Scientific Papers International Conference on Knowledge Society http://con feren ce. sc ientif ic papers.org A Structural Approach to Supply Chain Process Shpëtim Çerri a a Department of Marketing, Faculty of Economics, University Aleksandër Xhuvani, Pranë Parkut Rinia, Elbasan, 3000 Albania, shpetim.cerri@uniel.edu.al ARTICLE INF O Article history: Received: January 15, 2014 Received in revised form: February 5, 2014 Accepted: February 10, 2014 Available online: February 21, 2014 K EYWORDS: Supply chain integration, structural equations modeling, Albania ABSTRACT The competitiveness and dynamics of business environment today expose firms to many challenges. They are part of a whole chain of entities and activities that create goods and services and make them available to customers. Implementation of supply chain management techniques requires thorough integration of processes between supply chain partners in all functional areas, including sourcing, manufacturing, and dis-tribution. This study uses a structural approach to measure supply chain integration of Albanian companies. Based on an extensive relevant literature review and interviews with field specialists, a supply chain inte-gration scale was developed. Then an exploratory factor analysis was conducted to test the applicability of the items developed. Structural equation modeling was used to test the convergent validity through confir-matory factor analysis. The study is finalized with a structural model of supply chain integration. The pro-posed model demonstrates the relative importance of several dimensions that comprise supply chain integra-tion. The result produces a validated integration scale that can help in diagnosing supply chain problems and possibilities. Introduction For many companies, the supply chain (SC) strategy plays a crucial role in generating and maintaining competitive advantage (Mentzer et al., 2001, Shankar 2001). In today s business environment, characterized by fierce competitiveness and highly dynamic events, gaining and maintaining competitive advantage requires a continuous collaboration and coordination with external resources and partners. Supply chain management has a favorite position in acting as a coordinator of information and decisions for all companies engaged in a supply chain, prioritizing those resources combination that lead to competitive advantage. Metzer et al. (2001, p. 2) define supply chain as three or more companies directly linked through one or more upstream and downstream flows of products, services, finances and information, from the source to the customer. Focusing more on supply chain integration (SCI) has happened due to the increased awareness among managers that performance maximization for a single firm can lead to non-optimal performance for the supply chain as a whole (Monczka et al., 1998). An integrated supply chain includes functional integration within the firm and outside the firm with other partners of supply chain, as well as with customers (Cooper et al., 1997). It is an interconnected network of customers and suppliers who work together to optimize their joint performance in creating, distributing and supporting an end product or service.
Supplier Technology & Planning Internal Measurement Systems Customer Supply Chain Relationship Figure 1: The conceptual model of the study Bowersox et al. (1999) have identified six areas whose integration lead to the integration of supply chain. They are namely customer integration, internal integration, supplier integration, technology and planning integration, measurement integration and relationship integration. This supply chain conceptualization has been used in many studies (De Martino and Marasco, 2007; Fugate, et al., 2010; Morash, 2001; Stank, et al., 2005; Töyli et al., 2008; Zhao, et al., 2011, etc.). The framework introduced by Bowerox et al. (1999) served as a basis for conceptualizing supply chain integration in this study. The general model proposed in this paper conceptualizes the SCI as a second order latent construct, whose antecedents are the six constructs mentioned above. The six antecedents of SCI are supossed to fully capture the essence of SCI. The model proposed is presented at Figure 1. The study of SCI focused on retail sector in Albania, aiming subjects with two or more outlets. The study follows the approach proposed by Dunn et al. (1994) on developing and validating latent variables in business logistics research. First, constructs were defined and potential items were developed. Then, content validity was checked and initial scale was developed. The next step was conducting exploratory factor analysis and confirmatory factor analysis, in order to purify the instrument proposed and check reliability, convergent and discriminant validity of the scale. Finally, structural equation modeling was used to test the whole proposed model and to investigate the relationships between the proposed constructs. Literature review and hypotheses development Today, supply chains and networks composed of multiple companies are becoming primary elements of competitive analysis (Chen and Paulraj, 2004). The supply chain