By Gunnar Bartsch, Deputy Head & Press Officer / Editor, Würzburg University

In the first few months of their lives, babies cry, babble, gurgle, and make a variety of other peculiar sounds. It can be difficult to imagine that they are actually laying the foundations for later speech with these utterances. However, there is a determining element that proves that even their cries can be assigned to a particular language: the speech melody – or, more accurately: prosody.

Related article: Research Shows Children Use Both Brain Hemispheres to Understand Language

“Every language is characterized by specific musical elements, which we call prosody,” said Kathleen Wermke, a professor at the Würzburg University Hospital at the Department of Orthodontics and Head of the Center for Pre-speech Development and Developmental Disorders. Prosody, in simple terms, is the combination of intonation (melody) and rhythm. Earlier studies have shown that even newborns are able to distinguish different languages, like German or French, using prosodic cues, particularly melody. With the help of these musical elements, infants recognize the respective language long before they are able to perceive its special features such as consonants, vowels, or syllables, according to an article on the Würzburg University website.

Study with more than 67,000 baby sounds

Together with scientists from the USA and New Zealand, she has now examined the vocalisations of a total of 277 infants over the first six months of life in more detail. In total, the team analyzed more than 67,500 cry vocalizations – the so-called hungry-crying – cooing and babbling sounds. 

“We have found a clear developmental pattern towards more complexity,” Wermke said about the result of the study, which has now been published in the journal Scientific Reports. According to the study, this increasing degree of complexity is an important building block on the way to language development. According to the research team, these findings not only significantly improve our understanding of the early preparatory processes for language acquisition, it also makes it possible to identify potential signs of a language development disorder.

Complexity increases over the course of the first six months

In their study, the team distinguished between two types of vocalizations in babies: cry and non-cry vocalizations in technical language. Or, to put it another way, the “communicative” crying uttered in the presence of the mother, which results from discomfort such as hunger and when there is a desire for contact. And, on the other hand, the sounds a baby makes when it feels comfortable and interacts vocally.

“The aim of the study was to conduct an objective developmental analysis of prosodic antecedents in the form of melodies in healthy infants from birth to 6 months of age in all their vocalizations,” said Wermke. Her hypothesis was: both types of vocalization show a characteristic developmental increase in complex melodies.

In fact, the evaluation shows that the melodies of spontaneous cries become increasingly complex during the first 180 days of life;  complex meaning that simple melodies (single-arc) are increasingly replaced by multiple-arc melodies, ie, the foundation for the richness of variants of later intonation patterns in speech is already laid during crying. The development was comparable for phonetic utterances that fall under the category of “comfort vocalizations.” The degree of complexity also increased in these, but with a temporary decline at around 140 days of age.

Rapid brain growth is the foundation

“Already at the end of the first month of life, the cry repertoire of the babies studied shows a complex melody in more than half of the cases,” said Wermke. From single-arc to multiple-arc melodies in 30 days: this developmental program is based on an early maturity of the neurophysiological mechanisms underlying melody production. In fact, the brains of newborns also grow tremendously fast during this time, and newborns show amazing coordination between breathing and phonation. Furthermore, the scientists believe that the early occurrence of complex cry melodies indicates that infants have already undergone a kind of training, a “preparatory” intrauterine development before birth, in order to start with the development of melodies immediately after or at the starting signal “birth.”

Wermke and her co-authors have an explanation for this slight decrease in complexity between the ages of four and five months: “During this time, infants expand their repertoire of vocalic utterances to include new components that interact with the overall melodic contour, namely vowel- and consonant-like elements,” said Wermke. At the same time, the larynx and vocal tract are changing, which entails a series of adaptation processes in sound production. In addition to this, infants also begin to produce their first syllable combinations in babbling during this phase.

“This new developmental period evidently causes a temporary ‘regression’ in melody development to establish vocal development on a higher hierarchical level. Thereafter, the infant begins to intentionally imitate intonation patterns of the surrounding language(s) in consonant-vowel syllable sequences in babbling.”

Prerequisite for innovative therapies

According to those involved, the developmental model now presented can contribute to a better understanding of why the human infant acquires such a complex skill as language so quickly and seemingly effortlessly. What sounds like rather dry basic research in the field of spoken language acquisition nevertheless has a very practical relevance.

“Knowledge of this developmental process will enable us to identify clinically robust risk markers for language development disorders,” said Wermke. This, she says, is the crucial prerequisite for developing new and innovative therapies for young children at risk for language disorders.

Original Paper: Wermke K, Robb MP, Schulter PJ. Melody complexity of infants’ cry and non-cry vocalisations increases across the first six months. Scientific Reports. 2021;11(4137).

Source: Würzburg University, Scientific Reports