Split Learning (SL) has been promoted as a promising collaborative machine learning technique designed to address data privacy and resource efficiency. Specifically, neural networks are divided into client and server sub-networks in order to mitigate the exposure of sensitive data and reduce the overhead on client devices, thereby making SL particularly suitable for resource-constrained devices. Although SL prevents the direct transmission of raw data, it does not alleviate entirely the risk of privacy breaches. In fact, the data intermediately transmitted to the server sub-model may include patterns or information that could reveal sensitive data. Moreover, achieving a balance between model utility and data privacy has emerged as a challenging problem. In this article, we propose a novel defense approach that combines: (i) Adversarial learning, and (ii) Network channel pruning. In particular, the proposed adversarial learning approach is specifically designed to reduce the risk of private data exposure while maintaining high performance for the utility task. On the other hand, the suggested channel pruning enables the model to adaptively adjust and reactivate pruned channels while conducting adversarial training. The integration of these two techniques reduces the informativeness of the intermediate data transmitted by the client sub-model, thereby enhancing its robustness against attribute inference attacks without adding significant computational overhead, making it well-suited for IoT devices, mobile platforms, and Internet of Vehicles (IoV) scenarios. The proposed defense approach was evaluated using EfficientNet-B0, a widely adopted compact model, along with three benchmark datasets. The obtained results showcased its superior defense capability against attribute inference attacks compared to existing state-of-the-art methods. This research’s findings demonstrated the effectiveness of the proposed channel pruning-based adversarial training approach in achieving the intended compromise between utility and privacy within SL frameworks. In fact, the classification accuracy attained by the attackers witnessed a drastic decrease of 70%.