ability to fulfill consumer demands and needs in an efficient and effective manner has become a strategic ability, which leads to competitive advantage (Ireland and Webb, 2007). Today there are not firms who compete against each other, but the network of interdependent firms where they belong compete with other networks (Christopher, 2005). Thus, the new challenge today is designing and effectively managing these supply chains or networks (Chen and Paulraj, 2004; Christopher, 2005). Integrating supply chains is a very effective tool to face this contemporary challenge (De Martino and Marasco, 2007). Several authors, like Bowersox and Morash (1989) and Hammer (2001) suggest that SCI means integrating relationships, activities, functions, processes and locations across all the members of supply chain. Naylor et al. (1999) showed that the objective of SCI is eliminating all the boundaries between companies and enabling a seamless flow of materials, money, resources and information. Lee and Whang (2001) suggested that SCI can be defined as a managerial approach which aims towards a greater coordination and collaboration between SC partners, in order to sustain competitiveness. Bowersox et al. (1999) have conceptualized SCI as comprised of six types of integration: customer integration, internal integration, supplier integration, technology and planning integration, measuring systems integration, and relationship integration. Customer integration means creating distinct activities with selected customers. Since few firms can satisfy every customer or customer segment, firm s management should decide on pursuing those activities that better fit customer needs (Bowersox et al., 1999). Internal integration is a core competency which means linking internal activities to comply with customers requests, at the lowest total system costs (Bowersox et al., 2002). This
competency asks for process excellence of the whole company, in order to achieve synergies which lead to higher performance in fulfilling customers demands (Bowersox et al., 1999) Supplier integration refers to the degree a firm could create partnerships with key members of its SC, in order to structure the strategies, practices, procedures and inter organizational behaviors into collaborative processes, synchronized and managed to fulfill end customers demands (Stank et al., 2001). Technology and planning integration means structuring firm s strategic objectives and goals, as well as sharing resources, rewards and risk across SC members in a contractual and consensual agreement in order to achieve and maintain competitiveness (Fuchs et al., 2000). Due to its strategic importance, technology and planning integration can be considered as a key pre condition towards SCI. Measuring systems integration is very necessary to manage coordinated operations of SC. The integration of measuring systems refers to the degree a company could structure measuring systems and manage measuring activities with key members of its SC, in order to evaluate integrative strategies of SC (Bowersox et al., 1999). Relationship integration is a key prerequisite for SCI. From a strategic perspective, the integration between members of a SC starts when the relationships between firms are considered as strategic assets (Anderson et al., 1994). Relationship integration is achieved when a firm can structure the creating, commitment, maintaining, and terminating a relationship with its partners through consensual and contractual agreements (Bowersox et al., 1999; Stank, et al., 2001). The model proposed in this study conceptualizes SCI as a reflective construct. Six antecedents, latent construct themselves, lead to SCI. Thus, the hypotheses derived from the model proposed in the study are: H1: Customer integration is a significant driver of SCI. H2: Internal integration is a significant driver of SCI. H3: Supplier integration is a significant driver of SCI. H4: Technology and planning integration is a significant driver of SCI. H5: Measurement systems integration is a significant driver of SCI. H6: Relationship integration is a significant driver of SCI. Initial scale construction In order to identify the initial items of measurement scales for SCI, three sessions of focus groups were conducted. Members of these focus groups were supply chain and logistics researchers as well as supply chain professionals. Focus groups discussed the original study of Bowersox et al. (1999), which contains in total 100 items for measuring six types of integration. From this pool of indicators, finally 45 items were chosen to construct the initial scales of SCI. The selection criteria were their adaptability and suitability to Albanian economy context. Some of the indicators were modified and adapted to suit the study context. In order to evaluate content validity for each of the initial items of six antecedents of SCI, the approach proposed by Lawshe (1975) was used. This approach measures the level of harmony between the specialist evaluators about how much essential a particular item is in explaining a construct or phenomenon (Lawshe, 1975). After examining each initial item, harmony was achieved for 45 of the items representing SCI. These items were then used to build the measurement scale for SCI antecedents and SCI itself. Table 1 presents the items used for measuring each construct. Table 1: Constructs of the study and respective items Construct Customer integration (CI) Item - Having unique logistics service strategy for different customers. (CI1) - Continuously integrating and facilitating individual customer requests across strategic business units. (CI2) - Focusing logistic operations on key customers success. (CI3) - Periodically reviewing customer service offers in order to ensure compliance with customers logistical requests. (CI4)
