Historically the sciences have always progressed faster than our morality. From the churche’s slow adjustment to a Copernican world to the slow acceptance of our diminutive place in the universe, the human condition has always been vulnerable to personal biases and egocentrism.
Any truthful (moral) scientific methodology originating from refined methods, as our higher educational institutions nurture us to do, by design has to concentrate both method and perception. I also proposed that we cannot separate morality from science unless we conform to pseudoscience. This argument is essential to create a demarcation between real science (truths) and pseudoscience (falsities). So where due we turn if science is under threat?
Any empirical scientific methodology to create a demarcation between real science and pseudoscience need a solid foundation. But is such a demarcation sufficient in protecting us from psuedosceince, or will it inevitably arrest itself in its own duress? We must today, more than in previous times, consider the powerful concentrating effect of sponsored institutionalized thinking and corporate funded research on science. Science is our untapped potential and only hope to constantly evolve a body of knowledge that can be applied to a growing list of new subjects. It is our only hope to intellectual freedom in our ongoing search for truthful facts about our world and universe.
It is generally accepted that empirical evidence is the evidence of the senses, of direct observation or measurement and the pillars of the science we develop. Compare that to rational evidence, which is evidence that is the result of deduction, experience or other reasoning, or anecdotal evidence which comes from personal testimony which may be reliable or not, its potential to reliability also deserving closer scrutiny. Most research in healthcare is based on empirical evidence coming from narrowly defined avenues— called evidence-based research. We must however agree, it is only when we are open to all approaches having potential value in scientific advances that we can reliably help to improve the human condition.
We should consider what some science philosophers had to say on this matter. The Hungarian born science philosopher Imre Lakatos (1922-1974) suggested that the distinction between science and non-science, and good and bad science, should be based on when a research program cannot predict anything new, or when its claims cannot be tested—the latter subsequently is bad science and might be degenerating to the point of pseudoscience.
Evidence-based research, our most acceptable approach to the scientific method, also serve to refine auxiliary conjectures and continues to be progressive for as long as new facts can be predicated, and new tests can emerge from data. The philosopher Sir Karl Popper famously contributed to the philosophy of science with his claim that falsifiability of existing theories is the demarcation of science from non-science. In different terms it also implies that no methodology is entirely free from observational error and therefore can always be falsified and improved on. So far what all these claims have in common is that good science should be able to advance by learning from its errors and mistakes and result in something new to examine. Yet, it must still be secured in solidity. nd be free of personal views or self interest.
The reliability of good science get more insecure if science confirms that no observation (regardless of methodology) is entirely free from measurement error or bias, consequently we may question whether our experimental result was what it appeared to be. Things may also change as we measure them (Heisenberg principle aside), such change occurring in both the observer and the object being observed as they both continuously evolve. The political, fashion and financial flavour (financiers) of the day may subsequently severely impact the direction research projects may take. Quantum physics, entanglement, theories about dark energy and claims by physicists that ‘light knows when we are looking at it and behaves differently when it is being observed further add to the confusion. Slowly it is becoming clear that good science (or at least our expectations of it) is both ephemeral and elusive. It is also hard to imagine a cognitive evolution in a universe with set boundaries where everything is know and understood.
In addition to this problem, as I explained in Spheres of perception (2020), besides the aforementioned challenges time and its inseparable companion change are vital in our changing perceptions of the material world we continuously observe and measure. Think of trying to land a plane on an air strip at Heathrow based on historic predictions of continental drift and weather patterns. Unavoidably good science has to progress from its previous flaws and adapt to change; crashing a plane when human lives are at stake is not a good method to eliminate bad science in order to learn more. Inarguably if science is not aimed at preserving and improving life and our understanding of it on all levels, why must we bother.
Should we make the mistake of setting our believes concretely on empirical science and its ‘flawless’ conclusions, set on such unfalsifiable theories , measured predictability and following concrete rules under fixed conditions — how shall we evolve a good science from here then? It seems Popper was right in as much as warning about confronting this dilemma. In a mechanistic evidence-based correctness in the physical world we are also (perhaps a surprise to many) in greater danger of advancing pseudoscience and reduce our odds of survival as a species. Soon the concrete matter we so arduously tried to break down, measure under strictly applied set conditions as defined by us, down to its smallest components and energy spectra, may become inadequate. Unless we somehow allow for the fact that the subjects being measured and studied also change, be it at different rates over time they interact in a complex network. However, even this won't be enough, we also somehow need to create more scope for our perceptive abilities to continuously coevolve in all spheres attuned to the evolution of the subjects studied.
Lakatos proposed that a scientific revolution occurs when a dominant programme has completely degenerated and is incompetent in responding to accumulating anomalies – creating a crisis in confidence in either the methodology, the basis in approach of the measurer or both. A new scientific breakthrough is then needed to for a progressive science to explain emerging anomalies. I think we are close to such a revolution in the natural and physical sciences today. Lakatos pre-warned that such a revolution if and when it occurs should be driven by logic and method, not irrational mob psychology as is emerging today when we think of AI and genomics. Many still see both evolution and many outcomes in medical science as attempts to demarcate the physical from the metaphysical, subsequently when science fails them they rush to find comfort in the metaphysical or in the uncertainty of beliefs and remedies without any proof —this is dangerous under current needs and social newly evolved social demands.
