CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 57, 2017 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Sauro Pierucci, Jiří Jaromír Klemeš, Laura Piazza, Serafim Bakalis 
Copyright © 2017, AIDIC Servizi S.r.l. 

ISBN 978-88-95608- 48-8; ISSN 2283-9216 

Dynamic Safety Capability and Organizational Management 
Systems: an Assessment Tool to Evaluate the “Fitness-To-

Operate” in High-Risk Industrial Environments  
Matteo Curcurutoa, Mark A. Griffinb, Melinda R. Hodkiewiczc 
a School of Social Sciences, Leeds Beckett University, Portland Way, Leeds, LS1 3EE, United Kingdom  
b Business School, The University of Western Australia, 35 Stirling Hwy, Perth, 6009, WA, Australia 
c School of Mechnical Engineering, The University of Western Australia, 35 Stirling Hwy, Perth, 6009, WA, Australia 
M.MA.Curcuruto@leedsbeckett.ac.uk 

Aim. The paper outlines a systemic approach to understanding and assessing safety capability in high-risk 
industries, like  off-shore oil, gas industry, chemical operators. The “Fitness to Operate” framework (acronym: 
FTO) (Griffin et al., 2014) has been recently defined by three enabling capitals that create safety capability: 
organizational capital, social capital, and human capital. Furthermore, each type of capital is identified by more 
specific dimensions based on current theories of safety, management, and organizational processes. In this 
paper, we will present a multidimensional assessment tool that offers a comprehensive picture of safety 
capability by real industrial operators in order to understand and evaluate their “fitness-to-operate” (FTO).  
Method. This current paper aims to describe the multi-phase development process of a FTO assessment tool 
in the format of a multidimensional survey questionnaire. A)  The first research phase consists of the item 
generation of a large prototype pool with about 200 contents-items covering the 27 dimensions of the 
conceptual representation of the FTO framework. This initial pool was developed by a team of academic 
researchers, through a deductive process, and in the light of the original FTO conceptualization, as defined by 
Griffin and colleagues (2014) B) In a second research phase, the initial pools of items were re-examined by a 
new pool of academic researchers, assessing the quality of the contents, and in order to refine the extensive 
version of the prototype, eliminating potential redundancies and inadequate items. C) In a third phase with 
structured interviews to a pool of industrial experts (senior safety managers; senior executives), the authors 
assessed the quality of the prototype tool developed by the academic researchers, in order to evaluate and 
ranks the items of the prototype in term of quality, in order to define and identify a shorter version of the 
prototype. All the items were assessed by the experts considering criteria such as: i) relevance ii) clearness iii) 
verifiability iv) specificity v) ease of answer. Implications. Overall, the FTO assessment tool enables a 
comprehensive coverage of factors that influence short-term and long-term safety outcomes. The tool may 
serve to help safety regulators and industrial operators to understand, assess, and eventually implement and 
improve the safety capability and fitness-to-operate in complex industrial and organizational contexts. 

1. Understanding Dynamic Safety Capability (DSC): conceptual definitions and foundations 

This paper focuses on the concept of ‘‘dynamic safety capability’’ (DSC) to describe an organization’s 
capacity to proactively improve its core safety systems in high-risk environments characterized by complexity 
and uncertainty (Griffin et al., 2016). Managing improvements is a central concern for all organizations but is 
particularly challenging in hazardous industries where the reliability of safety systems is essential. 
Investigations of major accidents frequently recommend major changes both within the organization and 
across the broader industry. Ongoing changes in economic, social, and environmental conditions also require 
change and adaptation in hazardous industries. Maintaining reliability and safety under frequently changing 
conditions is an equally pressing imperative that is highlighted by extensive research into high-reliability 
organizations (HROs). The study of HROs emphasizes how successful organizations maintain reliability while 
adapting to unexpected change and unplanned events (e.g., Curcuruto et al., 2016).  

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1757049

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Curcuruto M., Griffin M., Hodkiewicz M., 2017, Dynamic safety capability and organizational management systems: 
an assessment tool to evaluate the “fitness-to-operate”  in high-risk industrial environments, Chemical Engineering Transactions, 57, 289-294  
DOI: 10.3303/CET1757049 