Internal integration (II) Supplier integration (SI) Technology and planning integration (TI) Measuring systems integration (MI) Relationship integration (RI) Supply chain integration (SCI) - Continuously fulfilling special requests of selected key customers. (C5) - Synchronizing logistical operations with customer s operations. (CI6) - Building communication lines with customers which enable last minute changes without loss of planned efficiency. (CI7) - Fulfilling a wide range of unique customer demands through implementing pre planned solutions. (CI8) - Reducing formal organizational structure to fully integrate firm s operations. (II1) - Moving the focus of the company from managing functions to managing processes. (II2) - Actively encouraging the implementing of best practices. (II3) - Actively engaging in standardizing the practices and operations of SC. (II4) - Continuously reducing facility and operational complexity. (II5) - Developing performance incentives based on process improvement. (II6) - Using real time logistical solutions. (II7) - Reducing order to delivery cycle time. (II8) - Successfully integrating operations with customers and/or suppliers through developing interlinking activities. (SI1) - Believing that strategic management, the role and performance of SC partners are critical for firm s success. (SI2) - Using logistical capacities as criteria for choosing firm s suppliers. (SI3) - Significantly reducing the number of suppliers in order to achieve operational integration. (SI4) - Enjoying performance improvement through integrating operations with SC partners. (SI5) - Sharing technical sources with key suppliers in order to facilitate operations. (SI6) - Willingness to enter into long term relationships with suppliers. (SI7) - Using innovative methods to facilitate the coordination through performance monitoring. (SI8) - Being able to internally share standardized and customized information. (TI1) - Moving toward integrated planning. (TI2) - Continuously investing in technology to increase inter organizational information exchange. (TI3) - Developing a common set of expectations with SC partners. (TI4) - Being involved in joint planning and forecasting with suppliers and/or customers. (TI5) - Measuring functional performance comprehensively. (MI1) - Being committed to zero defections. (MI2) - Developing and applying measures that extends across the SC relationships. (MI3) - Implementing and using a formal program to measure customer satisfaction. (MI4) - Using benchmarking as a measurement indicator. (MI5) - Management being able to determine the impact of enhanced SC on incomes and revenues. (MI6) - Clearly determining roles and responsibilities together with SC partners. (RI1) - Creating acceptable practices for cooperation with suppliers and customers. (RI2) - Management being able to understand that engaging in a SC means substantial empowerment. (RI3) - Having clear orientations for developing, maintaining, monitoring and terminating SC relationships. (RI4) - Effectively sharing operational information between departments. (RI5) - Effectively sharing operational information with suppliers and/or selected customers. (RI6) - Company having a high level of SCI. (SCI1) - Company having a high integration level with suppliers. (SCI2) - Company having a high internal inter functional integration level. (SCI3) - Company having a high integration level with customers. (SCI4) Research methodology and variable measurement The sample of the study comprised of retail businesses with two or more outlets. The sample was drawn from retail businesses population in the seven largest cities in Albania. Data were collected through face to face interviews. From 300 questionnaires distributed, 289 were returned fully completed, and from those 8 were excluded because of possible unrealistic responses. Thus, only 281 questionnaires were considered valid for further analysis. A seven point Likert scale was used for all the items of the measurement instrument, where 1 =
