
https://doi.org/10.1016/s2212-5671(15)01251-2
https://www.worldbank.org/en/country/uganda
https://doi.org/10.1016/j.jclepro.2019.04.127
https://doi.org/10.1016/j.jclepro.2019.03.290
https://doi.org/10.1108/JIC-06-2020-0181
https://doi.org/10.1108/JIC-06-2020-0181
https://doi.org/10.1016/j.jclepro.2018.07.254
https://doi.org/10.1108/BIJ-11-2021-0641
https://doi.org/10.1108/BIJ-11-2021-0641
mailto:kalinda@mubs.ac.ug

	Intellectual capital and sustainability practices of manufacturing firms in Uganda
	Introduction
	Literature review and hypothesis development
	Theoretical underpinning
	Intellectual capital and sustainability practices
	Human capital and sustainability practices
	Structural capital and sustainability practices
	Relational capital and sustainability practices
	Intellectual capital and sustainability practices
	Summary of literature review


	Methodology
	Research design, population and sample
	Demographic characteristics
	Questionnaire and variables measurement
	Validity and reliability
	Data analysis

	Results
	The measurement models
	Structural model
	Test of hypothesis


	Discussion
	Summary and conclusions
	References
	Further reading