289



Distinct types of change are reflected in the response to significant accidents and critical incidents compared 
to the continuous improvement of HROs described before (Curcuruto et al., 2014; Saracino et al., 2015). In 
contrast, changes to highly reliable systems involve more proactive and forward-looking changes that tend to 
be more incremental in nature. Both types of change have been the motivation for substantial improvements in 
safety operations for hazardous industries. However, according with Griffin, Cordery and Soo (2016), there is 
currently a relative lack of conceptual frameworks for describing qualitatively different kinds of change in 
safety systems. More precisely, the authors argued that the process of proactively changing core safety 
systems is not well articulated in current approaches to safety. Consequently, they introduced the concept of 
‘‘dynamic safety capability’’ (DSC) to explain the nature of this capability and the nature of organizational 
change that is involved. They defined DSC as “an organization’s capacity to generate, reconfigure, and adapt 
operational routines to sustain high levels of safety performance in environments characterized by change and 
uncertainty” (Griffin et al., 2016, p. 249). The construct of DSC is funded on the theories of dynamic capability 
(e.g., Ambrosini & Bowman, 2009) which seek to understand an organization’s ‘‘ability to sense and then seize 

new opportunities, and to reconfigure and protect knowledge assets, competencies, and complementary 
assets’’ (Augier & Teece, 2009, p. 412). In other  words, the notion of dynamic capability might be also defined 
as ‘‘a learned and stable pattern of collective activity through which the organization systematically generates 

and modifies its operating routines in pursuit of improved effectiveness” (Zollo & Winter, 2002, p. 340). 

2. Enabling “DSC” in industrial organizations : Human, Social, Organizational Capitals 

In the field of risk and safety management, the construct of DSC is especially important because many 
hazardous operations face substantial change arising from new technology, evolving environmental 
imperatives, and workforce demographics (Griffin et al., 2016). Although specific changes are unpredictable, 
there is a need to prepare for new conditions and operate safely and competitively. DSC provides a bridging 
concept to integrate relevant research from both organizational management and safety management (Griffin 
et al., 2016). In another paper, Griffin et al. (2014) outlined a systemic approach to understanding and 
assessing safety capability in the off-shore oil and gas industry. The authors presented a more comprehensive 
conceptual picture of safety capability for regulators and operators of offshore facilities, namely “Fitness-to-
Operate” (acronym: FTO) (Griffin et al., 2014). The FTO framework defines three enabling capitals that create 
safety capability: organizational capital, social capital, and human capital. For each type of capital, the authors 
identified more specific dimensions and sub-elements based on current theories of safety, management, and 
organizational processes. The assessment guide matches specific characteristics to each element of the 
framework to support assessment of safety capability. As such, the content and scope of the FTO framework 
enable a more comprehensive coverage of factors that should influence short-term and long-term safety 
capability and outcomes. For instance, the human capital domain includes personal attributes of the 
employees, like technical safety-skills and expertise and not-technical personal skills, which have been 
frequently investigated as proximal antecedents of safe conducts in the workplace (Griffin & Curcuruto, 2016). 
Similarly, the social capital domain covers multiple collective properties of work-teams such as safety culture 
and team processes, which have been empirically associated with team safety performances (Curcuruto et al., 
2015). Finally, the organizational capital domain includes different collective properties that align with the 
organizational such as information systems and organizational systems, which aim to manage and link 
together information from complementary organizational processes and routines, like risk management and 
HRM (Saracino et al., 2015). Figure 1 illustrates an adaptation of the overall structure of the original 
framework proposed by Griffin et al. (2014). The picture shows how each enabling capital is composed of an 
articulated set of dimensions and sub-elements. We will use this framework as a general conceptual guide.  

3. Research aim: to develop a FTO assessment tool to evaluate the three enabling capitals  

After describing the conceptual definitions and foundations of DSC and illustrating the hierarchical structure of 
the enabling capitals of DSC (dimensions; sub-elements), we will shortly present now our research aims and 
the methods we used. Essentially, the scope of our research is to contribute to develop an original 
multidimensional survey tool that might  be used to provide an assessment of the quality of the human, social 
and organizational capitals enabling DSC, including an estimation of their internal structures (dimensions; sub-
elements). We believe that such a tool can be useful for public institutions, industries and safety regulators to 
assess the “fitness to operate” in high-risk environments. A similar tool could be used to help companies and 
organizations in different ways: a) to develop an understanding of their safety capability using a common 
language and framework b) to diagnosis the factors impacting safety performances c) to monitor the general 
quality of their safety management systems and  sub-systems c) to detect potential weakness that might need 
potential changes and improvements d) to support a life cycle approach to maintaining safety capability. 