Totally disagree and 7 = Totally agree. Managers of the retail businesses, part of the sample, were asked to express their level of agreement with each of the statements in the questionnaire. Exploratory Factor Analysis (EFA) The main objective of EFA is to determine the underlying structure between variables in an analysis (Hair et al., 2009). EFA was conducted using Principal Axle Factoring PAF extraction method, with oblimin rotation, in order to identify the factor structure for the seven proposed constructs. PAF was chosen because the objective of the analysis was to obtain parameters reflecting latent constructs (Garson, 2012). Oblimin rotation was chosen because it was supposed that inter correlations existed between dimensions (Dunteman, 1989, Stevens, 2002; Hair et al., 2009). The objective of these examinations was to evaluate the dimensionality of the scales used in this study. EFA and scale purification process were conducted step by step. The items with low factor loadings (lower than 0.05), high cross loadings (greater than 0.4), and/or high item-to-total correlation were excluded from the factor matrix. The items who didn t meet these criteria, thus excluded from factor matrix, were CI8, SI2, SI6, MI3, and RI3. Because some elements were excluded and the resulting total number of factor was reduced, it was necessary to re calculate item-to-total correlations as well as to re examine the factor structure of the reduced items set. This iterative process concluded in a final set of 40 items representing six antecedents of SCI and SCI itself. The final factor solution had good loadings patterns and explained 77.308 per cent of the variance. Confirmatory Factor Analysis (CFA) In order to evaluate the dimensionality, reliability, and validity of the generated structure of constructs, CFA was conducted. CFA seeks to determine if the number of factors and the loadings of measured variables are consistent with what is expected from the existing theory (Brown, 2006). In order to confirm the unidimensionality of the scale, LISREL 8.80 software was used. Correlations between items and fit statistics were assessed. Standard errors and t-values, which indicated the degree of significance of each element in explaining their respective factor, were within acceptable limits. The R 2, which indicate the strength of relationship between the item and latent construct it is supposed to measure, were all significant. Path coefficients estimates for unidimensional hypothesized factors are presented in figures 2 to 8. Then, scale reliability was assessed, through standardized Cronbach alpha coefficient (Cronbach, 1951). Nunnally (1978) and Churchill (1979) suggest that a scale with Cronbach alpha larger than 0.7 is considered reliable. Final Cronbach alphas (item-to-total corrected alphas) varied from 0.715 to 0.908, suggesting a good internal consistency between items within each construct and reliability for the constructs. Furthermore, combined reliability for all items of the scale was 0.957, indicating that reliability as well as convergent validity was met (Hair et al., 2009). Factor structure was considered stable because the alphas for the combined scales would not increase significantly if any of the items was removed. Table 2: Path coefficients estimations for scale s constructs Path CI CI1 CI CI2 CI CI3 CI CI4 CI CI5 CI CI6 CI CI7 II II1 II II2 II II3 II II4 Path coefficient estimated 0.74* 0.81** 0.90* 0.77* 0.90* 0.78* 0.89* 0.82* 0.94* 0.69* 0.82*
II II5 II II6 II II7 II II8 SI SI1 SI SI3 SI SI4 SI SI5 SI SI7 SI SI8 TI TI1 TI TI2 TI TI3 TI TI4 TI TI5 MI MI1 MI MI2 MI MI4 MI MI5 MI MI6 RI RI1 RI RI2 RI RI4 RI RI5 RI RI6 SCI SCI1 SCI SCI2 SCI SCI3 SCI SCI4 * p<0.01 ** p<0.05 0.70* 0.77** 0.84* 0.65** 0.82* 0.95* 0.71* 0.85* 0.68** 0.66** 0.92* 0.88* 0.81* 0.74* 0.81* 0.68* 0.93* 0.76* 0.82** 0.87** 0.85* 0.90** 0.87** 0.75* 0.73* 0.81* 0.74** 0.69* 0.75* Table 3: Composite reliability and validity indexes for model constructs Construct Number of items Composite reliability (ρ or r p) Customer 7 0.874 Internal 8 0.914 Supplier 6 0.922 Technology & Planning 5 0.937 Measurement Systems 5 0.887 Relationship 5 0.913 Supply Chain 4 0.951 Composite reliabilities for extracted factors were computed in order to provide further evidence on reliability and convergent validity. Construct reliability and convergent validity are evaluated using rho (ρ) coefficient (Croteau and Li, 2003), a coefficient which measures how well a set of items measure a single latent construct (Churchill, 1979). Nunnally (1978) suggest that each construct which have a rho value equal or greater than 0.70 is reliable and should be kept in the model. As presented in Table 3, rho coefficients vary from 0.874 to 0.951 for the seven constructs, further confirming their reliability and convergent validity. Finally, discriminant validity was checked using the approach proposed by Anderson and Gerbing (1988). They suggested conducting a series of paired chi square difference tests based on models of confirmatory factor analysis. First, a constrained CFA model for each possible pair of construct is build, in which the correlations between paired constructs are fixed to 1. Then, the difference of chi-square values for constrained and unconstrained CFA model is computed. Discriminant validity exists when the unconstrained model has a significantly lower chi-square value than the constrained model (Anderson and Gerbing, 1988). All the chi-square differences between constrained and unconstrained models are significantly high (p<0.001), providing sufficient evidence on discriminant validity of the scale (Table 4).
