Diabetic ketoacidosis is a critical medical emergency that needs to be dealt with promptly to prevent severe complications and death. Traditional glucose tracking gadgets omit the complex metabolic styles, leading to worsening ketoacidosis, causing risky delays in detection at the point of vital intervention. The article introduces a novel detection scheme that combines continuous glucose and ketone monitoring with sophisticated sequence modeling algorithms to facilitate early detection of metabolic crisis. Bidirectional long short-term memory networks augmented with attention mechanisms handle synchronized physiological data streams that detect subtle patterns ahead of clinical threshold violations. The system performs better than traditional threshold-monitoring approaches using detailed temporal pattern exploration over long observation periods. Clinical validation shows outstanding discrimination performance in varied patient populations with low false alert rates, critical to long-term clinical use. Integration avenues include automated insulin delivery systems, remote monitoring platforms, and population health management platforms that level the field towards specialized diabetes care. Economic impact analyses demonstrate dramatic healthcare cost savings through active intervention protocols to avoid emergency admissions and intensive care needs. Regulatory aspects cover compliance with medical device software and applying privacy-preserving federated learning approaches for joint model development. Future development avenues involve integrated metabolic monitoring platforms with further physiological parameters to enable wider crisis detection. The platform is a paradigm shift towards predictive diabetes management, allowing proactive intervention measures that optimize patient outcomes exponentially while decreasing the burden on the healthcare system through intelligent automation and ongoing surveillance abilities.