290



 
 

Figure 1: The Fitness-To-Operate framework (FTO) adapted from the model defined by Griffin et al. (2014): 

enabling capitals, dimensions and sub-elements supporting the safety capability by industrial organizations 

4.  Research methods and phases  

To develop an assessment tool of the elements supporting dynamic safety capability by organizations, we set 
up a multi-phase strategy with multiple qualitative research stages (Curcuruto, 2016): a) initial item generation 
by a pool of researchers b) content-analysis by a pool of academic experts c) structured interviews with safety 
managers from a world leader chemical industrial company. These phases will be better described in the next 
sections. 

4.1 Generation of an extensive pool of descriptive statement items 

The first research phase consisted generation of a large prototype pool with about 250 contents-items 
covering all the twenty-seven conceptual elements of the FTO framework, as defined by Griffin and colleagues 
(2014). This initial pool was developed through a deductive process by a multidisciplinary team of academic 
research associates and assistants from different university faculties like engineering, business and 
organization, psychology. For each element of the FTO framework, the researchers generated an exhaustive 
set of descriptive statements covering all the principal characteristics of every element. Just to provide an 
example, the element “emergency skills” of the human capital domain was described by a set of items 
indicating key characteristics like:  “to know all prescribed procedures for emergency situations”, “to know how 
to handle emergency equipment and devices in emergency situations”, “to know how to coordinate their efforts 

with other people and teams in real emergency situations”. 

4.2 Content analysis to select a refined prototype assessment tool 

In a second research phase, the large pool of items developed in the previous stage were re-examined by a 
new research group composed of five senior academic researchers, who assessed the quality of the large 
pool of items created at stage 1. All the items were evaluated in terms of adequacy, clarity, potential 
redundancies, in order to eventually refine the extensive version of the prototype. At the end of this stage, a 
reduced version of 186 items was achieved. For example, the “error management culture” was described by 
items such as: “to discuss one’s own errors in a “blame-free” atmosphere”, “to handle the detected errors in a 
constructive way”, “to avoid successfully the potential negative consequences of errors”.  

291



4.3 Structured interview stage with senior industrial safety experts  

In a third phase, structured interviews of six industrial experts (senior safety managers; senior executives) 
were conducted. The authors assessed the quality of the prototype tool developed by the academic 
researchers, in order to evaluate and validate all the items in term of fit and congruence with the real industrial 
and organizational settings. Every expert presented a specific competence in relevant areas of managerial 
safety systems, like process safety, behavioral safety, human resource management, organizational 
information systems. All the experts were currently employed a high-risk chemical plant in Southern Europe. 
Interview grid. Each industry expert was asked to assess a single dimension of the FTO prototype 
questionnaire, using a specific quality assessment grid prepared by the authors. The grid allowed the research 
team to collect and order the judgement of the experts, with the final aim to rank all the items using 
quantitative criteria, and eventually assigning an “index of quality” to every item developed at Stage 2. Seven 
quantitative parameters were used to understand how much the content items presented attributes of quality 
in terms of : a) relevance for the organizations at different stage of maturity and safety culture b) 
demonstrability of the answer for the organizations and external assessors c) ease of the answer for the 
interviewed. Every parameter was assessed  with a scale from 0 (not at all) to 4 (in a great extent). The 
assessment grid is reported in table 1.  
Filter questions. In addition to the quality criteria reported in table 1, the interviewees were asked to respond 
to three extra filter questions. These extra questions were used to identify: a) the potential best response for 
every item, considering different hierarchical levels in the organization b) not functional items for the goodness 
and economy of every single scale meant as whole indicators c) potential redundant content items that might 
be merged to facilitate more parsimonious scale. In other words, these last three questions were used as filter 
criteria for the final decision about the item retention in the final version of the FTO prototype tool. These final 
filter questions are reported below: 

- Question filter 1 (target of respondents at every item): “Who could realistically provide an accurate 
information on this issue?” (possible answers: 1= operator at the “bottom” organizational level; 2= 
supervisors & managers; 3 = only managers).  

- Question filter 2 (applicability of the assessment scale for each element of FTO): “Have you found 
some items being no relevant, ambivalent or not functional to assess this element of the FTO tool?”.  

- Question filter 3 (parsimony of the assessment scale for each scale of FTO): “Which items with a 
similar content would you merge to reduce the length of the assessment scale of this FTO element?” 

4.4 Evaluating and ranking the items of the FTO prototype assessment tool  

Once all the items were assessed by the industrial experts, the researchers computed an overall quality index 
for each item in order to select a valid and parsimonious version of the academic FTO assessment tool. This 
general quality index was computed as statistical mean of the seven partial rates described in table 1. 
According to this final quality index we selected from four to six item to evaluate every single element defining 
the three enabling capitals of Dynamic Safety Capability (as presented in the FTO framework showed in figure 
1). We used a value of 3 as cut-off value. When more than six items presented more than six adequate items, 
we used the filter question to select the final items to retain, giving priority to the items which showed more 
probability to be understandable at every hierarchical level of organizations (filter 1), and discarding the items 
which were indicated as potentially redundant or not  functional to define a unique scale of items (filters 2 & 3).    