Table 4: Discriminant validity check through chi-square difference test CI II SI TI MI RI CI II 247.61 SI 325.79 340.12 TI 406.15 154.64 168.97 MI 224.49 358.01 213.81 257.66 RI 184.47 114.78 149.64 167.95 184.67 SCI 431.26 347.32 248.32 314.22 189.67 225.98 All differences significant at p<0.001 Hypotheses testing results and discussion The proposed research model and hypotheses presented in previous sections were tested by examining the parameter estimations. In order to support a hypothesis, the respective parameter should be statistically significant, in the direction it was predicted to be, as well as to have a significant value (Hair et al., 2009). To be considered as significant, the standardized structural coefficient linking two constructs should have a value of at least 0.20 and ideally should be greater than 0.30 (Hair et al., 2009). The overall model fit was estimated through structural equation modeling, using the maximum likelihood estimation method, since the measured indicators follow a normal multivariate distribution, i.e. they are normally distributed for each value of other indicators (Hair et al., 2009). This method calculates the estimations based on maximizing the probabilities that observed covariances are drawn from a population that is supposed to be equal to that reflected in the coefficient estimations. Therefore, the maximum likelihoods take those values that consist of greatest possibilities to reproduce covariances in the observed data (Garson, 2012; Hair et al., 2009). For this model, the fit indices are χ 2 = 570.94 (df = 550), GFI=0.98, AGFI=0.97, SRMR=0.06, NNFI=0.97, IFI=0.96, CFI=0.97, PGFI=0.93 and RMSEA=0.07. The value for each indicator exceeds the respective threshold value which allows the conclusion that the model has a good fit. Table 5 summarizes the hypotheses testing results, reflected by standardized path coefficients and the p-values. Table 5: Path coefficient analysis results Hypothesis Standardized path Statistical Hypothesis testing coefficient significance H 1: CI SCI 0.52 p<0.01 Supported H 2: II SCI 0.37 p<0.05 Supported H 3: SI SCI 0.41 p<0.01 Supported H 4: TI SCI 0.08 p<0.05 Not supported H 5: MI SCI 0.06 p<0.05 Not supported H 6: RI SCI 0.38 p<0.01 Supported Of all the tested paths, two of them, that of the direction TI SCI and that of the direction MI SCI, although statistically significant at p<0.05, had coefficient values smaller than 0.10 (a threshold value that would allow them to be considered at least negligible. Consequently, the hypothesis H 4 regarding the impact of technology and planning integration on SCI and hypothesis H 5 regarding the impact of measurement systems integration on SCI, were considered as not supported from statistical analysis. However, generally it can be concluded that the testing results provide good support for the proposed research model. H 1 : Customer integration is a significant driver of SCI: path coefficient 0.52, p<0.01, thus this hypotheses is confirmed. Since not all companies have the capacity and opportunities to satisfy every customer or every customer segment, they should focus on matching their strengths and competencies with the needs of customers they can serve better. In addition, by successfully integrating its customers, the company will be able to steer its resources towards activities that create real value for customers. Having available
different logistic services strategies for different customers, the company is able to serve better, faster, and more effectively exactly to those customers that are very valuable to it, generating more revenue. Also, a strong customer focus is achieved by integrating individual customer requirements through strategic business units, where each unit receives relevant information on customer requirements and makes its best possible to meet them. H 2 : Internal integration is a significant driver of SCI: path coefficient 0.37, p<0.05, the second hypotheses is confirmed too. This conclusion comes naturally, given the benefits of integration and coordination of company s activities and internal operations, such as better