Should we perhaps blame science for being too realistically harsh, or too unrealistically demarcated from all spheres of existence? If we consider our current concept of a Darwinian based evolution as the cornerstone of much of contemporary biology and medical science, and place this under Lakatos’s, Popper’s and my own scrutiny here, then it is also overdue for an update. The reason for this is that the general perception is still of an evolution based on a crude ‘unconscious’ mechanical natural-selection searching for survival and reproduction in an egocentric blueprinted gene. With many advanced techniques available and the genomes of various species now mapped, it is helping us to understand evolution more as interactive and 'perceptive' living system— interconnected to living environments.
A new picture of a perceptive bionetwork continuously adjusting and fine-tuning itself as part of a communicative and interdependent bionetwork is emerging and we need urgent adjustments to guide a new science, unless we surrender to a future of pseudoscience. If we continue to pursue this road, besides bad science inevitably leading to regression, we also miss out on a significant and overdue moral advancement as explained in my new book. I also argue we cannot separate science from morality.
Lakatos’s concepts, Popperian falsification and Kuhn’s claim of science having a cultural drive that may mislead, all have one thing clearly in common, and that is the possibility that any strictly evidence-based research programme might exhibit changing fortunes over time and we need to be prepared for this. A cultural drive (such as the technical drive for a superior AI) demarcating itself from the gains and benefits of an interconnected science may in reverse be seen as an indicator of bad science, currently we see this emerge on many fronts. Darwinian based evolutionary theory fits the latter pattern in view of new advances in phylogenetics witnessing a ‘communicative’ biochemistry as the essence of life. Another concern is the increasing gap between natural sciences, morality, and advancing technology, AI. There is also however nothing to rule out the possibility that a degenerating program could somehow stage a spectacular recovery. The latter does not imply manipulation or manipulation of research subjects to fit a need, but rather adapting new perceptions and/or methodologies to help us better understand our evolutionary epistemology. We should pay heed to this as I pointed out in Spheres of Perception, by also widening our perceptions to circulate in freely evolving spheres (physical, uncertainty and metaphysical), especially in healthcare. These three spheres being, the evidence-based physical world, the uncertain (unproven) and metaphysical (unknown to be perceived). They should all be open to evolve together in a good science interacting within a progressive moral world. In such a science no demarcations or biases can hamper progressive understanding to reliably interconnect truthful afcts based on sound principles as part of a continuously evolving perceptive living network.
The philosophers all hinted that science should be non-restrictive. Lakatos’s warned scientists doggedly pursuing a degenerating research program are guilty of an irrational commitment to a bad science. Popper tells us if nothing can be falsified it is bad science. Today exiting research fields have opened up in astrobiology, quantum mechanics/computing, on dark matter and dark energy, besides the above-mentioned escalating evidence of a flexible genome interactive within changing living environments. These exciting fields are still very much neglected, lost amongst an array of programs finding much more security in the familiarity of bad science with set values operating in inflexible theories, finding more security in financial investments.
In a capitalist society it appears that unfortunately ‘bad science’ may be currently all that is available to take the next leap forward. In a post reductionist era where the material world and all our advancing means to perceive and measure it will become restrictive when dissected down to its smallest elements. Especially in biochemistry, physics and chemistry, solidity appear to be less concrete than expected. All we can turn to then is an interactive and interconnect all regarding concern driven by perceptions focussed on this escalating change in evolving complexity. The aim will become to gain better understanding of how all these narrowly defined elements interconnect and advance or regress in self-generated complexity. For this we will need new methodologies to create space for the undiscovered and unexpected. Such methodologies should simultaneously not be restrained by culturism or fad as Kuhn suggested, neither should it be based on set institutionalised thinking, existing methods or non-falsifiable set theory as Popper guided or be disabled in its ability to claim anything new (evolve new unrestricted ideas) as Lakatos indicated.
In conclusion we should not neglect including the valuable, seemingly indifferent, opinion on the topic from the American philosopher Larry Laudan in 1983—he claimed there is no hope of finding a necessary and sufficient criterion of something as heterogeneous as scientific methodology. This widely accepted conclusion of Lauden guided us to eagerly enter in our pursuit of good science, without set beliefs or personal biases.
There is now also growing recognition that the natural, social sciences and the humanities all function as parts of the same human heterogenous endeavour attempting to create systematic and critical investigation—all aimed at acquiring the best possible understanding of the workings of nature, objects and people in a rapidly evolving interconnected living network. The diverse disciplines that form this community of knowledge disciplines are increasingly interdependent as Hansson also implied in 2007. We now understand that all these components (including us) are constantly changing, interactive within a biostructure we are only beginning to understand. Lauden was right in that 'empirical science is facing simultaneous dilemmas all at once as it can only function if perceptive to a heterogeneous environment'. In the current climate of knowledge explosion, and with fund-directed research attempting to gain its support in ‘institutionalised evidence-based’ research, the amount of unpredictable and marginalised axillary theories that lack funding may furthermore be easily under supported or even overlooked. With their potential value lost we are now dangerously close to be led by a demarcated pseudoscience operating in blind isolation.
In order to negate and advance into this vast new world with new opportunity and not despondency, we need to be armed with a reliable, free and truthful science in full acknowledgement of our world as perceptive and interconnected in progressive spheres of perception. These spheres, constantly evolving and adjusting to complexity, both in the physically evident (empirical ) and uncertainty, without neglecting the metaphysical. To do this we must be receptive to change without barriers as an interactive concern adjusting to rapidly evolving heterogeneity. We may define this need for new methodologies as a pending scientific revolution in an advancing morality.
References
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