Table 1:  The Interview Grid used in phase 3 to assess the quality of the FTO prototype tool  

Seven criteria of quality of the items in terms of:  “relevance” (questions 1, 2 & 3), “demonstrability” (questions 
4 & 5), “ease of answer” (questions 6 & 7) 

Instructions given to the interviewee: “Please, rate every item addressing each of the evaluation criteria”. 
(Evaluation scale: zero = not at all;  four = in a great extent)  
1. How much it this content item relevant for the general organizational system of your company? it this it 

2. How much is this content item relevant for the management of safety in a company at the entrance in a 
regulatory system? 

3. How much is this content item relevant for the management of safety  in a mature company with high level 
of reliability and safety culture? 

4. How much would be feasible for an organisation to provide proof that this item has been addressed? 
5. How much would be feasible for an external assessor  to rate an organisation on the basis of this content? 
6. In which extent the content item was clear? 
7. In which extent was easy for you to provide me with all this information on this content item? 

292



5. The final “Fitness-To-Operate” prototype assessment tool  

Following the several research stages recommended in literature to develop new assessment survey tool with 
a qualitative methodology (Curcuruto, 2016; Curcuruto et al., 2016), we were eventually able to achieve a final 
version of  the FTO assessment tool consists of 130 items, covering twenty-three of the elements defining the 
human, social and organizational capitals supporting dynamic safety capability in industrial setting (Griffin et 
al., 2016; Griffin et al., 2014). Given the complexity of the overall conceptual framework it is not possible to 
show an extended version of the overall prototype tool. However, tables 2, 3 and 4 present three examples of 
assessment scales for single element  from each one of the three main enabling capitals. More information 
about the complete version of the FTO tool are available contacting the authors of the present manuscript. 

Table 2:  The assessment scale for the element  “Process safety skills”  (from the “Human Capital”) 

 Instructions: “Please, consider people in your team or organizational unit …” 

1. As the operating context changes, do individuals know when to ask for external technical 
assistance? 

2. When individuals are engaged in new activities/ changes, are you confident that risks are 
understood? 

3. Are you confident that they have the breadth and depth of knowledge of major accident 
risks appropriate to your facility? 

4. Are you confident they would know when to stop the operation? 
5. Do you trust them to manage the response to an incident (such as a gas leak)? 
6. Are you confident the people that plan and manage the operation of your facility 

understand the factors that influence risk? 

Table 3:  The assessment scale for the element  “Learning & flexible culture”  (from the “Social Capital”) 

 Instructions: “Please, consider your team or organizational unit …” 

1. Does the team discuss how potential problems (e.g. near-miss, errors…) might be 
managed? 

2. Are unusual events used as sources for learning? 
3. Do team members discuss errors and mistakes, and how they could have been prevented 
4. Can the team do things differently if they think it is necessary without waiting for the 

approval of higher authorities? 

5. Can the team regroup and restructure its work if needed? 
6. Are team interactions effective when responding to unexpected events? 

Table 4:  The assessment scale for the element  “Risk management”  (from the “Organizational Capital”) 

Instructions: “Please, consider your department or your organization …” 

1. Are activities of risk and hazard identification conducted by specific qualified teams? 

2. Are activities conducted to identify control measures, in order to reduce every risk factor to 
the lowest level reasonably practicable? 

3. Are worker opinions and evaluations on risk factor attributes collected?                                         
(i.e. estimation of accident likelihood; personal exposure; consequence severity) 

4. Are workers involved in proactive activities of risk prevention and monitoring                                   
(i.e. job safety analysis; peer-to-peer observations; safety committee)? 

5. Are workers actively involved in the ergonomic and usability review of risk control 
measures (i.e. procedures; tools and devices)? 

6. Are workers encouraged to report any incongruences with existing EHS regulations (safety 
omissions, risky conduct and violations) to their direct supervisors or to the EHS office? 