support customer requirements and reducing the total cost of the firm s whole supply chain system. The company may increase the expenditures in one area of activities and reduce costs elsewhere, resulting in total benefits by reducing total costs and reaching positive synergistic effects. By coordinating processes of marketing and sales functions, procurement, manufacturing, assembling, and distribution of products or services, the company manages to possess a core competency, which turns into a strong competitive advantage. Companies actively encourage the implementation of best practices, reduce their formal organizational structures or actively engage in the standardization of supply chain operations, in order to improve their performance and achieve internal integration. H 3 : Supplier integration is a significant driver of SCI: path coefficient 0.41, p<0.01, indicating support for this hypothesis. Although the difficulties for achieving supplier integration are well known, the benefits of such an approach are evident for companies. The difficulties are understandable because, as the companies of external often have different goals, pursuing those goals and objectives of individual companies impede the coordination itself. However, by collaborating with external supply chain partners, companies can have access to their expertise, reduce operational redundancies and improve the quality and relevance of services they provided to each - other and to final customers. As Martin Christopher argues, companies today are part of an interdependent network of partners - a confederation of competencies and skills mutually complementary - that competes as an integrated supply chain against other supply chains (Christopher, 2005). In the process of selecting their suppliers, companies often consider the performance of suppliers in relation to the capacities that it considers as essential to its operation. In addition, another good way followed by companies to integrate their suppliers with the overall goal of integrating the whole supply chain is by significantly reducing the number of suppliers to improve operational integration. By focusing on a few supply partners, companies facilitate the operational integration with them and thus both parties become critical elements in the process of value creation for the final customer. H 4 : Technology and planning integration is a significant driver of SCI: path coefficient 0.08, p<0.05, thus concluding that this hypothesis is not supported by testing results. As evidenced by respective path coefficient value, technology and planning integration was not found to have a significant impact on SCI. The reason for this may be that companies today, at least in Albania, do not properly recognize the value of planning and its integration. Although it may share the right amount of information within their operational units, they still find it difficult to have an integrated intra-functional planning. Moreover, they seem to fail to develop common expectations with their supply chain partners. On the other hand, the development of competence to make joint forecasting with suppliers and/or customers still seems very distant for retail firms in Albania. H 5 : Measurement systems integration is a significant driver of SCI: path coefficient 0.06, p<0.05, so this hypothesis is not supported by testing results. Even this path that denotes the influence of measurement systems integration on SCI was not found to be significant. One of explanations for this insignificant path coefficient value can be found in not comprehensively measuring the firm s functional performance, as well as in not developing measures that spread along the supply chain relationships. In addition, retail companies in Albania still do not have a formal program for measuring customer satisfaction, not mentioning the existence of internal customer satisfaction historic data and statistics. Although companies seem to use benchmarking as a tool for performance measurement, they still are not able to accurately determine the impact of the enhanced supply chain on their incomes and profit.
H 6 : Relationship integration is a significant driver of SCI: path coefficient 0.38, p<0.01, this hypothesis is also confirmed. Relationship integration requires willingness by supply chain partners to create structures, framework and appropriate metrics that encourage inter - organizational behavior. Marketers must place a greater emphasis on maintaining and enhancing continuous customer/supplier relationships, in order to facilitate the progressive involvement of partner companies. In order to have a successful relationship where both parties are winners, partners should determine the rules of the game and engage in managerial level since in the early stages of the relationship. Roles specification defines the responsibility for joint and individual working processes. An integrated relationship is built on a mutually accepted range of practices that nurture the collaboration with/or customers and establish the foundations for an effective leadership. The supply chain leadership is increasingly based on knowledge, information, expertise or other skills. This collaborative perspective is the key for developing effective structures of supply chain that regulate the functional operations of numerous companies in a single integrated system. Nomological validity Nomological validity exists when a construct relates to other research constructs in a way that is consistent with the underlying theory (Gerbing and Anderson, 1988; Dunn et al., 1994). All the findings on the relationships between constructs strongly confirm previous studies and theory on respective relationships, like Chen et al., 2011; Radhakrishnan et al., 2011; Clements, 2007; Trkman et al., 2007; Wamba, 2012; Baofeng, 2012, etc., providing evidence that nomological validity for the constructs is achieved in this study. Conclusions The proposed model is theoretically innovative in several aspects. It provides a hierarchical conceptualization of SCI, where the construct of supply chain integration is considered as a consequence of four antecedents: customer integration, internal integration, supplier integration, and relationship integration. These four antecedents are conceptualized as latent variables that are measured through their respective indicators. In this way a multi hierarchical model of SCI is constructed, including SCI, it antecedents and the respective indicator variables. The results of the study also highlight the relative importance of these SCI antecedents and their respective contribution to the overall firm s integration level. Path coefficients clearly reflect the relative impact of each of these antecedents on the overall level of firm s SCI. As deduced from the results of the analysis, customer integration has the greatest impact, while internal integration is regarded as less important in relation to its contribution to SCI. Two antecedents, namely technology and planning integration and measurement systems integration, although initially hypothesized as significant influencers of SCI, their respective path coefficients resulting from the structural equations analysis did not have the proper value to be considered as important. The findings of the study have several practical (managerial) contributions. The most fundamental implication stemming from the proposed model is that retail companies should understand, in a comprehensive manner, the critical factors for achieving the integration of their supply chain. In this way, they could be clarified on the relative impact that each of the factors has in overall level of integration. Better recognizing and analyzing these diagnostic indicators, retail firm managers will be able to better formulate and implement strategies for their companies, as well as collaborative practices with their partners and customers. Customer integration is one of the most important factors in achieving the integration of supply chain. By knowing better the requirements and expectations of customers, the company will be able to effectively coordinate its inbound activities and outbound activities with its partners, in order to meet these requirements and expectations. Also, supplier integration, internal integration, and relationship integration are key factors in building an integrated supply chain. Creating effective partnerships with key members of the supply chain, the structuring and coordination of internal activities and effective management of relationships with partners and customers are prerequisites for successful SCI.
Although technology and planning integration and measurement systems integration were not found as significant factors in building an integrated supply chain, theoretical literature and practical evidence suggest that these competencies are not negligible for achieving this SCI. Moreover, it is evident nowadays, when technology is radically changing the firm s operations and the way of doing business. However, current stage of development of Albanian companies does not adequately reflect the importance of these two types of integration. Other future research will be able evidence the growing importance that technology and planning integration and measurement systems integration have on SCI. As nothing can be perfect, this study carries some drawbacks and limitations. One of them is the fact that the sample consisted only of retail companies. So, although the aim of the study was to deeply explore the SCI, only one link of supply chain was chosen as the reference population: retailing companies. Although this choice was made for pragmatic reasons, the focus of retailers on the supply chain where they belong is narrow, since the supply chain is viewed from their position and point of view. A more comprehensive study should gather data from all the actors and partners in the supply chain, in order to achieve more generalizable results and more understandable implications for all supply chain stakeholders. An additional limitation of the study stems from the fact that it focused only on businesses conducting their activities in Albania. Despite the importance of this study to Albanian companies, its validity would be larger if businesses from other countries would have been included in analysis. 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