 

293



6. Conclusions 

The study reports systematic development of a set of items that capture the way organisations achieve safety 
capability. The items reflect processes at the individual, social, and organisational level that are important for 
ensuring organisations can manage safety in dynamic and unpredictable environments. The FTO assessment 
framework presented in this paper might support a systemic and comprehensive approach to safety over the 
life-time of an industrial facility. The need for high reliability and responsiveness to change and means that it is 
important for regulators and operators to recognize the key factors that influence safety capability.  
In order to provide further evidences of validity, the next logic research steps should set up experimentations 
of the FTO assessment model in specific industrial contexts using a confirmative oriented approach (Mariani 
et al., 2016). In which extent the validation of our assessment model can be generalized in other industrial 
business sectors and in different national regulation systems? Moreover, beyond the instances of 
generalizability and contextual validity, it would be certainly relevant for research advancement purposes to try 
to address specific conceptual key questions, concerning the internal structure of our framework and the 
alignment among subcomponents. For instance, which typology of relationship exists between the different 
enabling capitals of the FTO framework and between their elements? How these relationship may change in a 
long term cycle of life? The systemic nature of the framework certainly  encourages integration of safety 
culture and human skill with the organizational procedures and processes that enable reliability and 
adaptability. We hope that our assessment framework might help to identify the causal links between 
organizational, social, human factors that combine to create the safety dynamic capability of industries. 

Acknowledgments  

This research was developed between 2014 and 2015 at the Centre for Safety at the University of Western 
Australia directed by professor Mark Griffin, when the first author was employed there with the role of 
Research Assistant Professor. The authors would like to thanks the site director and safety managers from the 
BASF plant in Pontecchio Marconi (Italy), for their precious contribution to the interview stage described at the 
section 4.3 of this manuscript: Tiziano Lanzarini, Franco Fantuzzi, Giulio Mulazzani, Daniela Bongiovanni. 

Reference  

Ambrosini, V., Bowman, C., 2009, What are dynamic capabilities and are they a useful construct in strategic 
management?, International Journal of Management Reviews, 11, 29–49. DOI:10.1111/j.1468-
2370.2008.0025 

Augier, M., Teece, D.J., 2009, Dynamic capabilities and the role of managers in business strategy and 
economic performance, Organization Science, 20, 410–421. DOI:10.1287/orsc.1090.0424 

Curcuruto, M., 2016, Safety participation in the workplace: An assessment tool of proactive safety orientations 
by individuals (PRO-SAFE), Chemical Engineering Transactions, 53, 181-186. DOI: 10.3303/CET1653031 

Curcuruto, M., Conchie, S., Mariani, M.G., Violante, F.S., 2015, The role of prosocial and proactive safety 
behaviors in predicting safety performance, Safety Science, 80, 317–323. DOI:10.1016/j.ssci.2015.07.032 

Curcuruto, M., Guglielmi, D., Mariani, M.G., 2014, A diagnostic tool to evaluate the proactivity levels of risk-
reporting activities by the workforce, Chemical Engineering Transactions, 36, 397–402. 
DOI:10.3303/CET1436067 

Curcuruto, M., Mearns, K.J., Mariani, M.G., 2016, Proactive role-orientation toward workplace safety: 
Psychological dimensions, nomological network and external validity, Safety Science, 87, 144–155. 
DOI:10.1016/j.ssci.2016.03.007 

Griffin, M.A., Cordery, J., Soo., C., 2016, Dynamic safety capability: How organizations proactively change 
core safety systems, Organizational Psychology Review, 248-272. DOI: 10.1177/2041386615590679 

Griffin, M.A., Curcuruto, M., 2016, Safety climate in organizations, Annual Review of Organizational 
Psychology and Organizational Behavior, 3, 191-212. DOI:10.1146/annurev-orgpsych-041015-062414 

Griffin, M.A., Hodkiewicz, M.R., Dunster, J., Kanse, L., Parkes, K.R., Finnerty, D., Cordery, J.L., Unsworth, 
K.L., 2014, A conceptual framework and practical guide for assessing fitness-to-operate in the offshore oil 
and gas industry, Accident Analysis & Prevention, 68, 156–171. DOI:10.1016/j.aap.2013.12.005 

Mariani, M.G., Soldà, B., Curcuruto, M., 2015, Employee safety motivation: perspectives and measures on the 
basis of the self-determination theory, Medicina del Lavoro, 5, 333–341. 

Saracino, A., Curcuruto, M., Antonioni, G., Mariani, M.G., Guglielmi, D., Spadoni, G., 2015, Proactivity-and-
consequence-based safety incentive (PCBSI) developed with a fuzzy approach to reduce occupational 
accidents, Safety Science, 79, 175–183. DOI:10.1016/j.ssci.2015.06.011 

Zollo, M., Winter, S.G., 2002, Deliberate learning and the evolution of dynamic capabilities, Organization 
Science, 13, 339–351. DOI:10.1287/orsc.13.3.339.2780 

294